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vectorf512e.h
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vectorf512e.h
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/**************************** vectorf512.h *******************************
* Author: Agner Fog
* Date created: 2014-07-23
* Last modified: 2023-07-04
* Version: 2.02.02
* Project: vector class library
* Description:
* Header file defining 512-bit floating point vector classes
* Emulated for processors without AVX512 instruction set
*
* Instructions: see vcl_manual.pdf
*
* The following vector classes are defined here:
* Vec16f Vector of 16 single precision floating point numbers
* Vec16fb Vector of 16 Booleans for use with Vec16f
* Vec8d Vector of 8 double precision floating point numbers
* Vec8db Vector of 8 Booleans for use with Vec8d
*
* Each vector object is represented internally in the CPU as two 256-bit registers.
* This header file defines operators and functions for these vectors.
*
* (c) Copyright 2014-2023 Agner Fog.
* Apache License version 2.0 or later.
*****************************************************************************/
#ifndef VECTORF512E_H
#define VECTORF512E_H
#ifndef VECTORCLASS_H
#include "vectorclass.h"
#endif
#if VECTORCLASS_H < 20200
#error Incompatible versions of vector class library mixed
#endif
#if defined (VECTORF512_H)
#error Two different versions of vectorf512.h included
#endif
#include "vectori512e.h"
#ifdef VCL_NAMESPACE
namespace VCL_NAMESPACE {
#endif
/*****************************************************************************
*
* Vec16fb: Vector of 16 broad booleans for use with Vec16f
*
*****************************************************************************/
class Vec16fb : public Vec16b {
public:
// Default constructor:
Vec16fb () = default;
// Constructor to build from all elements:
Vec16fb(bool x0, bool x1, bool x2, bool x3, bool x4, bool x5, bool x6, bool x7,
bool x8, bool x9, bool x10, bool x11, bool x12, bool x13, bool x14, bool x15) :
Vec16b(x0, x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, x13, x14, x15) {
}
// Constructor from Vec16b
Vec16fb (Vec16b const x) {
z0 = x.get_low();
z1 = x.get_high();
}
// Constructor from two Vec8fb
Vec16fb (Vec8fb const x0, Vec8fb const x1) {
#ifdef VECTORF256E_H
z0 = reinterpret_i(x0);
z1 = reinterpret_i(x1);
#else
z0 = x0;
z1 = x1;
#endif
}
// Constructor to broadcast scalar value:
Vec16fb(bool b) : Vec16b(b) {
}
// Assignment operator to broadcast scalar value:
Vec16fb & operator = (bool b) {
*this = Vec16b(b);
return *this;
}
// Get low and high half
Vec8fb get_low() const {
return reinterpret_f(Vec8i(z0));
}
Vec8fb get_high() const {
return reinterpret_f(Vec8i(z1));
}
// Member function to change a bitfield to a boolean vector
Vec16fb & load_bits(uint16_t a) {
z0 = Vec8ib().load_bits(uint8_t(a));
z1 = Vec8ib().load_bits(uint8_t(a>>8));
return *this;
}
// Prevent constructing from int, etc.
Vec16fb(int b) = delete;
Vec16fb & operator = (int x) = delete;
};
// Define operators for Vec16fb
// vector operator & : bitwise and
static inline Vec16fb operator & (Vec16fb const a, Vec16fb const b) {
return Vec16fb(a.get_low() & b.get_low(), a.get_high() & b.get_high());
}
static inline Vec16fb operator && (Vec16fb const a, Vec16fb const b) {
return a & b;
}
// vector operator | : bitwise or
static inline Vec16fb operator | (Vec16fb const a, Vec16fb const b) {
return Vec16fb(a.get_low() | b.get_low(), a.get_high() | b.get_high());
}
static inline Vec16fb operator || (Vec16fb const a, Vec16fb const b) {
return a | b;
}
// vector operator ^ : bitwise xor
static inline Vec16fb operator ^ (Vec16fb const a, Vec16fb const b) {
return Vec16fb(a.get_low() ^ b.get_low(), a.get_high() ^ b.get_high());
}
// vector operator == : xnor
static inline Vec16fb operator == (Vec16fb const a, Vec16fb const b) {
return Vec16fb(Vec16fb(a) ^ Vec16fb(~b));
}
// vector operator != : xor
static inline Vec16fb operator != (Vec16fb const a, Vec16fb const b) {
return Vec16fb(a ^ b);
}
// vector operator ~ : bitwise not
static inline Vec16fb operator ~ (Vec16fb const a) {
return Vec16fb(~a.get_low(), ~a.get_high());
}
// vector operator ! : element not
static inline Vec16fb operator ! (Vec16fb const a) {
return ~a;
}
// vector operator &= : bitwise and
static inline Vec16fb & operator &= (Vec16fb & a, Vec16fb const b) {
a = a & b;
return a;
}
// vector operator |= : bitwise or
static inline Vec16fb & operator |= (Vec16fb & a, Vec16fb const b) {
a = a | b;
return a;
}
// vector operator ^= : bitwise xor
static inline Vec16fb & operator ^= (Vec16fb & a, Vec16fb const b) {
a = a ^ b;
return a;
}
/*****************************************************************************
*
* Vec8db: Vector of 8 broad booleans for use with Vec8d
*
*****************************************************************************/
class Vec8db : public Vec512b {
public:
// Default constructor:
Vec8db () = default;
// Constructor to build from all elements:
Vec8db(bool x0, bool x1, bool x2, bool x3, bool x4, bool x5, bool x6, bool x7) {
z0 = Vec4qb(x0, x1, x2, x3);
z1 = Vec4qb(x4, x5, x6, x7);
}
// Construct from Vec512b
Vec8db (Vec512b const x) {
z0 = x.get_low();
z1 = x.get_high();
}
// Constructor from two Vec4db
Vec8db (Vec4db const x0, Vec4db const x1) {
#ifdef VECTORF256E_H
z0 = reinterpret_i(x0);
z1 = reinterpret_i(x1);
#else
z0 = x0;
z1 = x1;
#endif
}
// Constructor to broadcast single value:
Vec8db(bool b) {
z0 = z1 = Vec8i(-int32_t(b));
}
// Assignment operator to broadcast scalar value:
Vec8db & operator = (bool b) {
*this = Vec8db(b);
return *this;
}
Vec8db & insert(int index, bool a) {
if (index < 4) {
z0 = Vec4q(z0).insert(index, -(int64_t)a);
}
else {
z1 = Vec4q(z1).insert(index-4, -(int64_t)a);
}
return *this;
}
// Member function extract a single element from vector
bool extract(int index) const {
if ((uint32_t)index < 4) {
return Vec4q(z0).extract(index) != 0;
}
else {
return Vec4q(z1).extract(index-4) != 0;
}
}
// Extract a single element. Operator [] can only read an element, not write.
bool operator [] (int index) const {
return extract(index);
}
// Get low and high half
Vec4db get_low() const {
return reinterpret_d(Vec4q(z0));
}
Vec4db get_high() const {
return reinterpret_d(Vec4q(z1));
}
// Member function to change a bitfield to a boolean vector
Vec8db & load_bits(uint8_t a) {
z0 = Vec4qb().load_bits(a);
z1 = Vec4qb().load_bits(uint8_t(a>>4u));
return *this;
}
static constexpr int size() {
return 8;
}
static constexpr int elementtype() {
return 3;
}
// Prevent constructing from int, etc. because of ambiguity
Vec8db(int b) = delete;
// Prevent assigning int because of ambiguity
Vec8db & operator = (int x) = delete;
};
// Define operators for Vec8db
// vector operator & : bitwise and
static inline Vec8db operator & (Vec8db const a, Vec8db const b) {
return Vec8db(a.get_low() & b.get_low(), a.get_high() & b.get_high());
}
static inline Vec8db operator && (Vec8db const a, Vec8db const b) {
return a & b;
}
// vector operator | : bitwise or
static inline Vec8db operator | (Vec8db const a, Vec8db const b) {
return Vec8db(a.get_low() | b.get_low(), a.get_high() | b.get_high());
}
static inline Vec8db operator || (Vec8db const a, Vec8db const b) {
return a | b;
}
// vector operator ^ : bitwise xor
static inline Vec8db operator ^ (Vec8db const a, Vec8db const b) {
return Vec8db(a.get_low() ^ b.get_low(), a.get_high() ^ b.get_high());
}
// vector operator == : xnor
static inline Vec8db operator == (Vec8db const a, Vec8db const b) {
return Vec8db(Vec8db(a) ^ Vec8db(~b));
}
// vector operator != : xor
static inline Vec8db operator != (Vec8db const a, Vec8db const b) {
return Vec8db(a ^ b);
}
// vector operator ~ : bitwise not
static inline Vec8db operator ~ (Vec8db const a) {
return Vec8db(~a.get_low(), ~a.get_high());
}
// vector operator ! : element not
static inline Vec8db operator ! (Vec8db const a) {
return ~a;
}
// vector operator &= : bitwise and
static inline Vec8db & operator &= (Vec8db & a, Vec8db const b) {
a = a & b;
return a;
}
// vector operator |= : bitwise or
static inline Vec8db & operator |= (Vec8db & a, Vec8db const b) {
a = a | b;
return a;
}
// vector operator ^= : bitwise xor
static inline Vec8db & operator ^= (Vec8db & a, Vec8db const b) {
a = a ^ b;
return a;
}
/*****************************************************************************
*
* Vec16f: Vector of 16 single precision floating point values
*
*****************************************************************************/
class Vec16f {
protected:
Vec8f z0;
Vec8f z1;
public:
// Default constructor:
Vec16f() = default;
// Constructor to broadcast the same value into all elements:
Vec16f(float f) {
z0 = z1 = Vec8f(f);
}
// Constructor to build from all elements:
Vec16f(float f0, float f1, float f2, float f3, float f4, float f5, float f6, float f7,
float f8, float f9, float f10, float f11, float f12, float f13, float f14, float f15) {
z0 = Vec8f(f0, f1, f2, f3, f4, f5, f6, f7);
z1 = Vec8f(f8, f9, f10, f11, f12, f13, f14, f15);
}
// Constructor to build from two Vec8f:
Vec16f(Vec8f const a0, Vec8f const a1) {
z0 = a0;
z1 = a1;
}
// split into two halves
Vec8f get_low() const {
return z0;
}
Vec8f get_high() const {
return z1;
}
// Member function to load from array (unaligned)
Vec16f & load(float const * p) {
z0 = Vec8f().load(p);
z1 = Vec8f().load(p+8);
return *this;
}
// Member function to load from array, aligned by 64
// You may use load_a instead of load if you are certain that p points to an address divisible by 64
Vec16f & load_a(float const * p) {
z0 = Vec8f().load_a(p);
z1 = Vec8f().load_a(p+8);
return *this;
}
// Member function to store into array (unaligned)
void store(float * p) const {
Vec8f(z0).store(p);
Vec8f(z1).store(p+8);
}
// Member function to store into array, aligned by 64
// You may use store_a instead of store if you are certain that p points to an address divisible by 64
void store_a(float * p) const {
Vec8f(z0).store_a(p);
Vec8f(z1).store_a(p+8);
}
// Member function storing to aligned uncached memory (non-temporal store).
// This may be more efficient than store_a when storing large blocks of memory if it
// is unlikely that the data will stay in the cache until it is read again.
// Note: Will generate runtime error if p is not aligned by 64
void store_nt(float * p) const {
Vec8f(z0).store_nt(p);
Vec8f(z1).store_nt(p+8);
}
// Partial load. Load n elements and set the rest to 0
Vec16f & load_partial(int n, float const * p) {
if (n < 8) {
z0 = Vec8f().load_partial(n, p);
z1 = Vec8f(0.f);
}
else {
z0 = Vec8f().load(p);
z1 = Vec8f().load_partial(n-8, p + 8);
}
return *this;
}
// Partial store. Store n elements
void store_partial(int n, float * p) const {
if (n < 8) {
Vec8f(z0).store_partial(n, p);
}
else {
Vec8f(z0).store(p);
Vec8f(z1).store_partial(n-8, p+8);
}
}
// cut off vector to n elements. The last 8-n elements are set to zero
Vec16f & cutoff(int n) {
if (n < 8) {
z0 = Vec8f(z0).cutoff(n);
z1 = Vec8f(0.f);
}
else {
z1 = Vec8f(z1).cutoff(n-8);
}
return *this;
}
// Member function to change a single element in vector
Vec16f const insert(int index, float value) {
if ((uint32_t)index < 8) {
z0 = Vec8f(z0).insert(index, value);
}
else {
z1 = Vec8f(z1).insert(index-8, value);
}
return *this;
}
// Member function extract a single element from vector
float extract(int index) const {
float a[16];
store(a);
return a[index & 15];
}
// Extract a single element. Use store function if extracting more than one element.
// Operator [] can only read an element, not write.
float operator [] (int index) const {
return extract(index);
}
static constexpr int size() {
return 16;
}
static constexpr int elementtype() {
return 16;
}
};
/*****************************************************************************
*
* Operators for Vec16f
*
*****************************************************************************/
// vector operator + : add element by element
static inline Vec16f operator + (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() + b.get_low(), a.get_high() + b.get_high());
}
// vector operator + : add vector and scalar
static inline Vec16f operator + (Vec16f const a, float b) {
return a + Vec16f(b);
}
static inline Vec16f operator + (float a, Vec16f const b) {
return Vec16f(a) + b;
}
// vector operator += : add
static inline Vec16f & operator += (Vec16f & a, Vec16f const b) {
a = a + b;
return a;
}
// postfix operator ++
static inline Vec16f operator ++ (Vec16f & a, int) {
Vec16f a0 = a;
a = a + 1.0f;
return a0;
}
// prefix operator ++
static inline Vec16f & operator ++ (Vec16f & a) {
a = a + 1.0f;
return a;
}
// vector operator - : subtract element by element
static inline Vec16f operator - (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() - b.get_low(), a.get_high() - b.get_high());
}
// vector operator - : subtract vector and scalar
static inline Vec16f operator - (Vec16f const a, float b) {
return a - Vec16f(b);
}
static inline Vec16f operator - (float a, Vec16f const b) {
return Vec16f(a) - b;
}
// vector operator - : unary minus
// Change sign bit, even for 0, INF and NAN
static inline Vec16f operator - (Vec16f const a) {
return Vec16f(-a.get_low(), -a.get_high());
}
// vector operator -= : subtract
static inline Vec16f & operator -= (Vec16f & a, Vec16f const b) {
a = a - b;
return a;
}
// postfix operator --
static inline Vec16f operator -- (Vec16f & a, int) {
Vec16f a0 = a;
a = a - 1.0f;
return a0;
}
// prefix operator --
static inline Vec16f & operator -- (Vec16f & a) {
a = a - 1.0f;
return a;
}
// vector operator * : multiply element by element
static inline Vec16f operator * (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() * b.get_low(), a.get_high() * b.get_high());
}
// vector operator * : multiply vector and scalar
static inline Vec16f operator * (Vec16f const a, float b) {
return a * Vec16f(b);
}
static inline Vec16f operator * (float a, Vec16f const b) {
return Vec16f(a) * b;
}
// vector operator *= : multiply
static inline Vec16f & operator *= (Vec16f & a, Vec16f const b) {
a = a * b;
return a;
}
// vector operator / : divide all elements by same integer
static inline Vec16f operator / (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() / b.get_low(), a.get_high() / b.get_high());
}
// vector operator / : divide vector and scalar
static inline Vec16f operator / (Vec16f const a, float b) {
return a / Vec16f(b);
}
static inline Vec16f operator / (float a, Vec16f const b) {
return Vec16f(a) / b;
}
// vector operator /= : divide
static inline Vec16f & operator /= (Vec16f & a, Vec16f const b) {
a = a / b;
return a;
}
// vector operator == : returns true for elements for which a == b
static inline Vec16fb operator == (Vec16f const a, Vec16f const b) {
return Vec16fb(a.get_low() == b.get_low(), a.get_high() == b.get_high());
}
// vector operator != : returns true for elements for which a != b
static inline Vec16fb operator != (Vec16f const a, Vec16f const b) {
return Vec16fb(a.get_low() != b.get_low(), a.get_high() != b.get_high());
}
// vector operator < : returns true for elements for which a < b
static inline Vec16fb operator < (Vec16f const a, Vec16f const b) {
return Vec16fb(a.get_low() < b.get_low(), a.get_high() < b.get_high());
}
// vector operator <= : returns true for elements for which a <= b
static inline Vec16fb operator <= (Vec16f const a, Vec16f const b) {
return Vec16fb(a.get_low() <= b.get_low(), a.get_high() <= b.get_high());
}
// vector operator > : returns true for elements for which a > b
static inline Vec16fb operator > (Vec16f const a, Vec16f const b) {
return b < a;
}
// vector operator >= : returns true for elements for which a >= b
static inline Vec16fb operator >= (Vec16f const a, Vec16f const b) {
return b <= a;
}
// Bitwise logical operators
// vector operator & : bitwise and
static inline Vec16f operator & (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() & b.get_low(), a.get_high() & b.get_high());
}
// vector operator &= : bitwise and
static inline Vec16f & operator &= (Vec16f & a, Vec16f const b) {
a = a & b;
return a;
}
// vector operator & : bitwise and of Vec16f and Vec16fb
static inline Vec16f operator & (Vec16f const a, Vec16fb const b) {
return Vec16f(a.get_low() & b.get_low(), a.get_high() & b.get_high());
}
static inline Vec16f operator & (Vec16fb const a, Vec16f const b) {
return b & a;
}
// vector operator | : bitwise or
static inline Vec16f operator | (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() | b.get_low(), a.get_high() | b.get_high());
}
// vector operator |= : bitwise or
static inline Vec16f & operator |= (Vec16f & a, Vec16f const b) {
a = a | b;
return a;
}
// vector operator ^ : bitwise xor
static inline Vec16f operator ^ (Vec16f const a, Vec16f const b) {
return Vec16f(a.get_low() ^ b.get_low(), a.get_high() ^ b.get_high());
}
// vector operator ^= : bitwise xor
static inline Vec16f & operator ^= (Vec16f & a, Vec16f const b) {
a = a ^ b;
return a;
}
// vector operator ! : logical not. Returns Boolean vector
static inline Vec16fb operator ! (Vec16f const a) {
return Vec16fb(!a.get_low(), !a.get_high());
}
/*****************************************************************************
*
* Functions for Vec16f
*
*****************************************************************************/
// Select between two operands. Corresponds to this pseudocode:
// for (int i = 0; i < 8; i++) result[i] = s[i] ? a[i] : b[i];
// Each byte in s must be either 0 (false) or 0xFFFFFFFF (true). No other values are allowed.
static inline Vec16f select (Vec16fb const s, Vec16f const a, Vec16f const b) {
return Vec16f(select(s.get_low(), a.get_low(), b.get_low()), select(s.get_high(), a.get_high(), b.get_high()));
}
// Conditional add: For all vector elements i: result[i] = f[i] ? (a[i] + b[i]) : a[i]
static inline Vec16f if_add (Vec16fb const f, Vec16f const a, Vec16f const b) {
return Vec16f(if_add(f.get_low(), a.get_low(), b.get_low()), if_add(f.get_high(), a.get_high(), b.get_high()));
}
// Conditional subtract
static inline Vec16f if_sub (Vec16fb const f, Vec16f const a, Vec16f const b) {
return Vec16f(if_sub(f.get_low(), a.get_low(), b.get_low()), if_sub(f.get_high(), a.get_high(), b.get_high()));
}
// Conditional multiply
static inline Vec16f if_mul (Vec16fb const f, Vec16f const a, Vec16f const b) {
return Vec16f(if_mul(f.get_low(), a.get_low(), b.get_low()), if_mul(f.get_high(), a.get_high(), b.get_high()));
}
// Conditional divide
static inline Vec16f if_div (Vec16fb const f, Vec16f const a, Vec16f const b) {
return Vec16f(if_div(f.get_low(), a.get_low(), b.get_low()), if_div(f.get_high(), a.get_high(), b.get_high()));
}
// Horizontal add: Calculates the sum of all vector elements.
static inline float horizontal_add (Vec16f const a) {
return horizontal_add(a.get_low() + a.get_high());
}
// function max: a > b ? a : b
static inline Vec16f max(Vec16f const a, Vec16f const b) {
return Vec16f(max(a.get_low(), b.get_low()), max(a.get_high(), b.get_high()));
}
// function min: a < b ? a : b
static inline Vec16f min(Vec16f const a, Vec16f const b) {
return Vec16f(min(a.get_low(), b.get_low()), min(a.get_high(), b.get_high()));
}
// NAN-safe versions of maximum and minimum are in vector_convert.h
// function abs: absolute value
// Removes sign bit, even for -0.0f, -INF and -NAN
static inline Vec16f abs(Vec16f const a) {
return Vec16f(abs(a.get_low()), abs(a.get_high()));
}
// function sqrt: square root
static inline Vec16f sqrt(Vec16f const a) {
return Vec16f(sqrt(a.get_low()), sqrt(a.get_high()));
}
// function square: a * a
static inline Vec16f square(Vec16f const a) {
return a * a;
}
// pow(Vec16f, int):
template <typename TT> static Vec16f pow(Vec16f const a, TT const n);
// Raise floating point numbers to integer power n
template <>
inline Vec16f pow<int>(Vec16f const x0, int const n) {
return pow_template_i<Vec16f>(x0, n);
}
// allow conversion from unsigned int
template <>
inline Vec16f pow<uint32_t>(Vec16f const x0, uint32_t const n) {
return pow_template_i<Vec16f>(x0, (int)n);
}
// Raise floating point numbers to integer power n, where n is a compile-time constant
template <int n>
static inline Vec16f pow_n(Vec16f const a) {
if (n < 0) return Vec16f(1.0f) / pow_n<-n>(a);
if (n == 0) return Vec16f(1.0f);
if (n >= 256) return pow(a, n);
Vec16f x = a; // a^(2^i)
Vec16f y; // accumulator
const int lowest = n - (n & (n-1));// lowest set bit in n
if (n & 1) y = x;
if (n < 2) return y;
x = x*x; // x^2
if (n & 2) {
if (lowest == 2) y = x; else y *= x;
}
if (n < 4) return y;
x = x*x; // x^4
if (n & 4) {
if (lowest == 4) y = x; else y *= x;
}
if (n < 8) return y;
x = x*x; // x^8
if (n & 8) {
if (lowest == 8) y = x; else y *= x;
}
if (n < 16) return y;
x = x*x; // x^16
if (n & 16) {
if (lowest == 16) y = x; else y *= x;
}
if (n < 32) return y;
x = x*x; // x^32
if (n & 32) {
if (lowest == 32) y = x; else y *= x;
}
if (n < 64) return y;
x = x*x; // x^64
if (n & 64) {
if (lowest == 64) y = x; else y *= x;
}
if (n < 128) return y;
x = x*x; // x^128
if (n & 128) {
if (lowest == 128) y = x; else y *= x;
}
return y;
}
template <int n>
static inline Vec16f pow(Vec16f const a, Const_int_t<n>) {
return pow_n<n>(a);
}
// function round: round to nearest integer (even). (result as float vector)
static inline Vec16f round(Vec16f const a) {
return Vec16f(round(a.get_low()), round(a.get_high()));
}
// function truncate: round towards zero. (result as float vector)
static inline Vec16f truncate(Vec16f const a) {
return Vec16f(truncate(a.get_low()), truncate(a.get_high()));
}
// function floor: round towards minus infinity. (result as float vector)
static inline Vec16f floor(Vec16f const a) {
return Vec16f(floor(a.get_low()), floor(a.get_high()));
}
// function ceil: round towards plus infinity. (result as float vector)
static inline Vec16f ceil(Vec16f const a) {
return Vec16f(ceil(a.get_low()), ceil(a.get_high()));
}
// function roundi: round to nearest integer (even). (result as integer vector)
static inline Vec16i roundi(Vec16f const a) {
return Vec16i(roundi(a.get_low()), roundi(a.get_high()));
}
//static inline Vec16i round_to_int(Vec16f const a) {return roundi(a);} // deprecated
// function truncatei: round towards zero. (result as integer vector)
static inline Vec16i truncatei(Vec16f const a) {
return Vec16i(truncatei(a.get_low()), truncatei(a.get_high()));
}
//static inline Vec16i truncate_to_int(Vec16f const a) {return truncatei(a);} // deprecated
// function to_float: convert integer vector to float vector
static inline Vec16f to_float(Vec16i const a) {
return Vec16f(to_float(a.get_low()), to_float(a.get_high()));
}
// function to_float: convert unsigned integer vector to float vector
static inline Vec16f to_float(Vec16ui const a) {
return Vec16f(to_float(a.get_low()), to_float(a.get_high()));
}
// Approximate math functions
// approximate reciprocal (Faster than 1.f / a.
// relative accuracy better than 2^-11 without AVX512, 2^-14 with AVX512)
static inline Vec16f approx_recipr(Vec16f const a) {
return Vec16f(approx_recipr(a.get_low()), approx_recipr(a.get_high()));
}
// approximate reciprocal squareroot (Faster than 1.f / sqrt(a).
// Relative accuracy better than 2^-11 without AVX512, 2^-14 with AVX512)
static inline Vec16f approx_rsqrt(Vec16f const a) {
return Vec16f(approx_rsqrt(a.get_low()), approx_rsqrt(a.get_high()));
}
// Fused multiply and add functions
// Multiply and add
static inline Vec16f mul_add(Vec16f const a, Vec16f const b, Vec16f const c) {
return Vec16f(mul_add(a.get_low(), b.get_low(), c.get_low()), mul_add(a.get_high(), b.get_high(), c.get_high()));
}
// Multiply and subtract
static inline Vec16f mul_sub(Vec16f const a, Vec16f const b, Vec16f const c) {
return Vec16f(mul_sub(a.get_low(), b.get_low(), c.get_low()), mul_sub(a.get_high(), b.get_high(), c.get_high()));
}
// Multiply and inverse subtract
static inline Vec16f nmul_add(Vec16f const a, Vec16f const b, Vec16f const c) {
return Vec16f(nmul_add(a.get_low(), b.get_low(), c.get_low()), nmul_add(a.get_high(), b.get_high(), c.get_high()));
}
// Multiply and subtract with extra precision on the intermediate calculations,
// even if FMA instructions not supported, using Veltkamp-Dekker split
static inline Vec16f mul_sub_x(Vec16f const a, Vec16f const b, Vec16f const c) {
return Vec16f(mul_sub_x(a.get_low(), b.get_low(), c.get_low()), mul_sub_x(a.get_high(), b.get_high(), c.get_high()));
}
// Math functions using fast bit manipulation
// Extract the exponent as an integer
// exponent(a) = floor(log2(abs(a)));
// exponent(1.0f) = 0, exponent(0.0f) = -127, exponent(INF) = +128, exponent(NAN) = +128
static inline Vec16i exponent(Vec16f const a) {
return Vec16i(exponent(a.get_low()), exponent(a.get_high()));
}
// Extract the fraction part of a floating point number
// a = 2^exponent(a) * fraction(a), except for a = 0
// fraction(1.0f) = 1.0f, fraction(5.0f) = 1.25f
static inline Vec16f fraction(Vec16f const a) {
return Vec16f(fraction(a.get_low()), fraction(a.get_high()));
}
// Fast calculation of pow(2,n) with n integer
// n = 0 gives 1.0f
// n >= 128 gives +INF
// n <= -127 gives 0.0f
// This function will never produce denormals, and never raise exceptions
static inline Vec16f exp2(Vec16i const n) {
return Vec16f(exp2(n.get_low()), exp2(n.get_high()));
}
//static Vec16f exp2(Vec16f const x); // defined in vectormath_exp.h
// Categorization functions
// Function sign_bit: gives true for elements that have the sign bit set
// even for -0.0f, -INF and -NAN
// Note that sign_bit(Vec16f(-0.0f)) gives true, while Vec16f(-0.0f) < Vec16f(0.0f) gives false
// (the underscore in the name avoids a conflict with a macro in Intel's mathimf.h)
static inline Vec16fb sign_bit(Vec16f const a) {
return Vec16fb(sign_bit(a.get_low()), sign_bit(a.get_high()));
}
// Function sign_combine: changes the sign of a when b has the sign bit set
// same as select(sign_bit(b), -a, a)
static inline Vec16f sign_combine(Vec16f const a, Vec16f const b) {
return Vec16f(sign_combine(a.get_low(), b.get_low()), sign_combine(a.get_high(), b.get_high()));
}
// Function is_finite: gives true for elements that are normal, denormal or zero,
// false for INF and NAN
// (the underscore in the name avoids a conflict with a macro in Intel's mathimf.h)
static inline Vec16fb is_finite(Vec16f const a) {
return Vec16fb(is_finite(a.get_low()), is_finite(a.get_high()));
}
// Function is_inf: gives true for elements that are +INF or -INF
// false for finite numbers and NAN
// (the underscore in the name avoids a conflict with a macro in Intel's mathimf.h)
static inline Vec16fb is_inf(Vec16f const a) {
return Vec16fb(is_inf(a.get_low()), is_inf(a.get_high()));
}
// Function is_nan: gives true for elements that are +NAN or -NAN
// false for finite numbers and +/-INF
// (the underscore in the name avoids a conflict with a macro in Intel's mathimf.h)
static inline Vec16fb is_nan(Vec16f const a) {
return Vec16fb(is_nan(a.get_low()), is_nan(a.get_high()));
}
// Function is_subnormal: gives true for elements that are denormal (subnormal)
// false for finite numbers, zero, NAN and INF
static inline Vec16fb is_subnormal(Vec16f const a) {
return Vec16fb(is_subnormal(a.get_low()), is_subnormal(a.get_high()));
}
// Function is_zero_or_subnormal: gives true for elements that are zero or subnormal (denormal)
// false for finite numbers, NAN and INF
static inline Vec16fb is_zero_or_subnormal(Vec16f const a) {
return Vec16fb(is_zero_or_subnormal(a.get_low()), is_zero_or_subnormal(a.get_high()));
}
// Function infinite4f: returns a vector where all elements are +INF
static inline Vec16f infinite16f() {
Vec8f inf = infinite8f();
return Vec16f(inf, inf);
}
// Function nan4f: returns a vector where all elements are +NAN (quiet)
static inline Vec16f nan16f(uint32_t n = 0x10) {
Vec8f nan = nan8f(n);
return Vec16f(nan, nan);
}
// change signs on vectors Vec16f
// Each index i0 - i7 is 1 for changing sign on the corresponding element, 0 for no change
// ("static" is removed from change_sign templates because it seems to generate problems for
// the Clang compiler with nested template calls. "static" is probably superfluous anyway.)
template <int i0, int i1, int i2, int i3, int i4, int i5, int i6, int i7, int i8, int i9, int i10, int i11, int i12, int i13, int i14, int i15>
inline Vec16f change_sign(Vec16f const a) {
return Vec16f(change_sign<i0,i1,i2,i3,i4,i5,i6,i7>(a.get_low()), change_sign<i8,i9,i10,i11,i12,i13,i14,i15>(a.get_high()));
}
/*****************************************************************************
*
* Vec8d: Vector of 8 double precision floating point values
*
*****************************************************************************/
class Vec8d {
protected:
Vec4d z0;
Vec4d z1;
public:
// Default constructor:
Vec8d() = default;
// Constructor to broadcast the same value into all elements:
Vec8d(double d) {
z0 = z1 = Vec4d(d);
}
// Constructor to build from all elements:
Vec8d(double d0, double d1, double d2, double d3, double d4, double d5, double d6, double d7) {
z0 = Vec4d(d0, d1, d2, d3);
z1 = Vec4d(d4, d5, d6, d7);
}
// Constructor to build from two Vec4d:
Vec8d(Vec4d const a0, Vec4d const a1) {
z0 = a0;
z1 = a1;
}
// Member function to load from array (unaligned)
Vec8d & load(double const * p) {
z0.load(p);
z1.load(p+4);
return *this;
}
// Member function to load from array, aligned by 64
// You may use load_a instead of load if you are certain that p points to an address divisible by 64
Vec8d & load_a(double const * p) {
z0.load_a(p);
z1.load_a(p+4);
return *this;
}
// Member function to store into array (unaligned)
void store(double * p) const {
z0.store(p);
z1.store(p+4);
}
// Member function to store into array, aligned by 64
// You may use store_a instead of store if you are certain that p points to an address divisible by 64
void store_a(double * p) const {
z0.store_a(p);
z1.store_a(p+4);
}
// Member function storing to aligned uncached memory (non-temporal store).
// This may be more efficient than store_a when storing large blocks of memory if it