llvm-project/clang/lib/Headers/avxintrin.h

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/*===---- avxintrin.h - AVX intrinsics -------------------------------------===
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
*===-----------------------------------------------------------------------===
*/
#ifndef __IMMINTRIN_H
#error "Never use <avxintrin.h> directly; include <immintrin.h> instead."
#endif
#ifndef __AVXINTRIN_H
#define __AVXINTRIN_H
typedef double __v4df __attribute__ ((__vector_size__ (32)));
typedef float __v8sf __attribute__ ((__vector_size__ (32)));
typedef long long __v4di __attribute__ ((__vector_size__ (32)));
typedef int __v8si __attribute__ ((__vector_size__ (32)));
typedef short __v16hi __attribute__ ((__vector_size__ (32)));
typedef char __v32qi __attribute__ ((__vector_size__ (32)));
/* Unsigned types */
typedef unsigned long long __v4du __attribute__ ((__vector_size__ (32)));
typedef unsigned int __v8su __attribute__ ((__vector_size__ (32)));
typedef unsigned short __v16hu __attribute__ ((__vector_size__ (32)));
typedef unsigned char __v32qu __attribute__ ((__vector_size__ (32)));
Fix the SSE4 byte sign extension in a cleaner way, and more thoroughly test that our intrinsics behave the same under -fsigned-char and -funsigned-char. This further testing uncovered that AVX-2 has a broken cmpgt for 8-bit elements, and has for a long time. This is fixed in the same way as SSE4 handles the case. The other ISA extensions currently work correctly because they use specific instruction intrinsics. As soon as they are rewritten in terms of generic IR, they will need to add these special casts. I've added the necessary testing to catch this however, so we shouldn't have to chase it down again. I considered changing the core typedef to be signed, but that seems like a bad idea. Notably, it would be an ABI break if anyone is reaching into the innards of the intrinsic headers and passing __v16qi on an API boundary. I can't be completely confident that this wouldn't happen due to a macro expanding in a lambda, etc., so it seems much better to leave it alone. It also matches GCC's behavior exactly. A fun side note is that for both GCC and Clang, -funsigned-char really does change the semantics of __v16qi. To observe this, consider: % cat x.cc #include <smmintrin.h> #include <iostream> int main() { __v16qi a = { 1, -1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; __v16qi b = _mm_set1_epi8(-1); std::cout << (int)(a / b)[0] << ", " << (int)(a / b)[1] << '\n'; } % clang++ -o x x.cc && ./x -1, 1 % clang++ -funsigned-char -o x x.cc && ./x 0, 1 However, while this may be surprising, both Clang and GCC agree. Differential Revision: http://reviews.llvm.org/D13324 llvm-svn: 249097
2015-10-02 07:40:12 +08:00
/* We need an explicitly signed variant for char. Note that this shouldn't
* appear in the interface though. */
typedef signed char __v32qs __attribute__((__vector_size__(32)));
Fix the SSE4 byte sign extension in a cleaner way, and more thoroughly test that our intrinsics behave the same under -fsigned-char and -funsigned-char. This further testing uncovered that AVX-2 has a broken cmpgt for 8-bit elements, and has for a long time. This is fixed in the same way as SSE4 handles the case. The other ISA extensions currently work correctly because they use specific instruction intrinsics. As soon as they are rewritten in terms of generic IR, they will need to add these special casts. I've added the necessary testing to catch this however, so we shouldn't have to chase it down again. I considered changing the core typedef to be signed, but that seems like a bad idea. Notably, it would be an ABI break if anyone is reaching into the innards of the intrinsic headers and passing __v16qi on an API boundary. I can't be completely confident that this wouldn't happen due to a macro expanding in a lambda, etc., so it seems much better to leave it alone. It also matches GCC's behavior exactly. A fun side note is that for both GCC and Clang, -funsigned-char really does change the semantics of __v16qi. To observe this, consider: % cat x.cc #include <smmintrin.h> #include <iostream> int main() { __v16qi a = { 1, -1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; __v16qi b = _mm_set1_epi8(-1); std::cout << (int)(a / b)[0] << ", " << (int)(a / b)[1] << '\n'; } % clang++ -o x x.cc && ./x -1, 1 % clang++ -funsigned-char -o x x.cc && ./x 0, 1 However, while this may be surprising, both Clang and GCC agree. Differential Revision: http://reviews.llvm.org/D13324 llvm-svn: 249097
2015-10-02 07:40:12 +08:00
typedef float __m256 __attribute__ ((__vector_size__ (32)));
typedef double __m256d __attribute__((__vector_size__(32)));
typedef long long __m256i __attribute__((__vector_size__(32)));
/* Define the default attributes for the functions in this file. */
#define __DEFAULT_FN_ATTRS __attribute__((__always_inline__, __nodebug__, __target__("avx")))
/* Arithmetic */
/// Adds two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VADDPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \returns A 256-bit vector of [4 x double] containing the sums of both
/// operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_add_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4df)__a+(__v4df)__b);
}
/// Adds two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VADDPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \returns A 256-bit vector of [8 x float] containing the sums of both
/// operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_add_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8sf)__a+(__v8sf)__b);
}
/// Subtracts two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VSUBPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing the minuend.
/// \param __b
/// A 256-bit vector of [4 x double] containing the subtrahend.
/// \returns A 256-bit vector of [4 x double] containing the differences between
/// both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_sub_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4df)__a-(__v4df)__b);
}
/// Subtracts two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VSUBPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing the minuend.
/// \param __b
/// A 256-bit vector of [8 x float] containing the subtrahend.
/// \returns A 256-bit vector of [8 x float] containing the differences between
/// both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_sub_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8sf)__a-(__v8sf)__b);
}
/// Adds the even-indexed values and subtracts the odd-indexed values of
/// two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VADDSUBPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing the left source operand.
/// \param __b
/// A 256-bit vector of [4 x double] containing the right source operand.
/// \returns A 256-bit vector of [4 x double] containing the alternating sums
/// and differences between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_addsub_pd(__m256d __a, __m256d __b)
{
return (__m256d)__builtin_ia32_addsubpd256((__v4df)__a, (__v4df)__b);
}
/// Adds the even-indexed values and subtracts the odd-indexed values of
/// two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VADDSUBPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing the left source operand.
/// \param __b
/// A 256-bit vector of [8 x float] containing the right source operand.
/// \returns A 256-bit vector of [8 x float] containing the alternating sums and
/// differences between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_addsub_ps(__m256 __a, __m256 __b)
{
return (__m256)__builtin_ia32_addsubps256((__v8sf)__a, (__v8sf)__b);
}
/// Divides two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VDIVPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing the dividend.
/// \param __b
/// A 256-bit vector of [4 x double] containing the divisor.
/// \returns A 256-bit vector of [4 x double] containing the quotients of both
/// operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_div_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4df)__a/(__v4df)__b);
}
/// Divides two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VDIVPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing the dividend.
/// \param __b
/// A 256-bit vector of [8 x float] containing the divisor.
/// \returns A 256-bit vector of [8 x float] containing the quotients of both
/// operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_div_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8sf)__a/(__v8sf)__b);
}
/// Compares two 256-bit vectors of [4 x double] and returns the greater
/// of each pair of values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMAXPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \returns A 256-bit vector of [4 x double] containing the maximum values
/// between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_max_pd(__m256d __a, __m256d __b)
{
return (__m256d)__builtin_ia32_maxpd256((__v4df)__a, (__v4df)__b);
}
/// Compares two 256-bit vectors of [8 x float] and returns the greater
/// of each pair of values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMAXPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \returns A 256-bit vector of [8 x float] containing the maximum values
/// between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_max_ps(__m256 __a, __m256 __b)
{
return (__m256)__builtin_ia32_maxps256((__v8sf)__a, (__v8sf)__b);
}
/// Compares two 256-bit vectors of [4 x double] and returns the lesser
/// of each pair of values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMINPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \returns A 256-bit vector of [4 x double] containing the minimum values
/// between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_min_pd(__m256d __a, __m256d __b)
{
return (__m256d)__builtin_ia32_minpd256((__v4df)__a, (__v4df)__b);
}
/// Compares two 256-bit vectors of [8 x float] and returns the lesser
/// of each pair of values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMINPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \returns A 256-bit vector of [8 x float] containing the minimum values
/// between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_min_ps(__m256 __a, __m256 __b)
{
return (__m256)__builtin_ia32_minps256((__v8sf)__a, (__v8sf)__b);
}
/// Multiplies two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMULPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the operands.
/// \returns A 256-bit vector of [4 x double] containing the products of both
/// operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_mul_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4df)__a * (__v4df)__b);
}
/// Multiplies two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMULPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the operands.
/// \returns A 256-bit vector of [8 x float] containing the products of both
/// operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_mul_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8sf)__a * (__v8sf)__b);
}
/// Calculates the square roots of the values in a 256-bit vector of
/// [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VSQRTPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \returns A 256-bit vector of [4 x double] containing the square roots of the
/// values in the operand.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_sqrt_pd(__m256d __a)
{
return (__m256d)__builtin_ia32_sqrtpd256((__v4df)__a);
}
/// Calculates the square roots of the values in a 256-bit vector of
/// [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VSQRTPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the square roots of the
/// values in the operand.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_sqrt_ps(__m256 __a)
{
return (__m256)__builtin_ia32_sqrtps256((__v8sf)__a);
}
/// Calculates the reciprocal square roots of the values in a 256-bit
/// vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VRSQRTPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the reciprocal square
/// roots of the values in the operand.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_rsqrt_ps(__m256 __a)
{
return (__m256)__builtin_ia32_rsqrtps256((__v8sf)__a);
}
/// Calculates the reciprocals of the values in a 256-bit vector of
/// [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VRCPPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the reciprocals of the
/// values in the operand.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_rcp_ps(__m256 __a)
{
return (__m256)__builtin_ia32_rcpps256((__v8sf)__a);
}
/// Rounds the values in a 256-bit vector of [4 x double] as specified
/// by the byte operand. The source values are rounded to integer values and
/// returned as 64-bit double-precision floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_round_pd(__m256d V, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPD </c> instruction.
///
/// \param V
/// A 256-bit vector of [4 x double].
/// \param M
/// An integer value that specifies the rounding operation. \n
/// Bits [7:4] are reserved. \n
/// Bit [3] is a precision exception value: \n
/// 0: A normal PE exception is used. \n
/// 1: The PE field is not updated. \n
/// Bit [2] is the rounding control source: \n
/// 0: Use bits [1:0] of \a M. \n
/// 1: Use the current MXCSR setting. \n
/// Bits [1:0] contain the rounding control definition: \n
/// 00: Nearest. \n
/// 01: Downward (toward negative infinity). \n
/// 10: Upward (toward positive infinity). \n
/// 11: Truncated.
/// \returns A 256-bit vector of [4 x double] containing the rounded values.
#define _mm256_round_pd(V, M) \
(__m256d)__builtin_ia32_roundpd256((__v4df)(__m256d)(V), (M))
/// Rounds the values stored in a 256-bit vector of [8 x float] as
/// specified by the byte operand. The source values are rounded to integer
/// values and returned as floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_round_ps(__m256 V, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPS </c> instruction.
///
/// \param V
/// A 256-bit vector of [8 x float].
/// \param M
/// An integer value that specifies the rounding operation. \n
/// Bits [7:4] are reserved. \n
/// Bit [3] is a precision exception value: \n
/// 0: A normal PE exception is used. \n
/// 1: The PE field is not updated. \n
/// Bit [2] is the rounding control source: \n
/// 0: Use bits [1:0] of \a M. \n
/// 1: Use the current MXCSR setting. \n
/// Bits [1:0] contain the rounding control definition: \n
/// 00: Nearest. \n
/// 01: Downward (toward negative infinity). \n
/// 10: Upward (toward positive infinity). \n
/// 11: Truncated.
/// \returns A 256-bit vector of [8 x float] containing the rounded values.
#define _mm256_round_ps(V, M) \
(__m256)__builtin_ia32_roundps256((__v8sf)(__m256)(V), (M))
/// Rounds up the values stored in a 256-bit vector of [4 x double]. The
/// source values are rounded up to integer values and returned as 64-bit
/// double-precision floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_ceil_pd(__m256d V);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPD </c> instruction.
///
/// \param V
/// A 256-bit vector of [4 x double].
/// \returns A 256-bit vector of [4 x double] containing the rounded up values.
#define _mm256_ceil_pd(V) _mm256_round_pd((V), _MM_FROUND_CEIL)
/// Rounds down the values stored in a 256-bit vector of [4 x double].
/// The source values are rounded down to integer values and returned as
/// 64-bit double-precision floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_floor_pd(__m256d V);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPD </c> instruction.
///
/// \param V
/// A 256-bit vector of [4 x double].
/// \returns A 256-bit vector of [4 x double] containing the rounded down
/// values.
#define _mm256_floor_pd(V) _mm256_round_pd((V), _MM_FROUND_FLOOR)
/// Rounds up the values stored in a 256-bit vector of [8 x float]. The
/// source values are rounded up to integer values and returned as
/// floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_ceil_ps(__m256 V);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPS </c> instruction.
///
/// \param V
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the rounded up values.
#define _mm256_ceil_ps(V) _mm256_round_ps((V), _MM_FROUND_CEIL)
/// Rounds down the values stored in a 256-bit vector of [8 x float]. The
/// source values are rounded down to integer values and returned as
/// floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_floor_ps(__m256 V);
/// \endcode
///
/// This intrinsic corresponds to the <c> VROUNDPS </c> instruction.
///
/// \param V
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the rounded down values.
#define _mm256_floor_ps(V) _mm256_round_ps((V), _MM_FROUND_FLOOR)
/* Logical */
/// Performs a bitwise AND of two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VANDPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \returns A 256-bit vector of [4 x double] containing the bitwise AND of the
/// values between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_and_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4du)__a & (__v4du)__b);
}
/// Performs a bitwise AND of two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VANDPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \returns A 256-bit vector of [8 x float] containing the bitwise AND of the
/// values between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_and_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8su)__a & (__v8su)__b);
}
/// Performs a bitwise AND of two 256-bit vectors of [4 x double], using
/// the one's complement of the values contained in the first source operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VANDNPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing the left source operand. The
/// one's complement of this value is used in the bitwise AND.
/// \param __b
/// A 256-bit vector of [4 x double] containing the right source operand.
/// \returns A 256-bit vector of [4 x double] containing the bitwise AND of the
/// values of the second operand and the one's complement of the first
/// operand.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_andnot_pd(__m256d __a, __m256d __b)
{
return (__m256d)(~(__v4du)__a & (__v4du)__b);
}
/// Performs a bitwise AND of two 256-bit vectors of [8 x float], using
/// the one's complement of the values contained in the first source operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VANDNPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing the left source operand. The
/// one's complement of this value is used in the bitwise AND.
/// \param __b
/// A 256-bit vector of [8 x float] containing the right source operand.
/// \returns A 256-bit vector of [8 x float] containing the bitwise AND of the
/// values of the second operand and the one's complement of the first
/// operand.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_andnot_ps(__m256 __a, __m256 __b)
{
return (__m256)(~(__v8su)__a & (__v8su)__b);
}
/// Performs a bitwise OR of two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VORPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \returns A 256-bit vector of [4 x double] containing the bitwise OR of the
/// values between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_or_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4du)__a | (__v4du)__b);
}
/// Performs a bitwise OR of two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VORPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \returns A 256-bit vector of [8 x float] containing the bitwise OR of the
/// values between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_or_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8su)__a | (__v8su)__b);
}
/// Performs a bitwise XOR of two 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VXORPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// \returns A 256-bit vector of [4 x double] containing the bitwise XOR of the
/// values between both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_xor_pd(__m256d __a, __m256d __b)
{
return (__m256d)((__v4du)__a ^ (__v4du)__b);
}
/// Performs a bitwise XOR of two 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VXORPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// \returns A 256-bit vector of [8 x float] containing the bitwise XOR of the
/// values between both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_xor_ps(__m256 __a, __m256 __b)
{
return (__m256)((__v8su)__a ^ (__v8su)__b);
}
/* Horizontal arithmetic */
/// Horizontally adds the adjacent pairs of values contained in two
/// 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VHADDPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// The horizontal sums of the values are returned in the even-indexed
/// elements of a vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// The horizontal sums of the values are returned in the odd-indexed
/// elements of a vector of [4 x double].
/// \returns A 256-bit vector of [4 x double] containing the horizontal sums of
/// both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_hadd_pd(__m256d __a, __m256d __b)
{
return (__m256d)__builtin_ia32_haddpd256((__v4df)__a, (__v4df)__b);
}
/// Horizontally adds the adjacent pairs of values contained in two
/// 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VHADDPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// The horizontal sums of the values are returned in the elements with
/// index 0, 1, 4, 5 of a vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// The horizontal sums of the values are returned in the elements with
/// index 2, 3, 6, 7 of a vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the horizontal sums of
/// both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_hadd_ps(__m256 __a, __m256 __b)
{
return (__m256)__builtin_ia32_haddps256((__v8sf)__a, (__v8sf)__b);
}
/// Horizontally subtracts the adjacent pairs of values contained in two
/// 256-bit vectors of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VHSUBPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// The horizontal differences between the values are returned in the
/// even-indexed elements of a vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double] containing one of the source operands.
/// The horizontal differences between the values are returned in the
/// odd-indexed elements of a vector of [4 x double].
/// \returns A 256-bit vector of [4 x double] containing the horizontal
/// differences of both operands.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_hsub_pd(__m256d __a, __m256d __b)
{
return (__m256d)__builtin_ia32_hsubpd256((__v4df)__a, (__v4df)__b);
}
/// Horizontally subtracts the adjacent pairs of values contained in two
/// 256-bit vectors of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VHSUBPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// The horizontal differences between the values are returned in the
/// elements with index 0, 1, 4, 5 of a vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float] containing one of the source operands.
/// The horizontal differences between the values are returned in the
/// elements with index 2, 3, 6, 7 of a vector of [8 x float].
/// \returns A 256-bit vector of [8 x float] containing the horizontal
/// differences of both operands.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_hsub_ps(__m256 __a, __m256 __b)
{
return (__m256)__builtin_ia32_hsubps256((__v8sf)__a, (__v8sf)__b);
}
/* Vector permutations */
/// Copies the values in a 128-bit vector of [2 x double] as specified
/// by the 128-bit integer vector operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPD </c> instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \param __c
/// A 128-bit integer vector operand specifying how the values are to be
/// copied. \n
/// Bit [1]: \n
/// 0: Bits [63:0] of the source are copied to bits [63:0] of the returned
/// vector. \n
/// 1: Bits [127:64] of the source are copied to bits [63:0] of the
/// returned vector. \n
/// Bit [65]: \n
/// 0: Bits [63:0] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// 1: Bits [127:64] of the source are copied to bits [127:64] of the
/// returned vector.
/// \returns A 128-bit vector of [2 x double] containing the copied values.
static __inline __m128d __DEFAULT_FN_ATTRS
_mm_permutevar_pd(__m128d __a, __m128i __c)
{
return (__m128d)__builtin_ia32_vpermilvarpd((__v2df)__a, (__v2di)__c);
}
/// Copies the values in a 256-bit vector of [4 x double] as specified
/// by the 256-bit integer vector operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \param __c
/// A 256-bit integer vector operand specifying how the values are to be
/// copied. \n
/// Bit [1]: \n
/// 0: Bits [63:0] of the source are copied to bits [63:0] of the returned
/// vector. \n
/// 1: Bits [127:64] of the source are copied to bits [63:0] of the
/// returned vector. \n
/// Bit [65]: \n
/// 0: Bits [63:0] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// 1: Bits [127:64] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// Bit [129]: \n
/// 0: Bits [191:128] of the source are copied to bits [191:128] of the
/// returned vector. \n
/// 1: Bits [255:192] of the source are copied to bits [191:128] of the
/// returned vector. \n
/// Bit [193]: \n
/// 0: Bits [191:128] of the source are copied to bits [255:192] of the
/// returned vector. \n
/// 1: Bits [255:192] of the source are copied to bits [255:192] of the
/// returned vector.
/// \returns A 256-bit vector of [4 x double] containing the copied values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_permutevar_pd(__m256d __a, __m256i __c)
{
return (__m256d)__builtin_ia32_vpermilvarpd256((__v4df)__a, (__v4di)__c);
}
/// Copies the values stored in a 128-bit vector of [4 x float] as
/// specified by the 128-bit integer vector operand.
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPS </c> instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \param __c
/// A 128-bit integer vector operand specifying how the values are to be
/// copied. \n
/// Bits [1:0]: \n
/// 00: Bits [31:0] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// Bits [33:32]: \n
/// 00: Bits [31:0] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// Bits [65:64]: \n
/// 00: Bits [31:0] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// Bits [97:96]: \n
/// 00: Bits [31:0] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [127:96] of the
/// returned vector.
/// \returns A 128-bit vector of [4 x float] containing the copied values.
static __inline __m128 __DEFAULT_FN_ATTRS
_mm_permutevar_ps(__m128 __a, __m128i __c)
{
return (__m128)__builtin_ia32_vpermilvarps((__v4sf)__a, (__v4si)__c);
}
/// Copies the values stored in a 256-bit vector of [8 x float] as
/// specified by the 256-bit integer vector operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \param __c
/// A 256-bit integer vector operand specifying how the values are to be
/// copied. \n
/// Bits [1:0]: \n
/// 00: Bits [31:0] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// Bits [33:32]: \n
/// 00: Bits [31:0] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// Bits [65:64]: \n
/// 00: Bits [31:0] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// Bits [97:96]: \n
/// 00: Bits [31:0] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// Bits [129:128]: \n
/// 00: Bits [159:128] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// Bits [161:160]: \n
/// 00: Bits [159:128] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// Bits [193:192]: \n
/// 00: Bits [159:128] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// Bits [225:224]: \n
/// 00: Bits [159:128] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [255:224] of the
/// returned vector.
/// \returns A 256-bit vector of [8 x float] containing the copied values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_permutevar_ps(__m256 __a, __m256i __c)
{
return (__m256)__builtin_ia32_vpermilvarps256((__v8sf)__a, (__v8si)__c);
}
/// Copies the values in a 128-bit vector of [2 x double] as specified
/// by the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128d _mm_permute_pd(__m128d A, const int C);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERMILPD </c> instruction.
///
/// \param A
/// A 128-bit vector of [2 x double].
/// \param C
/// An immediate integer operand specifying how the values are to be
/// copied. \n
/// Bit [0]: \n
/// 0: Bits [63:0] of the source are copied to bits [63:0] of the returned
/// vector. \n
/// 1: Bits [127:64] of the source are copied to bits [63:0] of the
/// returned vector. \n
/// Bit [1]: \n
/// 0: Bits [63:0] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// 1: Bits [127:64] of the source are copied to bits [127:64] of the
/// returned vector.
/// \returns A 128-bit vector of [2 x double] containing the copied values.
#define _mm_permute_pd(A, C) \
(__m128d)__builtin_ia32_vpermilpd((__v2df)(__m128d)(A), (int)(C))
/// Copies the values in a 256-bit vector of [4 x double] as specified by
/// the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_permute_pd(__m256d A, const int C);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERMILPD </c> instruction.
///
/// \param A
/// A 256-bit vector of [4 x double].
/// \param C
/// An immediate integer operand specifying how the values are to be
/// copied. \n
/// Bit [0]: \n
/// 0: Bits [63:0] of the source are copied to bits [63:0] of the returned
/// vector. \n
/// 1: Bits [127:64] of the source are copied to bits [63:0] of the
/// returned vector. \n
/// Bit [1]: \n
/// 0: Bits [63:0] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// 1: Bits [127:64] of the source are copied to bits [127:64] of the
/// returned vector. \n
/// Bit [2]: \n
/// 0: Bits [191:128] of the source are copied to bits [191:128] of the
/// returned vector. \n
/// 1: Bits [255:192] of the source are copied to bits [191:128] of the
/// returned vector. \n
/// Bit [3]: \n
/// 0: Bits [191:128] of the source are copied to bits [255:192] of the
/// returned vector. \n
/// 1: Bits [255:192] of the source are copied to bits [255:192] of the
/// returned vector.
/// \returns A 256-bit vector of [4 x double] containing the copied values.
#define _mm256_permute_pd(A, C) \
(__m256d)__builtin_ia32_vpermilpd256((__v4df)(__m256d)(A), (int)(C))
/// Copies the values in a 128-bit vector of [4 x float] as specified by
/// the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128 _mm_permute_ps(__m128 A, const int C);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERMILPS </c> instruction.
///
/// \param A
/// A 128-bit vector of [4 x float].
/// \param C
/// An immediate integer operand specifying how the values are to be
/// copied. \n
/// Bits [1:0]: \n
/// 00: Bits [31:0] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// Bits [3:2]: \n
/// 00: Bits [31:0] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// Bits [5:4]: \n
/// 00: Bits [31:0] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// Bits [7:6]: \n
/// 00: Bits [31:0] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [127:96] of the
/// returned vector.
/// \returns A 128-bit vector of [4 x float] containing the copied values.
#define _mm_permute_ps(A, C) \
(__m128)__builtin_ia32_vpermilps((__v4sf)(__m128)(A), (int)(C))
/// Copies the values in a 256-bit vector of [8 x float] as specified by
/// the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_permute_ps(__m256 A, const int C);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERMILPS </c> instruction.
///
/// \param A
/// A 256-bit vector of [8 x float].
/// \param C
/// An immediate integer operand specifying how the values are to be
/// copied. \n
/// Bits [1:0]: \n
/// 00: Bits [31:0] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [31:0] of the
/// returned vector. \n
/// Bits [3:2]: \n
/// 00: Bits [31:0] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [63:32] of the
/// returned vector. \n
/// Bits [5:4]: \n
/// 00: Bits [31:0] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [95:64] of the
/// returned vector. \n
/// Bits [7:6]: \n
/// 00: Bits [31:0] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 01: Bits [63:32] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 10: Bits [95:64] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// 11: Bits [127:96] of the source are copied to bits [127:96] of the
/// returned vector. \n
/// Bits [1:0]: \n
/// 00: Bits [159:128] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [159:128] of the
/// returned vector. \n
/// Bits [3:2]: \n
/// 00: Bits [159:128] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [191:160] of the
/// returned vector. \n
/// Bits [5:4]: \n
/// 00: Bits [159:128] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [223:192] of the
/// returned vector. \n
/// Bits [7:6]: \n
/// 00: Bits [159:128] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 01: Bits [191:160] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 10: Bits [223:192] of the source are copied to bits [255:224] of the
/// returned vector. \n
/// 11: Bits [255:224] of the source are copied to bits [255:224] of the
/// returned vector.
/// \returns A 256-bit vector of [8 x float] containing the copied values.
#define _mm256_permute_ps(A, C) \
(__m256)__builtin_ia32_vpermilps256((__v8sf)(__m256)(A), (int)(C))
/// Permutes 128-bit data values stored in two 256-bit vectors of
/// [4 x double], as specified by the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_permute2f128_pd(__m256d V1, __m256d V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERM2F128 </c> instruction.
///
/// \param V1
/// A 256-bit vector of [4 x double].
/// \param V2
/// A 256-bit vector of [4 x double.
/// \param M
/// An immediate integer operand specifying how the values are to be
/// permuted. \n
/// Bits [1:0]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// Bits [5:4]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [255:128] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [255:128] of the
/// destination.
/// \returns A 256-bit vector of [4 x double] containing the copied values.
#define _mm256_permute2f128_pd(V1, V2, M) \
(__m256d)__builtin_ia32_vperm2f128_pd256((__v4df)(__m256d)(V1), \
(__v4df)(__m256d)(V2), (M))
/// Permutes 128-bit data values stored in two 256-bit vectors of
/// [8 x float], as specified by the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_permute2f128_ps(__m256 V1, __m256 V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERM2F128 </c> instruction.
///
/// \param V1
/// A 256-bit vector of [8 x float].
/// \param V2
/// A 256-bit vector of [8 x float].
/// \param M
/// An immediate integer operand specifying how the values are to be
/// permuted. \n
/// Bits [1:0]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// Bits [5:4]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [255:128] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [255:128] of the
/// destination.
/// \returns A 256-bit vector of [8 x float] containing the copied values.
#define _mm256_permute2f128_ps(V1, V2, M) \
(__m256)__builtin_ia32_vperm2f128_ps256((__v8sf)(__m256)(V1), \
(__v8sf)(__m256)(V2), (M))
/// Permutes 128-bit data values stored in two 256-bit integer vectors,
/// as specified by the immediate integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256i _mm256_permute2f128_si256(__m256i V1, __m256i V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VPERM2F128 </c> instruction.
///
/// \param V1
/// A 256-bit integer vector.
/// \param V2
/// A 256-bit integer vector.
/// \param M
/// An immediate integer operand specifying how the values are to be copied.
/// Bits [1:0]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [127:0] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [127:0] of the
/// destination. \n
/// Bits [5:4]: \n
/// 00: Bits [127:0] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 01: Bits [255:128] of operand \a V1 are copied to bits [255:128] of the
/// destination. \n
/// 10: Bits [127:0] of operand \a V2 are copied to bits [255:128] of the
/// destination. \n
/// 11: Bits [255:128] of operand \a V2 are copied to bits [255:128] of the
/// destination.
/// \returns A 256-bit integer vector containing the copied values.
#define _mm256_permute2f128_si256(V1, V2, M) \
(__m256i)__builtin_ia32_vperm2f128_si256((__v8si)(__m256i)(V1), \
(__v8si)(__m256i)(V2), (M))
/* Vector Blend */
/// Merges 64-bit double-precision data values stored in either of the
/// two 256-bit vectors of [4 x double], as specified by the immediate
/// integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_blend_pd(__m256d V1, __m256d V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VBLENDPD </c> instruction.
///
/// \param V1
/// A 256-bit vector of [4 x double].
/// \param V2
/// A 256-bit vector of [4 x double].
/// \param M
/// An immediate integer operand, with mask bits [3:0] specifying how the
/// values are to be copied. The position of the mask bit corresponds to the
/// index of a copied value. When a mask bit is 0, the corresponding 64-bit
/// element in operand \a V1 is copied to the same position in the
/// destination. When a mask bit is 1, the corresponding 64-bit element in
/// operand \a V2 is copied to the same position in the destination.
/// \returns A 256-bit vector of [4 x double] containing the copied values.
#define _mm256_blend_pd(V1, V2, M) \
(__m256d)__builtin_ia32_blendpd256((__v4df)(__m256d)(V1), \
(__v4df)(__m256d)(V2), (int)(M))
/// Merges 32-bit single-precision data values stored in either of the
/// two 256-bit vectors of [8 x float], as specified by the immediate
/// integer operand.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_blend_ps(__m256 V1, __m256 V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VBLENDPS </c> instruction.
///
/// \param V1
/// A 256-bit vector of [8 x float].
/// \param V2
/// A 256-bit vector of [8 x float].
/// \param M
/// An immediate integer operand, with mask bits [7:0] specifying how the
/// values are to be copied. The position of the mask bit corresponds to the
/// index of a copied value. When a mask bit is 0, the corresponding 32-bit
/// element in operand \a V1 is copied to the same position in the
/// destination. When a mask bit is 1, the corresponding 32-bit element in
/// operand \a V2 is copied to the same position in the destination.
/// \returns A 256-bit vector of [8 x float] containing the copied values.
#define _mm256_blend_ps(V1, V2, M) \
(__m256)__builtin_ia32_blendps256((__v8sf)(__m256)(V1), \
(__v8sf)(__m256)(V2), (int)(M))
/// Merges 64-bit double-precision data values stored in either of the
/// two 256-bit vectors of [4 x double], as specified by the 256-bit vector
/// operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBLENDVPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double].
/// \param __c
/// A 256-bit vector operand, with mask bits 255, 191, 127, and 63 specifying
/// how the values are to be copied. The position of the mask bit corresponds
/// to the most significant bit of a copied value. When a mask bit is 0, the
/// corresponding 64-bit element in operand \a __a is copied to the same
/// position in the destination. When a mask bit is 1, the corresponding
/// 64-bit element in operand \a __b is copied to the same position in the
/// destination.
/// \returns A 256-bit vector of [4 x double] containing the copied values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_blendv_pd(__m256d __a, __m256d __b, __m256d __c)
{
return (__m256d)__builtin_ia32_blendvpd256(
(__v4df)__a, (__v4df)__b, (__v4df)__c);
}
/// Merges 32-bit single-precision data values stored in either of the
/// two 256-bit vectors of [8 x float], as specified by the 256-bit vector
/// operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBLENDVPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float].
/// \param __c
/// A 256-bit vector operand, with mask bits 255, 223, 191, 159, 127, 95, 63,
/// and 31 specifying how the values are to be copied. The position of the
/// mask bit corresponds to the most significant bit of a copied value. When
/// a mask bit is 0, the corresponding 32-bit element in operand \a __a is
/// copied to the same position in the destination. When a mask bit is 1, the
/// corresponding 32-bit element in operand \a __b is copied to the same
/// position in the destination.
/// \returns A 256-bit vector of [8 x float] containing the copied values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_blendv_ps(__m256 __a, __m256 __b, __m256 __c)
{
return (__m256)__builtin_ia32_blendvps256(
(__v8sf)__a, (__v8sf)__b, (__v8sf)__c);
}
/* Vector Dot Product */
/// Computes two dot products in parallel, using the lower and upper
/// halves of two [8 x float] vectors as input to the two computations, and
/// returning the two dot products in the lower and upper halves of the
/// [8 x float] result.
///
/// The immediate integer operand controls which input elements will
/// contribute to the dot product, and where the final results are returned.
/// In general, for each dot product, the four corresponding elements of the
/// input vectors are multiplied; the first two and second two products are
/// summed, then the two sums are added to form the final result.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_dp_ps(__m256 V1, __m256 V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VDPPS </c> instruction.
///
/// \param V1
/// A vector of [8 x float] values, treated as two [4 x float] vectors.
/// \param V2
/// A vector of [8 x float] values, treated as two [4 x float] vectors.
/// \param M
/// An immediate integer argument. Bits [7:4] determine which elements of
/// the input vectors are used, with bit [4] corresponding to the lowest
/// element and bit [7] corresponding to the highest element of each [4 x
/// float] subvector. If a bit is set, the corresponding elements from the
/// two input vectors are used as an input for dot product; otherwise that
/// input is treated as zero. Bits [3:0] determine which elements of the
/// result will receive a copy of the final dot product, with bit [0]
/// corresponding to the lowest element and bit [3] corresponding to the
/// highest element of each [4 x float] subvector. If a bit is set, the dot
/// product is returned in the corresponding element; otherwise that element
/// is set to zero. The bitmask is applied in the same way to each of the
/// two parallel dot product computations.
/// \returns A 256-bit vector of [8 x float] containing the two dot products.
#define _mm256_dp_ps(V1, V2, M) \
(__m256)__builtin_ia32_dpps256((__v8sf)(__m256)(V1), \
(__v8sf)(__m256)(V2), (M))
/* Vector shuffle */
/// Selects 8 float values from the 256-bit operands of [8 x float], as
/// specified by the immediate value operand.
///
/// The four selected elements in each operand are copied to the destination
/// according to the bits specified in the immediate operand. The selected
/// elements from the first 256-bit operand are copied to bits [63:0] and
/// bits [191:128] of the destination, and the selected elements from the
/// second 256-bit operand are copied to bits [127:64] and bits [255:192] of
/// the destination. For example, if bits [7:0] of the immediate operand
/// contain a value of 0xFF, the 256-bit destination vector would contain the
/// following values: b[7], b[7], a[7], a[7], b[3], b[3], a[3], a[3].
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_shuffle_ps(__m256 a, __m256 b, const int mask);
/// \endcode
///
/// This intrinsic corresponds to the <c> VSHUFPS </c> instruction.
///
/// \param a
/// A 256-bit vector of [8 x float]. The four selected elements in this
/// operand are copied to bits [63:0] and bits [191:128] in the destination,
/// according to the bits specified in the immediate operand.
/// \param b
/// A 256-bit vector of [8 x float]. The four selected elements in this
/// operand are copied to bits [127:64] and bits [255:192] in the
/// destination, according to the bits specified in the immediate operand.
/// \param mask
/// An immediate value containing an 8-bit value specifying which elements to
/// copy from \a a and \a b \n.
/// Bits [3:0] specify the values copied from operand \a a. \n
/// Bits [7:4] specify the values copied from operand \a b. \n
/// The destinations within the 256-bit destination are assigned values as
/// follows, according to the bit value assignments described below: \n
/// Bits [1:0] are used to assign values to bits [31:0] and [159:128] in the
/// destination. \n
/// Bits [3:2] are used to assign values to bits [63:32] and [191:160] in the
/// destination. \n
/// Bits [5:4] are used to assign values to bits [95:64] and [223:192] in the
/// destination. \n
/// Bits [7:6] are used to assign values to bits [127:96] and [255:224] in
/// the destination. \n
/// Bit value assignments: \n
/// 00: Bits [31:0] and [159:128] are copied from the selected operand. \n
/// 01: Bits [63:32] and [191:160] are copied from the selected operand. \n
/// 10: Bits [95:64] and [223:192] are copied from the selected operand. \n
/// 11: Bits [127:96] and [255:224] are copied from the selected operand.
/// \returns A 256-bit vector of [8 x float] containing the shuffled values.
#define _mm256_shuffle_ps(a, b, mask) \
(__m256)__builtin_shufflevector((__v8sf)(__m256)(a), \
(__v8sf)(__m256)(b), \
0 + (((mask) >> 0) & 0x3), \
0 + (((mask) >> 2) & 0x3), \
8 + (((mask) >> 4) & 0x3), \
8 + (((mask) >> 6) & 0x3), \
4 + (((mask) >> 0) & 0x3), \
4 + (((mask) >> 2) & 0x3), \
12 + (((mask) >> 4) & 0x3), \
12 + (((mask) >> 6) & 0x3))
/// Selects four double-precision values from the 256-bit operands of
/// [4 x double], as specified by the immediate value operand.
///
/// The selected elements from the first 256-bit operand are copied to bits
/// [63:0] and bits [191:128] in the destination, and the selected elements
/// from the second 256-bit operand are copied to bits [127:64] and bits
/// [255:192] in the destination. For example, if bits [3:0] of the immediate
/// operand contain a value of 0xF, the 256-bit destination vector would
/// contain the following values: b[3], a[3], b[1], a[1].
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_shuffle_pd(__m256d a, __m256d b, const int mask);
/// \endcode
///
/// This intrinsic corresponds to the <c> VSHUFPD </c> instruction.
///
/// \param a
/// A 256-bit vector of [4 x double].
/// \param b
/// A 256-bit vector of [4 x double].
/// \param mask
/// An immediate value containing 8-bit values specifying which elements to
/// copy from \a a and \a b: \n
/// Bit [0]=0: Bits [63:0] are copied from \a a to bits [63:0] of the
/// destination. \n
/// Bit [0]=1: Bits [127:64] are copied from \a a to bits [63:0] of the
/// destination. \n
/// Bit [1]=0: Bits [63:0] are copied from \a b to bits [127:64] of the
/// destination. \n
/// Bit [1]=1: Bits [127:64] are copied from \a b to bits [127:64] of the
/// destination. \n
/// Bit [2]=0: Bits [191:128] are copied from \a a to bits [191:128] of the
/// destination. \n
/// Bit [2]=1: Bits [255:192] are copied from \a a to bits [191:128] of the
/// destination. \n
/// Bit [3]=0: Bits [191:128] are copied from \a b to bits [255:192] of the
/// destination. \n
/// Bit [3]=1: Bits [255:192] are copied from \a b to bits [255:192] of the
/// destination.
/// \returns A 256-bit vector of [4 x double] containing the shuffled values.
#define _mm256_shuffle_pd(a, b, mask) \
(__m256d)__builtin_shufflevector((__v4df)(__m256d)(a), \
(__v4df)(__m256d)(b), \
0 + (((mask) >> 0) & 0x1), \
4 + (((mask) >> 1) & 0x1), \
2 + (((mask) >> 2) & 0x1), \
6 + (((mask) >> 3) & 0x1))
/* Compare */
#define _CMP_EQ_OQ 0x00 /* Equal (ordered, non-signaling) */
#define _CMP_LT_OS 0x01 /* Less-than (ordered, signaling) */
#define _CMP_LE_OS 0x02 /* Less-than-or-equal (ordered, signaling) */
#define _CMP_UNORD_Q 0x03 /* Unordered (non-signaling) */
#define _CMP_NEQ_UQ 0x04 /* Not-equal (unordered, non-signaling) */
#define _CMP_NLT_US 0x05 /* Not-less-than (unordered, signaling) */
#define _CMP_NLE_US 0x06 /* Not-less-than-or-equal (unordered, signaling) */
#define _CMP_ORD_Q 0x07 /* Ordered (non-signaling) */
#define _CMP_EQ_UQ 0x08 /* Equal (unordered, non-signaling) */
#define _CMP_NGE_US 0x09 /* Not-greater-than-or-equal (unordered, signaling) */
#define _CMP_NGT_US 0x0a /* Not-greater-than (unordered, signaling) */
#define _CMP_FALSE_OQ 0x0b /* False (ordered, non-signaling) */
#define _CMP_NEQ_OQ 0x0c /* Not-equal (ordered, non-signaling) */
#define _CMP_GE_OS 0x0d /* Greater-than-or-equal (ordered, signaling) */
#define _CMP_GT_OS 0x0e /* Greater-than (ordered, signaling) */
#define _CMP_TRUE_UQ 0x0f /* True (unordered, non-signaling) */
#define _CMP_EQ_OS 0x10 /* Equal (ordered, signaling) */
#define _CMP_LT_OQ 0x11 /* Less-than (ordered, non-signaling) */
#define _CMP_LE_OQ 0x12 /* Less-than-or-equal (ordered, non-signaling) */
#define _CMP_UNORD_S 0x13 /* Unordered (signaling) */
#define _CMP_NEQ_US 0x14 /* Not-equal (unordered, signaling) */
#define _CMP_NLT_UQ 0x15 /* Not-less-than (unordered, non-signaling) */
#define _CMP_NLE_UQ 0x16 /* Not-less-than-or-equal (unordered, non-signaling) */
#define _CMP_ORD_S 0x17 /* Ordered (signaling) */
#define _CMP_EQ_US 0x18 /* Equal (unordered, signaling) */
#define _CMP_NGE_UQ 0x19 /* Not-greater-than-or-equal (unordered, non-signaling) */
#define _CMP_NGT_UQ 0x1a /* Not-greater-than (unordered, non-signaling) */
#define _CMP_FALSE_OS 0x1b /* False (ordered, signaling) */
#define _CMP_NEQ_OS 0x1c /* Not-equal (ordered, signaling) */
#define _CMP_GE_OQ 0x1d /* Greater-than-or-equal (ordered, non-signaling) */
#define _CMP_GT_OQ 0x1e /* Greater-than (ordered, non-signaling) */
#define _CMP_TRUE_US 0x1f /* True (unordered, signaling) */
/// Compares each of the corresponding double-precision values of two
/// 128-bit vectors of [2 x double], using the operation specified by the
/// immediate integer operand.
///
/// Returns a [2 x double] vector consisting of two doubles corresponding to
/// the two comparison results: zero if the comparison is false, and all 1's
/// if the comparison is true.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128d _mm_cmp_pd(__m128d a, __m128d b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPPD </c> instruction.
///
/// \param a
/// A 128-bit vector of [2 x double].
/// \param b
/// A 128-bit vector of [2 x double].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 128-bit vector of [2 x double] containing the comparison results.
#define _mm_cmp_pd(a, b, c) \
(__m128d)__builtin_ia32_cmppd((__v2df)(__m128d)(a), \
(__v2df)(__m128d)(b), (c))
/// Compares each of the corresponding values of two 128-bit vectors of
/// [4 x float], using the operation specified by the immediate integer
/// operand.
///
/// Returns a [4 x float] vector consisting of four floats corresponding to
/// the four comparison results: zero if the comparison is false, and all 1's
/// if the comparison is true.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128 _mm_cmp_ps(__m128 a, __m128 b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPPS </c> instruction.
///
/// \param a
/// A 128-bit vector of [4 x float].
/// \param b
/// A 128-bit vector of [4 x float].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 128-bit vector of [4 x float] containing the comparison results.
#define _mm_cmp_ps(a, b, c) \
(__m128)__builtin_ia32_cmpps((__v4sf)(__m128)(a), \
(__v4sf)(__m128)(b), (c))
/// Compares each of the corresponding double-precision values of two
/// 256-bit vectors of [4 x double], using the operation specified by the
/// immediate integer operand.
///
/// Returns a [4 x double] vector consisting of four doubles corresponding to
/// the four comparison results: zero if the comparison is false, and all 1's
/// if the comparison is true.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_cmp_pd(__m256d a, __m256d b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPPD </c> instruction.
///
/// \param a
/// A 256-bit vector of [4 x double].
/// \param b
/// A 256-bit vector of [4 x double].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 256-bit vector of [4 x double] containing the comparison results.
#define _mm256_cmp_pd(a, b, c) \
(__m256d)__builtin_ia32_cmppd256((__v4df)(__m256d)(a), \
(__v4df)(__m256d)(b), (c))
/// Compares each of the corresponding values of two 256-bit vectors of
/// [8 x float], using the operation specified by the immediate integer
/// operand.
///
/// Returns a [8 x float] vector consisting of eight floats corresponding to
/// the eight comparison results: zero if the comparison is false, and all
/// 1's if the comparison is true.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_cmp_ps(__m256 a, __m256 b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPPS </c> instruction.
///
/// \param a
/// A 256-bit vector of [8 x float].
/// \param b
/// A 256-bit vector of [8 x float].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 256-bit vector of [8 x float] containing the comparison results.
#define _mm256_cmp_ps(a, b, c) \
(__m256)__builtin_ia32_cmpps256((__v8sf)(__m256)(a), \
(__v8sf)(__m256)(b), (c))
/// Compares each of the corresponding scalar double-precision values of
/// two 128-bit vectors of [2 x double], using the operation specified by the
/// immediate integer operand.
///
/// If the result is true, all 64 bits of the destination vector are set;
/// otherwise they are cleared.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128d _mm_cmp_sd(__m128d a, __m128d b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPSD </c> instruction.
///
/// \param a
/// A 128-bit vector of [2 x double].
/// \param b
/// A 128-bit vector of [2 x double].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 128-bit vector of [2 x double] containing the comparison results.
#define _mm_cmp_sd(a, b, c) \
(__m128d)__builtin_ia32_cmpsd((__v2df)(__m128d)(a), \
(__v2df)(__m128d)(b), (c))
/// Compares each of the corresponding scalar values of two 128-bit
/// vectors of [4 x float], using the operation specified by the immediate
/// integer operand.
///
/// If the result is true, all 32 bits of the destination vector are set;
/// otherwise they are cleared.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128 _mm_cmp_ss(__m128 a, __m128 b, const int c);
/// \endcode
///
/// This intrinsic corresponds to the <c> VCMPSS </c> instruction.
///
/// \param a
/// A 128-bit vector of [4 x float].
/// \param b
/// A 128-bit vector of [4 x float].
/// \param c
/// An immediate integer operand, with bits [4:0] specifying which comparison
/// operation to use: \n
/// 0x00: Equal (ordered, non-signaling) \n
/// 0x01: Less-than (ordered, signaling) \n
/// 0x02: Less-than-or-equal (ordered, signaling) \n
/// 0x03: Unordered (non-signaling) \n
/// 0x04: Not-equal (unordered, non-signaling) \n
/// 0x05: Not-less-than (unordered, signaling) \n
/// 0x06: Not-less-than-or-equal (unordered, signaling) \n
/// 0x07: Ordered (non-signaling) \n
/// 0x08: Equal (unordered, non-signaling) \n
/// 0x09: Not-greater-than-or-equal (unordered, signaling) \n
/// 0x0A: Not-greater-than (unordered, signaling) \n
/// 0x0B: False (ordered, non-signaling) \n
/// 0x0C: Not-equal (ordered, non-signaling) \n
/// 0x0D: Greater-than-or-equal (ordered, signaling) \n
/// 0x0E: Greater-than (ordered, signaling) \n
/// 0x0F: True (unordered, non-signaling) \n
/// 0x10: Equal (ordered, signaling) \n
/// 0x11: Less-than (ordered, non-signaling) \n
/// 0x12: Less-than-or-equal (ordered, non-signaling) \n
/// 0x13: Unordered (signaling) \n
/// 0x14: Not-equal (unordered, signaling) \n
/// 0x15: Not-less-than (unordered, non-signaling) \n
/// 0x16: Not-less-than-or-equal (unordered, non-signaling) \n
/// 0x17: Ordered (signaling) \n
/// 0x18: Equal (unordered, signaling) \n
/// 0x19: Not-greater-than-or-equal (unordered, non-signaling) \n
/// 0x1A: Not-greater-than (unordered, non-signaling) \n
/// 0x1B: False (ordered, signaling) \n
/// 0x1C: Not-equal (ordered, signaling) \n
/// 0x1D: Greater-than-or-equal (ordered, non-signaling) \n
/// 0x1E: Greater-than (ordered, non-signaling) \n
/// 0x1F: True (unordered, signaling)
/// \returns A 128-bit vector of [4 x float] containing the comparison results.
#define _mm_cmp_ss(a, b, c) \
(__m128)__builtin_ia32_cmpss((__v4sf)(__m128)(a), \
(__v4sf)(__m128)(b), (c))
/// Takes a [8 x i32] vector and returns the vector element value
/// indexed by the immediate constant operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A 256-bit vector of [8 x i32].
/// \param __imm
/// An immediate integer operand with bits [2:0] determining which vector
/// element is extracted and returned.
/// \returns A 32-bit integer containing the extracted 32 bits of extended
/// packed data.
#define _mm256_extract_epi32(X, N) \
(int)__builtin_ia32_vec_ext_v8si((__v8si)(__m256i)(X), (int)(N))
/// Takes a [16 x i16] vector and returns the vector element value
/// indexed by the immediate constant operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A 256-bit integer vector of [16 x i16].
/// \param __imm
/// An immediate integer operand with bits [3:0] determining which vector
/// element is extracted and returned.
/// \returns A 32-bit integer containing the extracted 16 bits of zero extended
/// packed data.
#define _mm256_extract_epi16(X, N) \
(int)(unsigned short)__builtin_ia32_vec_ext_v16hi((__v16hi)(__m256i)(X), \
(int)(N))
/// Takes a [32 x i8] vector and returns the vector element value
/// indexed by the immediate constant operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A 256-bit integer vector of [32 x i8].
/// \param __imm
/// An immediate integer operand with bits [4:0] determining which vector
/// element is extracted and returned.
/// \returns A 32-bit integer containing the extracted 8 bits of zero extended
/// packed data.
#define _mm256_extract_epi8(X, N) \
(int)(unsigned char)__builtin_ia32_vec_ext_v32qi((__v32qi)(__m256i)(X), \
(int)(N))
#ifdef __x86_64__
/// Takes a [4 x i64] vector and returns the vector element value
/// indexed by the immediate constant operand.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A 256-bit integer vector of [4 x i64].
/// \param __imm
/// An immediate integer operand with bits [1:0] determining which vector
/// element is extracted and returned.
/// \returns A 64-bit integer containing the extracted 64 bits of extended
/// packed data.
#define _mm256_extract_epi64(X, N) \
(long long)__builtin_ia32_vec_ext_v4di((__v4di)(__m256i)(X), (int)(N))
#endif
/// Takes a [8 x i32] vector and replaces the vector element value
/// indexed by the immediate constant operand by a new value. Returns the
/// modified vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A vector of [8 x i32] to be used by the insert operation.
/// \param __b
/// An integer value. The replacement value for the insert operation.
/// \param __imm
/// An immediate integer specifying the index of the vector element to be
/// replaced.
/// \returns A copy of vector \a __a, after replacing its element indexed by
/// \a __imm with \a __b.
#define _mm256_insert_epi32(X, I, N) \
(__m256i)__builtin_ia32_vec_set_v8si((__v8si)(__m256i)(X), \
(int)(I), (int)(N))
/// Takes a [16 x i16] vector and replaces the vector element value
/// indexed by the immediate constant operand with a new value. Returns the
/// modified vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A vector of [16 x i16] to be used by the insert operation.
/// \param __b
/// An i16 integer value. The replacement value for the insert operation.
/// \param __imm
/// An immediate integer specifying the index of the vector element to be
/// replaced.
/// \returns A copy of vector \a __a, after replacing its element indexed by
/// \a __imm with \a __b.
#define _mm256_insert_epi16(X, I, N) \
(__m256i)__builtin_ia32_vec_set_v16hi((__v16hi)(__m256i)(X), \
(int)(I), (int)(N))
/// Takes a [32 x i8] vector and replaces the vector element value
/// indexed by the immediate constant operand with a new value. Returns the
/// modified vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A vector of [32 x i8] to be used by the insert operation.
/// \param __b
/// An i8 integer value. The replacement value for the insert operation.
/// \param __imm
/// An immediate integer specifying the index of the vector element to be
/// replaced.
/// \returns A copy of vector \a __a, after replacing its element indexed by
/// \a __imm with \a __b.
#define _mm256_insert_epi8(X, I, N) \
(__m256i)__builtin_ia32_vec_set_v32qi((__v32qi)(__m256i)(X), \
(int)(I), (int)(N))
#ifdef __x86_64__
/// Takes a [4 x i64] vector and replaces the vector element value
/// indexed by the immediate constant operand with a new value. Returns the
/// modified vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128+COMPOSITE </c>
/// instruction.
///
/// \param __a
/// A vector of [4 x i64] to be used by the insert operation.
/// \param __b
/// A 64-bit integer value. The replacement value for the insert operation.
/// \param __imm
/// An immediate integer specifying the index of the vector element to be
/// replaced.
/// \returns A copy of vector \a __a, after replacing its element indexed by
/// \a __imm with \a __b.
#define _mm256_insert_epi64(X, I, N) \
(__m256i)__builtin_ia32_vec_set_v4di((__v4di)(__m256i)(X), \
(long long)(I), (int)(N))
#endif
/* Conversion */
/// Converts a vector of [4 x i32] into a vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTDQ2PD </c> instruction.
///
/// \param __a
/// A 128-bit integer vector of [4 x i32].
/// \returns A 256-bit vector of [4 x double] containing the converted values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_cvtepi32_pd(__m128i __a)
{
return (__m256d)__builtin_convertvector((__v4si)__a, __v4df);
}
/// Converts a vector of [8 x i32] into a vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTDQ2PS </c> instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \returns A 256-bit vector of [8 x float] containing the converted values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_cvtepi32_ps(__m256i __a)
{
return (__m256)__builtin_convertvector((__v8si)__a, __v8sf);
}
/// Converts a 256-bit vector of [4 x double] into a 128-bit vector of
/// [4 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTPD2PS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \returns A 128-bit vector of [4 x float] containing the converted values.
static __inline __m128 __DEFAULT_FN_ATTRS
_mm256_cvtpd_ps(__m256d __a)
{
return (__m128)__builtin_ia32_cvtpd2ps256((__v4df) __a);
}
/// Converts a vector of [8 x float] into a vector of [8 x i32].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTPS2DQ </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit integer vector containing the converted values.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_cvtps_epi32(__m256 __a)
{
return (__m256i)__builtin_ia32_cvtps2dq256((__v8sf) __a);
}
/// Converts a 128-bit vector of [4 x float] into a 256-bit vector of [4
/// x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTPS2PD </c> instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \returns A 256-bit vector of [4 x double] containing the converted values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_cvtps_pd(__m128 __a)
{
return (__m256d)__builtin_convertvector((__v4sf)__a, __v4df);
}
/// Converts a 256-bit vector of [4 x double] into a 128-bit vector of [4
/// x i32], truncating the result by rounding towards zero when it is
/// inexact.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTTPD2DQ </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \returns A 128-bit integer vector containing the converted values.
static __inline __m128i __DEFAULT_FN_ATTRS
_mm256_cvttpd_epi32(__m256d __a)
{
return (__m128i)__builtin_ia32_cvttpd2dq256((__v4df) __a);
}
/// Converts a 256-bit vector of [4 x double] into a 128-bit vector of [4
/// x i32]. When a conversion is inexact, the value returned is rounded
/// according to the rounding control bits in the MXCSR register.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTPD2DQ </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \returns A 128-bit integer vector containing the converted values.
static __inline __m128i __DEFAULT_FN_ATTRS
_mm256_cvtpd_epi32(__m256d __a)
{
return (__m128i)__builtin_ia32_cvtpd2dq256((__v4df) __a);
}
/// Converts a vector of [8 x float] into a vector of [8 x i32],
/// truncating the result by rounding towards zero when it is inexact.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VCVTTPS2DQ </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 256-bit integer vector containing the converted values.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_cvttps_epi32(__m256 __a)
{
return (__m256i)__builtin_ia32_cvttps2dq256((__v8sf) __a);
}
/// Returns the first element of the input vector of [4 x double].
///
/// \headerfile <avxintrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \returns A 64 bit double containing the first element of the input vector.
static __inline double __DEFAULT_FN_ATTRS
_mm256_cvtsd_f64(__m256d __a)
{
return __a[0];
}
/// Returns the first element of the input vector of [8 x i32].
///
/// \headerfile <avxintrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __a
/// A 256-bit vector of [8 x i32].
/// \returns A 32 bit integer containing the first element of the input vector.
static __inline int __DEFAULT_FN_ATTRS
_mm256_cvtsi256_si32(__m256i __a)
{
__v8si __b = (__v8si)__a;
return __b[0];
}
/// Returns the first element of the input vector of [8 x float].
///
/// \headerfile <avxintrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \returns A 32 bit float containing the first element of the input vector.
static __inline float __DEFAULT_FN_ATTRS
_mm256_cvtss_f32(__m256 __a)
{
return __a[0];
}
/* Vector replicate */
/// Moves and duplicates odd-indexed values from a 256-bit vector of
/// [8 x float] to float values in a 256-bit vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVSHDUP </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float]. \n
/// Bits [255:224] of \a __a are written to bits [255:224] and [223:192] of
/// the return value. \n
/// Bits [191:160] of \a __a are written to bits [191:160] and [159:128] of
/// the return value. \n
/// Bits [127:96] of \a __a are written to bits [127:96] and [95:64] of the
/// return value. \n
/// Bits [63:32] of \a __a are written to bits [63:32] and [31:0] of the
/// return value.
/// \returns A 256-bit vector of [8 x float] containing the moved and duplicated
/// values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_movehdup_ps(__m256 __a)
{
return __builtin_shufflevector((__v8sf)__a, (__v8sf)__a, 1, 1, 3, 3, 5, 5, 7, 7);
}
/// Moves and duplicates even-indexed values from a 256-bit vector of
/// [8 x float] to float values in a 256-bit vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVSLDUP </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float]. \n
/// Bits [223:192] of \a __a are written to bits [255:224] and [223:192] of
/// the return value. \n
/// Bits [159:128] of \a __a are written to bits [191:160] and [159:128] of
/// the return value. \n
/// Bits [95:64] of \a __a are written to bits [127:96] and [95:64] of the
/// return value. \n
/// Bits [31:0] of \a __a are written to bits [63:32] and [31:0] of the
/// return value.
/// \returns A 256-bit vector of [8 x float] containing the moved and duplicated
/// values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_moveldup_ps(__m256 __a)
{
return __builtin_shufflevector((__v8sf)__a, (__v8sf)__a, 0, 0, 2, 2, 4, 4, 6, 6);
}
/// Moves and duplicates double-precision floating point values from a
/// 256-bit vector of [4 x double] to double-precision values in a 256-bit
/// vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDDUP </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double]. \n
/// Bits [63:0] of \a __a are written to bits [127:64] and [63:0] of the
/// return value. \n
/// Bits [191:128] of \a __a are written to bits [255:192] and [191:128] of
/// the return value.
/// \returns A 256-bit vector of [4 x double] containing the moved and
/// duplicated values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_movedup_pd(__m256d __a)
{
return __builtin_shufflevector((__v4df)__a, (__v4df)__a, 0, 0, 2, 2);
}
/* Unpack and Interleave */
/// Unpacks the odd-indexed vector elements from two 256-bit vectors of
/// [4 x double] and interleaves them into a 256-bit vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKHPD </c> instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [4 x double]. \n
/// Bits [127:64] are written to bits [63:0] of the return value. \n
/// Bits [255:192] are written to bits [191:128] of the return value. \n
/// \param __b
/// A 256-bit floating-point vector of [4 x double]. \n
/// Bits [127:64] are written to bits [127:64] of the return value. \n
/// Bits [255:192] are written to bits [255:192] of the return value. \n
/// \returns A 256-bit vector of [4 x double] containing the interleaved values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_unpackhi_pd(__m256d __a, __m256d __b)
{
return __builtin_shufflevector((__v4df)__a, (__v4df)__b, 1, 5, 1+2, 5+2);
}
/// Unpacks the even-indexed vector elements from two 256-bit vectors of
/// [4 x double] and interleaves them into a 256-bit vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKLPD </c> instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [4 x double]. \n
/// Bits [63:0] are written to bits [63:0] of the return value. \n
/// Bits [191:128] are written to bits [191:128] of the return value.
/// \param __b
/// A 256-bit floating-point vector of [4 x double]. \n
/// Bits [63:0] are written to bits [127:64] of the return value. \n
/// Bits [191:128] are written to bits [255:192] of the return value. \n
/// \returns A 256-bit vector of [4 x double] containing the interleaved values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_unpacklo_pd(__m256d __a, __m256d __b)
{
return __builtin_shufflevector((__v4df)__a, (__v4df)__b, 0, 4, 0+2, 4+2);
}
/// Unpacks the 32-bit vector elements 2, 3, 6 and 7 from each of the
/// two 256-bit vectors of [8 x float] and interleaves them into a 256-bit
/// vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKHPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float]. \n
/// Bits [95:64] are written to bits [31:0] of the return value. \n
/// Bits [127:96] are written to bits [95:64] of the return value. \n
/// Bits [223:192] are written to bits [159:128] of the return value. \n
/// Bits [255:224] are written to bits [223:192] of the return value.
/// \param __b
/// A 256-bit vector of [8 x float]. \n
/// Bits [95:64] are written to bits [63:32] of the return value. \n
/// Bits [127:96] are written to bits [127:96] of the return value. \n
/// Bits [223:192] are written to bits [191:160] of the return value. \n
/// Bits [255:224] are written to bits [255:224] of the return value.
/// \returns A 256-bit vector of [8 x float] containing the interleaved values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_unpackhi_ps(__m256 __a, __m256 __b)
{
return __builtin_shufflevector((__v8sf)__a, (__v8sf)__b, 2, 10, 2+1, 10+1, 6, 14, 6+1, 14+1);
}
/// Unpacks the 32-bit vector elements 0, 1, 4 and 5 from each of the
/// two 256-bit vectors of [8 x float] and interleaves them into a 256-bit
/// vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKLPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float]. \n
/// Bits [31:0] are written to bits [31:0] of the return value. \n
/// Bits [63:32] are written to bits [95:64] of the return value. \n
/// Bits [159:128] are written to bits [159:128] of the return value. \n
/// Bits [191:160] are written to bits [223:192] of the return value.
/// \param __b
/// A 256-bit vector of [8 x float]. \n
/// Bits [31:0] are written to bits [63:32] of the return value. \n
/// Bits [63:32] are written to bits [127:96] of the return value. \n
/// Bits [159:128] are written to bits [191:160] of the return value. \n
/// Bits [191:160] are written to bits [255:224] of the return value.
/// \returns A 256-bit vector of [8 x float] containing the interleaved values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_unpacklo_ps(__m256 __a, __m256 __b)
{
return __builtin_shufflevector((__v8sf)__a, (__v8sf)__b, 0, 8, 0+1, 8+1, 4, 12, 4+1, 12+1);
}
/* Bit Test */
/// Given two 128-bit floating-point vectors of [2 x double], perform an
/// element-by-element comparison of the double-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the ZF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \param __b
/// A 128-bit vector of [2 x double].
/// \returns the ZF flag in the EFLAGS register.
static __inline int __DEFAULT_FN_ATTRS
_mm_testz_pd(__m128d __a, __m128d __b)
{
return __builtin_ia32_vtestzpd((__v2df)__a, (__v2df)__b);
}
/// Given two 128-bit floating-point vectors of [2 x double], perform an
/// element-by-element comparison of the double-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the CF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \param __b
/// A 128-bit vector of [2 x double].
/// \returns the CF flag in the EFLAGS register.
static __inline int __DEFAULT_FN_ATTRS
_mm_testc_pd(__m128d __a, __m128d __b)
{
return __builtin_ia32_vtestcpd((__v2df)__a, (__v2df)__b);
}
/// Given two 128-bit floating-point vectors of [2 x double], perform an
/// element-by-element comparison of the double-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns 1 if both the ZF and CF flags are set to 0,
/// otherwise it returns 0.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \param __b
/// A 128-bit vector of [2 x double].
/// \returns 1 if both the ZF and CF flags are set to 0, otherwise returns 0.
static __inline int __DEFAULT_FN_ATTRS
_mm_testnzc_pd(__m128d __a, __m128d __b)
{
return __builtin_ia32_vtestnzcpd((__v2df)__a, (__v2df)__b);
}
/// Given two 128-bit floating-point vectors of [4 x float], perform an
/// element-by-element comparison of the single-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the ZF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \param __b
/// A 128-bit vector of [4 x float].
/// \returns the ZF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm_testz_ps(__m128 __a, __m128 __b)
{
return __builtin_ia32_vtestzps((__v4sf)__a, (__v4sf)__b);
}
/// Given two 128-bit floating-point vectors of [4 x float], perform an
/// element-by-element comparison of the single-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the CF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \param __b
/// A 128-bit vector of [4 x float].
/// \returns the CF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm_testc_ps(__m128 __a, __m128 __b)
{
return __builtin_ia32_vtestcps((__v4sf)__a, (__v4sf)__b);
}
/// Given two 128-bit floating-point vectors of [4 x float], perform an
/// element-by-element comparison of the single-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns 1 if both the ZF and CF flags are set to 0,
/// otherwise it returns 0.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \param __b
/// A 128-bit vector of [4 x float].
/// \returns 1 if both the ZF and CF flags are set to 0, otherwise returns 0.
static __inline int __DEFAULT_FN_ATTRS
_mm_testnzc_ps(__m128 __a, __m128 __b)
{
return __builtin_ia32_vtestnzcps((__v4sf)__a, (__v4sf)__b);
}
/// Given two 256-bit floating-point vectors of [4 x double], perform an
/// element-by-element comparison of the double-precision elements in the
/// first source vector and the corresponding elements in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the ZF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double].
/// \returns the ZF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testz_pd(__m256d __a, __m256d __b)
{
return __builtin_ia32_vtestzpd256((__v4df)__a, (__v4df)__b);
}
/// Given two 256-bit floating-point vectors of [4 x double], perform an
/// element-by-element comparison of the double-precision elements in the
/// first source vector and the corresponding elements in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the CF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double].
/// \returns the CF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testc_pd(__m256d __a, __m256d __b)
{
return __builtin_ia32_vtestcpd256((__v4df)__a, (__v4df)__b);
}
/// Given two 256-bit floating-point vectors of [4 x double], perform an
/// element-by-element comparison of the double-precision elements in the
/// first source vector and the corresponding elements in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of double-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of double-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns 1 if both the ZF and CF flags are set to 0,
/// otherwise it returns 0.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double].
/// \param __b
/// A 256-bit vector of [4 x double].
/// \returns 1 if both the ZF and CF flags are set to 0, otherwise returns 0.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testnzc_pd(__m256d __a, __m256d __b)
{
return __builtin_ia32_vtestnzcpd256((__v4df)__a, (__v4df)__b);
}
/// Given two 256-bit floating-point vectors of [8 x float], perform an
/// element-by-element comparison of the single-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the ZF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float].
/// \returns the ZF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testz_ps(__m256 __a, __m256 __b)
{
return __builtin_ia32_vtestzps256((__v8sf)__a, (__v8sf)__b);
}
/// Given two 256-bit floating-point vectors of [8 x float], perform an
/// element-by-element comparison of the single-precision element in the
/// first source vector and the corresponding element in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the CF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float].
/// \returns the CF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testc_ps(__m256 __a, __m256 __b)
{
return __builtin_ia32_vtestcps256((__v8sf)__a, (__v8sf)__b);
}
/// Given two 256-bit floating-point vectors of [8 x float], perform an
/// element-by-element comparison of the single-precision elements in the
/// first source vector and the corresponding elements in the second source
/// vector.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of single-precision elements where the
/// sign-bits of both elements are 1, the ZF flag is set to 0. Otherwise the
/// ZF flag is set to 1. \n
/// If there is at least one pair of single-precision elements where the
/// sign-bit of the first element is 0 and the sign-bit of the second element
/// is 1, the CF flag is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns 1 if both the ZF and CF flags are set to 0,
/// otherwise it returns 0.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VTESTPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float].
/// \param __b
/// A 256-bit vector of [8 x float].
/// \returns 1 if both the ZF and CF flags are set to 0, otherwise returns 0.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testnzc_ps(__m256 __a, __m256 __b)
{
return __builtin_ia32_vtestnzcps256((__v8sf)__a, (__v8sf)__b);
}
/// Given two 256-bit integer vectors, perform a bit-by-bit comparison
/// of the two source vectors.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of bits where both bits are 1, the ZF flag
/// is set to 0. Otherwise the ZF flag is set to 1. \n
/// If there is at least one pair of bits where the bit from the first source
/// vector is 0 and the bit from the second source vector is 1, the CF flag
/// is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the ZF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPTEST </c> instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \param __b
/// A 256-bit integer vector.
/// \returns the ZF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testz_si256(__m256i __a, __m256i __b)
{
return __builtin_ia32_ptestz256((__v4di)__a, (__v4di)__b);
}
/// Given two 256-bit integer vectors, perform a bit-by-bit comparison
/// of the two source vectors.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of bits where both bits are 1, the ZF flag
/// is set to 0. Otherwise the ZF flag is set to 1. \n
/// If there is at least one pair of bits where the bit from the first source
/// vector is 0 and the bit from the second source vector is 1, the CF flag
/// is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns the value of the CF flag.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPTEST </c> instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \param __b
/// A 256-bit integer vector.
/// \returns the CF flag.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testc_si256(__m256i __a, __m256i __b)
{
return __builtin_ia32_ptestc256((__v4di)__a, (__v4di)__b);
}
/// Given two 256-bit integer vectors, perform a bit-by-bit comparison
/// of the two source vectors.
///
/// The EFLAGS register is updated as follows: \n
/// If there is at least one pair of bits where both bits are 1, the ZF flag
/// is set to 0. Otherwise the ZF flag is set to 1. \n
/// If there is at least one pair of bits where the bit from the first source
/// vector is 0 and the bit from the second source vector is 1, the CF flag
/// is set to 0. Otherwise the CF flag is set to 1. \n
/// This intrinsic returns 1 if both the ZF and CF flags are set to 0,
/// otherwise it returns 0.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPTEST </c> instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \param __b
/// A 256-bit integer vector.
/// \returns 1 if both the ZF and CF flags are set to 0, otherwise returns 0.
static __inline int __DEFAULT_FN_ATTRS
_mm256_testnzc_si256(__m256i __a, __m256i __b)
{
return __builtin_ia32_ptestnzc256((__v4di)__a, (__v4di)__b);
}
/* Vector extract sign mask */
/// Extracts the sign bits of double-precision floating point elements
/// in a 256-bit vector of [4 x double] and writes them to the lower order
/// bits of the return value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVMSKPD </c> instruction.
///
/// \param __a
/// A 256-bit vector of [4 x double] containing the double-precision
/// floating point values with sign bits to be extracted.
/// \returns The sign bits from the operand, written to bits [3:0].
static __inline int __DEFAULT_FN_ATTRS
_mm256_movemask_pd(__m256d __a)
{
return __builtin_ia32_movmskpd256((__v4df)__a);
}
/// Extracts the sign bits of single-precision floating point elements
/// in a 256-bit vector of [8 x float] and writes them to the lower order
/// bits of the return value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVMSKPS </c> instruction.
///
/// \param __a
/// A 256-bit vector of [8 x float] containing the single-precision floating
/// point values with sign bits to be extracted.
/// \returns The sign bits from the operand, written to bits [7:0].
static __inline int __DEFAULT_FN_ATTRS
_mm256_movemask_ps(__m256 __a)
{
return __builtin_ia32_movmskps256((__v8sf)__a);
}
/* Vector __zero */
/// Zeroes the contents of all XMM or YMM registers.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VZEROALL </c> instruction.
static __inline void __DEFAULT_FN_ATTRS
_mm256_zeroall(void)
{
__builtin_ia32_vzeroall();
}
/// Zeroes the upper 128 bits (bits 255:128) of all YMM registers.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VZEROUPPER </c> instruction.
static __inline void __DEFAULT_FN_ATTRS
_mm256_zeroupper(void)
{
__builtin_ia32_vzeroupper();
}
/* Vector load with broadcast */
/// Loads a scalar single-precision floating point value from the
/// specified address pointed to by \a __a and broadcasts it to the elements
/// of a [4 x float] vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBROADCASTSS </c> instruction.
///
/// \param __a
/// The single-precision floating point value to be broadcast.
/// \returns A 128-bit vector of [4 x float] whose 32-bit elements are set
/// equal to the broadcast value.
static __inline __m128 __DEFAULT_FN_ATTRS
_mm_broadcast_ss(float const *__a)
{
float __f = *__a;
return __extension__ (__m128)(__v4sf){ __f, __f, __f, __f };
}
/// Loads a scalar double-precision floating point value from the
/// specified address pointed to by \a __a and broadcasts it to the elements
/// of a [4 x double] vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBROADCASTSD </c> instruction.
///
/// \param __a
/// The double-precision floating point value to be broadcast.
/// \returns A 256-bit vector of [4 x double] whose 64-bit elements are set
/// equal to the broadcast value.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_broadcast_sd(double const *__a)
{
double __d = *__a;
return __extension__ (__m256d)(__v4df){ __d, __d, __d, __d };
}
/// Loads a scalar single-precision floating point value from the
/// specified address pointed to by \a __a and broadcasts it to the elements
/// of a [8 x float] vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBROADCASTSS </c> instruction.
///
/// \param __a
/// The single-precision floating point value to be broadcast.
/// \returns A 256-bit vector of [8 x float] whose 32-bit elements are set
/// equal to the broadcast value.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_broadcast_ss(float const *__a)
{
float __f = *__a;
return __extension__ (__m256)(__v8sf){ __f, __f, __f, __f, __f, __f, __f, __f };
}
/// Loads the data from a 128-bit vector of [2 x double] from the
/// specified address pointed to by \a __a and broadcasts it to 128-bit
/// elements in a 256-bit vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBROADCASTF128 </c> instruction.
///
/// \param __a
/// The 128-bit vector of [2 x double] to be broadcast.
/// \returns A 256-bit vector of [4 x double] whose 128-bit elements are set
/// equal to the broadcast value.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_broadcast_pd(__m128d const *__a)
{
__m128d __b = _mm_loadu_pd((const double *)__a);
return (__m256d)__builtin_shufflevector((__v2df)__b, (__v2df)__b,
0, 1, 0, 1);
}
/// Loads the data from a 128-bit vector of [4 x float] from the
/// specified address pointed to by \a __a and broadcasts it to 128-bit
/// elements in a 256-bit vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VBROADCASTF128 </c> instruction.
///
/// \param __a
/// The 128-bit vector of [4 x float] to be broadcast.
/// \returns A 256-bit vector of [8 x float] whose 128-bit elements are set
/// equal to the broadcast value.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_broadcast_ps(__m128 const *__a)
{
__m128 __b = _mm_loadu_ps((const float *)__a);
return (__m256)__builtin_shufflevector((__v4sf)__b, (__v4sf)__b,
0, 1, 2, 3, 0, 1, 2, 3);
}
/* SIMD load ops */
/// Loads 4 double-precision floating point values from a 32-byte aligned
/// memory location pointed to by \a __p into a vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVAPD </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a memory location containing
/// double-precision floating point values.
/// \returns A 256-bit vector of [4 x double] containing the moved values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_load_pd(double const *__p)
{
return *(__m256d *)__p;
}
/// Loads 8 single-precision floating point values from a 32-byte aligned
/// memory location pointed to by \a __p into a vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVAPS </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a memory location containing float values.
/// \returns A 256-bit vector of [8 x float] containing the moved values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_load_ps(float const *__p)
{
return *(__m256 *)__p;
}
/// Loads 4 double-precision floating point values from an unaligned
/// memory location pointed to by \a __p into a vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVUPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location containing double-precision floating
/// point values.
/// \returns A 256-bit vector of [4 x double] containing the moved values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_loadu_pd(double const *__p)
{
struct __loadu_pd {
__m256d __v;
} __attribute__((__packed__, __may_alias__));
return ((struct __loadu_pd*)__p)->__v;
}
/// Loads 8 single-precision floating point values from an unaligned
/// memory location pointed to by \a __p into a vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVUPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location containing single-precision floating
/// point values.
/// \returns A 256-bit vector of [8 x float] containing the moved values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_loadu_ps(float const *__p)
{
struct __loadu_ps {
__m256 __v;
} __attribute__((__packed__, __may_alias__));
return ((struct __loadu_ps*)__p)->__v;
}
/// Loads 256 bits of integer data from a 32-byte aligned memory
/// location pointed to by \a __p into elements of a 256-bit integer vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDQA </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a 256-bit integer vector containing integer
/// values.
/// \returns A 256-bit integer vector containing the moved values.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_load_si256(__m256i const *__p)
{
return *__p;
}
/// Loads 256 bits of integer data from an unaligned memory location
/// pointed to by \a __p into a 256-bit integer vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDQU </c> instruction.
///
/// \param __p
/// A pointer to a 256-bit integer vector containing integer values.
/// \returns A 256-bit integer vector containing the moved values.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_loadu_si256(__m256i const *__p)
{
struct __loadu_si256 {
__m256i __v;
} __attribute__((__packed__, __may_alias__));
return ((struct __loadu_si256*)__p)->__v;
}
/// Loads 256 bits of integer data from an unaligned memory location
/// pointed to by \a __p into a 256-bit integer vector. This intrinsic may
/// perform better than \c _mm256_loadu_si256 when the data crosses a cache
/// line boundary.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VLDDQU </c> instruction.
///
/// \param __p
/// A pointer to a 256-bit integer vector containing integer values.
/// \returns A 256-bit integer vector containing the moved values.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_lddqu_si256(__m256i const *__p)
{
return (__m256i)__builtin_ia32_lddqu256((char const *)__p);
}
/* SIMD store ops */
/// Stores double-precision floating point values from a 256-bit vector
/// of [4 x double] to a 32-byte aligned memory location pointed to by
/// \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVAPD </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a memory location that will receive the
/// double-precision floaing point values.
/// \param __a
/// A 256-bit vector of [4 x double] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_store_pd(double *__p, __m256d __a)
{
*(__m256d *)__p = __a;
}
/// Stores single-precision floating point values from a 256-bit vector
/// of [8 x float] to a 32-byte aligned memory location pointed to by \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVAPS </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a memory location that will receive the
/// float values.
/// \param __a
/// A 256-bit vector of [8 x float] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_store_ps(float *__p, __m256 __a)
{
*(__m256 *)__p = __a;
}
/// Stores double-precision floating point values from a 256-bit vector
/// of [4 x double] to an unaligned memory location pointed to by \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVUPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the double-precision
/// floating point values.
/// \param __a
/// A 256-bit vector of [4 x double] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu_pd(double *__p, __m256d __a)
{
struct __storeu_pd {
__m256d __v;
} __attribute__((__packed__, __may_alias__));
((struct __storeu_pd*)__p)->__v = __a;
}
/// Stores single-precision floating point values from a 256-bit vector
/// of [8 x float] to an unaligned memory location pointed to by \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVUPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the float values.
/// \param __a
/// A 256-bit vector of [8 x float] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu_ps(float *__p, __m256 __a)
{
struct __storeu_ps {
__m256 __v;
} __attribute__((__packed__, __may_alias__));
((struct __storeu_ps*)__p)->__v = __a;
}
/// Stores integer values from a 256-bit integer vector to a 32-byte
/// aligned memory location pointed to by \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDQA </c> instruction.
///
/// \param __p
/// A 32-byte aligned pointer to a memory location that will receive the
/// integer values.
/// \param __a
/// A 256-bit integer vector containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_store_si256(__m256i *__p, __m256i __a)
{
*__p = __a;
}
/// Stores integer values from a 256-bit integer vector to an unaligned
/// memory location pointed to by \a __p.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDQU </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the integer values.
/// \param __a
/// A 256-bit integer vector containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu_si256(__m256i *__p, __m256i __a)
{
struct __storeu_si256 {
__m256i __v;
} __attribute__((__packed__, __may_alias__));
((struct __storeu_si256*)__p)->__v = __a;
}
/* Conditional load ops */
/// Conditionally loads double-precision floating point elements from a
/// memory location pointed to by \a __p into a 128-bit vector of
/// [2 x double], depending on the mask bits associated with each data
/// element.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location that contains the double-precision
/// floating point values.
/// \param __m
/// A 128-bit integer vector containing the mask. The most significant bit of
/// each data element represents the mask bits. If a mask bit is zero, the
/// corresponding value in the memory location is not loaded and the
/// corresponding field in the return value is set to zero.
/// \returns A 128-bit vector of [2 x double] containing the loaded values.
static __inline __m128d __DEFAULT_FN_ATTRS
_mm_maskload_pd(double const *__p, __m128i __m)
{
return (__m128d)__builtin_ia32_maskloadpd((const __v2df *)__p, (__v2di)__m);
}
/// Conditionally loads double-precision floating point elements from a
/// memory location pointed to by \a __p into a 256-bit vector of
/// [4 x double], depending on the mask bits associated with each data
/// element.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location that contains the double-precision
/// floating point values.
/// \param __m
/// A 256-bit integer vector of [4 x quadword] containing the mask. The most
/// significant bit of each quadword element represents the mask bits. If a
/// mask bit is zero, the corresponding value in the memory location is not
/// loaded and the corresponding field in the return value is set to zero.
/// \returns A 256-bit vector of [4 x double] containing the loaded values.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_maskload_pd(double const *__p, __m256i __m)
{
return (__m256d)__builtin_ia32_maskloadpd256((const __v4df *)__p,
(__v4di)__m);
}
/// Conditionally loads single-precision floating point elements from a
/// memory location pointed to by \a __p into a 128-bit vector of
/// [4 x float], depending on the mask bits associated with each data
/// element.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location that contains the single-precision
/// floating point values.
/// \param __m
/// A 128-bit integer vector containing the mask. The most significant bit of
/// each data element represents the mask bits. If a mask bit is zero, the
/// corresponding value in the memory location is not loaded and the
/// corresponding field in the return value is set to zero.
/// \returns A 128-bit vector of [4 x float] containing the loaded values.
static __inline __m128 __DEFAULT_FN_ATTRS
_mm_maskload_ps(float const *__p, __m128i __m)
{
return (__m128)__builtin_ia32_maskloadps((const __v4sf *)__p, (__v4si)__m);
}
/// Conditionally loads single-precision floating point elements from a
/// memory location pointed to by \a __p into a 256-bit vector of
/// [8 x float], depending on the mask bits associated with each data
/// element.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location that contains the single-precision
/// floating point values.
/// \param __m
/// A 256-bit integer vector of [8 x dword] containing the mask. The most
/// significant bit of each dword element represents the mask bits. If a mask
/// bit is zero, the corresponding value in the memory location is not loaded
/// and the corresponding field in the return value is set to zero.
/// \returns A 256-bit vector of [8 x float] containing the loaded values.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_maskload_ps(float const *__p, __m256i __m)
{
return (__m256)__builtin_ia32_maskloadps256((const __v8sf *)__p, (__v8si)__m);
}
/* Conditional store ops */
/// Moves single-precision floating point values from a 256-bit vector
/// of [8 x float] to a memory location pointed to by \a __p, according to
/// the specified mask.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the float values.
/// \param __m
/// A 256-bit integer vector of [8 x dword] containing the mask. The most
/// significant bit of each dword element in the mask vector represents the
/// mask bits. If a mask bit is zero, the corresponding value from vector
/// \a __a is not stored and the corresponding field in the memory location
/// pointed to by \a __p is not changed.
/// \param __a
/// A 256-bit vector of [8 x float] containing the values to be stored.
static __inline void __DEFAULT_FN_ATTRS
_mm256_maskstore_ps(float *__p, __m256i __m, __m256 __a)
{
__builtin_ia32_maskstoreps256((__v8sf *)__p, (__v8si)__m, (__v8sf)__a);
}
/// Moves double-precision values from a 128-bit vector of [2 x double]
/// to a memory location pointed to by \a __p, according to the specified
/// mask.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the float values.
/// \param __m
/// A 128-bit integer vector containing the mask. The most significant bit of
/// each field in the mask vector represents the mask bits. If a mask bit is
/// zero, the corresponding value from vector \a __a is not stored and the
/// corresponding field in the memory location pointed to by \a __p is not
/// changed.
/// \param __a
/// A 128-bit vector of [2 x double] containing the values to be stored.
static __inline void __DEFAULT_FN_ATTRS
_mm_maskstore_pd(double *__p, __m128i __m, __m128d __a)
{
__builtin_ia32_maskstorepd((__v2df *)__p, (__v2di)__m, (__v2df)__a);
}
/// Moves double-precision values from a 256-bit vector of [4 x double]
/// to a memory location pointed to by \a __p, according to the specified
/// mask.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPD </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the float values.
/// \param __m
/// A 256-bit integer vector of [4 x quadword] containing the mask. The most
/// significant bit of each quadword element in the mask vector represents
/// the mask bits. If a mask bit is zero, the corresponding value from vector
/// __a is not stored and the corresponding field in the memory location
/// pointed to by \a __p is not changed.
/// \param __a
/// A 256-bit vector of [4 x double] containing the values to be stored.
static __inline void __DEFAULT_FN_ATTRS
_mm256_maskstore_pd(double *__p, __m256i __m, __m256d __a)
{
__builtin_ia32_maskstorepd256((__v4df *)__p, (__v4di)__m, (__v4df)__a);
}
/// Moves single-precision floating point values from a 128-bit vector
/// of [4 x float] to a memory location pointed to by \a __p, according to
/// the specified mask.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMASKMOVPS </c> instruction.
///
/// \param __p
/// A pointer to a memory location that will receive the float values.
/// \param __m
/// A 128-bit integer vector containing the mask. The most significant bit of
/// each field in the mask vector represents the mask bits. If a mask bit is
/// zero, the corresponding value from vector __a is not stored and the
/// corresponding field in the memory location pointed to by \a __p is not
/// changed.
/// \param __a
/// A 128-bit vector of [4 x float] containing the values to be stored.
static __inline void __DEFAULT_FN_ATTRS
_mm_maskstore_ps(float *__p, __m128i __m, __m128 __a)
{
__builtin_ia32_maskstoreps((__v4sf *)__p, (__v4si)__m, (__v4sf)__a);
}
/* Cacheability support ops */
/// Moves integer data from a 256-bit integer vector to a 32-byte
/// aligned memory location. To minimize caching, the data is flagged as
/// non-temporal (unlikely to be used again soon).
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVNTDQ </c> instruction.
///
/// \param __a
/// A pointer to a 32-byte aligned memory location that will receive the
/// integer values.
/// \param __b
/// A 256-bit integer vector containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_stream_si256(__m256i *__a, __m256i __b)
{
typedef __v4di __v4di_aligned __attribute__((aligned(32)));
__builtin_nontemporal_store((__v4di_aligned)__b, (__v4di_aligned*)__a);
}
/// Moves double-precision values from a 256-bit vector of [4 x double]
/// to a 32-byte aligned memory location. To minimize caching, the data is
/// flagged as non-temporal (unlikely to be used again soon).
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVNTPD </c> instruction.
///
/// \param __a
/// A pointer to a 32-byte aligned memory location that will receive the
/// double-precision floating-point values.
/// \param __b
/// A 256-bit vector of [4 x double] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_stream_pd(double *__a, __m256d __b)
{
typedef __v4df __v4df_aligned __attribute__((aligned(32)));
__builtin_nontemporal_store((__v4df_aligned)__b, (__v4df_aligned*)__a);
}
/// Moves single-precision floating point values from a 256-bit vector
/// of [8 x float] to a 32-byte aligned memory location. To minimize
/// caching, the data is flagged as non-temporal (unlikely to be used again
/// soon).
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVNTPS </c> instruction.
///
/// \param __p
/// A pointer to a 32-byte aligned memory location that will receive the
/// single-precision floating point values.
/// \param __a
/// A 256-bit vector of [8 x float] containing the values to be moved.
static __inline void __DEFAULT_FN_ATTRS
_mm256_stream_ps(float *__p, __m256 __a)
{
typedef __v8sf __v8sf_aligned __attribute__((aligned(32)));
__builtin_nontemporal_store((__v8sf_aligned)__a, (__v8sf_aligned*)__p);
}
/* Create vectors */
/// Create a 256-bit vector of [4 x double] with undefined values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \returns A 256-bit vector of [4 x double] containing undefined values.
static __inline__ __m256d __DEFAULT_FN_ATTRS
_mm256_undefined_pd(void)
{
return (__m256d)__builtin_ia32_undef256();
}
/// Create a 256-bit vector of [8 x float] with undefined values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \returns A 256-bit vector of [8 x float] containing undefined values.
static __inline__ __m256 __DEFAULT_FN_ATTRS
_mm256_undefined_ps(void)
{
return (__m256)__builtin_ia32_undef256();
}
/// Create a 256-bit integer vector with undefined values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \returns A 256-bit integer vector containing undefined values.
static __inline__ __m256i __DEFAULT_FN_ATTRS
_mm256_undefined_si256(void)
{
return (__m256i)__builtin_ia32_undef256();
}
/// Constructs a 256-bit floating-point vector of [4 x double]
/// initialized with the specified double-precision floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKLPD+VINSERTF128 </c>
/// instruction.
///
/// \param __a
/// A double-precision floating-point value used to initialize bits [255:192]
/// of the result.
/// \param __b
/// A double-precision floating-point value used to initialize bits [191:128]
/// of the result.
/// \param __c
/// A double-precision floating-point value used to initialize bits [127:64]
/// of the result.
/// \param __d
/// A double-precision floating-point value used to initialize bits [63:0]
/// of the result.
/// \returns An initialized 256-bit floating-point vector of [4 x double].
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_set_pd(double __a, double __b, double __c, double __d)
{
return __extension__ (__m256d){ __d, __c, __b, __a };
}
/// Constructs a 256-bit floating-point vector of [8 x float] initialized
/// with the specified single-precision floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __a
/// A single-precision floating-point value used to initialize bits [255:224]
/// of the result.
/// \param __b
/// A single-precision floating-point value used to initialize bits [223:192]
/// of the result.
/// \param __c
/// A single-precision floating-point value used to initialize bits [191:160]
/// of the result.
/// \param __d
/// A single-precision floating-point value used to initialize bits [159:128]
/// of the result.
/// \param __e
/// A single-precision floating-point value used to initialize bits [127:96]
/// of the result.
/// \param __f
/// A single-precision floating-point value used to initialize bits [95:64]
/// of the result.
/// \param __g
/// A single-precision floating-point value used to initialize bits [63:32]
/// of the result.
/// \param __h
/// A single-precision floating-point value used to initialize bits [31:0]
/// of the result.
/// \returns An initialized 256-bit floating-point vector of [8 x float].
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_set_ps(float __a, float __b, float __c, float __d,
float __e, float __f, float __g, float __h)
{
return __extension__ (__m256){ __h, __g, __f, __e, __d, __c, __b, __a };
}
/// Constructs a 256-bit integer vector initialized with the specified
/// 32-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __i0
/// A 32-bit integral value used to initialize bits [255:224] of the result.
/// \param __i1
/// A 32-bit integral value used to initialize bits [223:192] of the result.
/// \param __i2
/// A 32-bit integral value used to initialize bits [191:160] of the result.
/// \param __i3
/// A 32-bit integral value used to initialize bits [159:128] of the result.
/// \param __i4
/// A 32-bit integral value used to initialize bits [127:96] of the result.
/// \param __i5
/// A 32-bit integral value used to initialize bits [95:64] of the result.
/// \param __i6
/// A 32-bit integral value used to initialize bits [63:32] of the result.
/// \param __i7
/// A 32-bit integral value used to initialize bits [31:0] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set_epi32(int __i0, int __i1, int __i2, int __i3,
int __i4, int __i5, int __i6, int __i7)
{
return __extension__ (__m256i)(__v8si){ __i7, __i6, __i5, __i4, __i3, __i2, __i1, __i0 };
}
/// Constructs a 256-bit integer vector initialized with the specified
/// 16-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __w15
/// A 16-bit integral value used to initialize bits [255:240] of the result.
/// \param __w14
/// A 16-bit integral value used to initialize bits [239:224] of the result.
/// \param __w13
/// A 16-bit integral value used to initialize bits [223:208] of the result.
/// \param __w12
/// A 16-bit integral value used to initialize bits [207:192] of the result.
/// \param __w11
/// A 16-bit integral value used to initialize bits [191:176] of the result.
/// \param __w10
/// A 16-bit integral value used to initialize bits [175:160] of the result.
/// \param __w09
/// A 16-bit integral value used to initialize bits [159:144] of the result.
/// \param __w08
/// A 16-bit integral value used to initialize bits [143:128] of the result.
/// \param __w07
/// A 16-bit integral value used to initialize bits [127:112] of the result.
/// \param __w06
/// A 16-bit integral value used to initialize bits [111:96] of the result.
/// \param __w05
/// A 16-bit integral value used to initialize bits [95:80] of the result.
/// \param __w04
/// A 16-bit integral value used to initialize bits [79:64] of the result.
/// \param __w03
/// A 16-bit integral value used to initialize bits [63:48] of the result.
/// \param __w02
/// A 16-bit integral value used to initialize bits [47:32] of the result.
/// \param __w01
/// A 16-bit integral value used to initialize bits [31:16] of the result.
/// \param __w00
/// A 16-bit integral value used to initialize bits [15:0] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set_epi16(short __w15, short __w14, short __w13, short __w12,
short __w11, short __w10, short __w09, short __w08,
short __w07, short __w06, short __w05, short __w04,
short __w03, short __w02, short __w01, short __w00)
{
return __extension__ (__m256i)(__v16hi){ __w00, __w01, __w02, __w03, __w04, __w05, __w06,
__w07, __w08, __w09, __w10, __w11, __w12, __w13, __w14, __w15 };
}
/// Constructs a 256-bit integer vector initialized with the specified
/// 8-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __b31
/// An 8-bit integral value used to initialize bits [255:248] of the result.
/// \param __b30
/// An 8-bit integral value used to initialize bits [247:240] of the result.
/// \param __b29
/// An 8-bit integral value used to initialize bits [239:232] of the result.
/// \param __b28
/// An 8-bit integral value used to initialize bits [231:224] of the result.
/// \param __b27
/// An 8-bit integral value used to initialize bits [223:216] of the result.
/// \param __b26
/// An 8-bit integral value used to initialize bits [215:208] of the result.
/// \param __b25
/// An 8-bit integral value used to initialize bits [207:200] of the result.
/// \param __b24
/// An 8-bit integral value used to initialize bits [199:192] of the result.
/// \param __b23
/// An 8-bit integral value used to initialize bits [191:184] of the result.
/// \param __b22
/// An 8-bit integral value used to initialize bits [183:176] of the result.
/// \param __b21
/// An 8-bit integral value used to initialize bits [175:168] of the result.
/// \param __b20
/// An 8-bit integral value used to initialize bits [167:160] of the result.
/// \param __b19
/// An 8-bit integral value used to initialize bits [159:152] of the result.
/// \param __b18
/// An 8-bit integral value used to initialize bits [151:144] of the result.
/// \param __b17
/// An 8-bit integral value used to initialize bits [143:136] of the result.
/// \param __b16
/// An 8-bit integral value used to initialize bits [135:128] of the result.
/// \param __b15
/// An 8-bit integral value used to initialize bits [127:120] of the result.
/// \param __b14
/// An 8-bit integral value used to initialize bits [119:112] of the result.
/// \param __b13
/// An 8-bit integral value used to initialize bits [111:104] of the result.
/// \param __b12
/// An 8-bit integral value used to initialize bits [103:96] of the result.
/// \param __b11
/// An 8-bit integral value used to initialize bits [95:88] of the result.
/// \param __b10
/// An 8-bit integral value used to initialize bits [87:80] of the result.
/// \param __b09
/// An 8-bit integral value used to initialize bits [79:72] of the result.
/// \param __b08
/// An 8-bit integral value used to initialize bits [71:64] of the result.
/// \param __b07
/// An 8-bit integral value used to initialize bits [63:56] of the result.
/// \param __b06
/// An 8-bit integral value used to initialize bits [55:48] of the result.
/// \param __b05
/// An 8-bit integral value used to initialize bits [47:40] of the result.
/// \param __b04
/// An 8-bit integral value used to initialize bits [39:32] of the result.
/// \param __b03
/// An 8-bit integral value used to initialize bits [31:24] of the result.
/// \param __b02
/// An 8-bit integral value used to initialize bits [23:16] of the result.
/// \param __b01
/// An 8-bit integral value used to initialize bits [15:8] of the result.
/// \param __b00
/// An 8-bit integral value used to initialize bits [7:0] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set_epi8(char __b31, char __b30, char __b29, char __b28,
char __b27, char __b26, char __b25, char __b24,
char __b23, char __b22, char __b21, char __b20,
char __b19, char __b18, char __b17, char __b16,
char __b15, char __b14, char __b13, char __b12,
char __b11, char __b10, char __b09, char __b08,
char __b07, char __b06, char __b05, char __b04,
char __b03, char __b02, char __b01, char __b00)
{
return __extension__ (__m256i)(__v32qi){
__b00, __b01, __b02, __b03, __b04, __b05, __b06, __b07,
__b08, __b09, __b10, __b11, __b12, __b13, __b14, __b15,
__b16, __b17, __b18, __b19, __b20, __b21, __b22, __b23,
__b24, __b25, __b26, __b27, __b28, __b29, __b30, __b31
};
}
/// Constructs a 256-bit integer vector initialized with the specified
/// 64-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPUNPCKLQDQ+VINSERTF128 </c>
/// instruction.
///
/// \param __a
/// A 64-bit integral value used to initialize bits [255:192] of the result.
/// \param __b
/// A 64-bit integral value used to initialize bits [191:128] of the result.
/// \param __c
/// A 64-bit integral value used to initialize bits [127:64] of the result.
/// \param __d
/// A 64-bit integral value used to initialize bits [63:0] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set_epi64x(long long __a, long long __b, long long __c, long long __d)
{
return __extension__ (__m256i)(__v4di){ __d, __c, __b, __a };
}
/* Create vectors with elements in reverse order */
/// Constructs a 256-bit floating-point vector of [4 x double],
/// initialized in reverse order with the specified double-precision
/// floating-point values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VUNPCKLPD+VINSERTF128 </c>
/// instruction.
///
/// \param __a
/// A double-precision floating-point value used to initialize bits [63:0]
/// of the result.
/// \param __b
/// A double-precision floating-point value used to initialize bits [127:64]
/// of the result.
/// \param __c
/// A double-precision floating-point value used to initialize bits [191:128]
/// of the result.
/// \param __d
/// A double-precision floating-point value used to initialize bits [255:192]
/// of the result.
/// \returns An initialized 256-bit floating-point vector of [4 x double].
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_setr_pd(double __a, double __b, double __c, double __d)
{
return _mm256_set_pd(__d, __c, __b, __a);
}
/// Constructs a 256-bit floating-point vector of [8 x float],
/// initialized in reverse order with the specified single-precision
/// float-point values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __a
/// A single-precision floating-point value used to initialize bits [31:0]
/// of the result.
/// \param __b
/// A single-precision floating-point value used to initialize bits [63:32]
/// of the result.
/// \param __c
/// A single-precision floating-point value used to initialize bits [95:64]
/// of the result.
/// \param __d
/// A single-precision floating-point value used to initialize bits [127:96]
/// of the result.
/// \param __e
/// A single-precision floating-point value used to initialize bits [159:128]
/// of the result.
/// \param __f
/// A single-precision floating-point value used to initialize bits [191:160]
/// of the result.
/// \param __g
/// A single-precision floating-point value used to initialize bits [223:192]
/// of the result.
/// \param __h
/// A single-precision floating-point value used to initialize bits [255:224]
/// of the result.
/// \returns An initialized 256-bit floating-point vector of [8 x float].
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_setr_ps(float __a, float __b, float __c, float __d,
float __e, float __f, float __g, float __h)
{
return _mm256_set_ps(__h, __g, __f, __e, __d, __c, __b, __a);
}
/// Constructs a 256-bit integer vector, initialized in reverse order
/// with the specified 32-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __i0
/// A 32-bit integral value used to initialize bits [31:0] of the result.
/// \param __i1
/// A 32-bit integral value used to initialize bits [63:32] of the result.
/// \param __i2
/// A 32-bit integral value used to initialize bits [95:64] of the result.
/// \param __i3
/// A 32-bit integral value used to initialize bits [127:96] of the result.
/// \param __i4
/// A 32-bit integral value used to initialize bits [159:128] of the result.
/// \param __i5
/// A 32-bit integral value used to initialize bits [191:160] of the result.
/// \param __i6
/// A 32-bit integral value used to initialize bits [223:192] of the result.
/// \param __i7
/// A 32-bit integral value used to initialize bits [255:224] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setr_epi32(int __i0, int __i1, int __i2, int __i3,
int __i4, int __i5, int __i6, int __i7)
{
return _mm256_set_epi32(__i7, __i6, __i5, __i4, __i3, __i2, __i1, __i0);
}
/// Constructs a 256-bit integer vector, initialized in reverse order
/// with the specified 16-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __w15
/// A 16-bit integral value used to initialize bits [15:0] of the result.
/// \param __w14
/// A 16-bit integral value used to initialize bits [31:16] of the result.
/// \param __w13
/// A 16-bit integral value used to initialize bits [47:32] of the result.
/// \param __w12
/// A 16-bit integral value used to initialize bits [63:48] of the result.
/// \param __w11
/// A 16-bit integral value used to initialize bits [79:64] of the result.
/// \param __w10
/// A 16-bit integral value used to initialize bits [95:80] of the result.
/// \param __w09
/// A 16-bit integral value used to initialize bits [111:96] of the result.
/// \param __w08
/// A 16-bit integral value used to initialize bits [127:112] of the result.
/// \param __w07
/// A 16-bit integral value used to initialize bits [143:128] of the result.
/// \param __w06
/// A 16-bit integral value used to initialize bits [159:144] of the result.
/// \param __w05
/// A 16-bit integral value used to initialize bits [175:160] of the result.
/// \param __w04
/// A 16-bit integral value used to initialize bits [191:176] of the result.
/// \param __w03
/// A 16-bit integral value used to initialize bits [207:192] of the result.
/// \param __w02
/// A 16-bit integral value used to initialize bits [223:208] of the result.
/// \param __w01
/// A 16-bit integral value used to initialize bits [239:224] of the result.
/// \param __w00
/// A 16-bit integral value used to initialize bits [255:240] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setr_epi16(short __w15, short __w14, short __w13, short __w12,
short __w11, short __w10, short __w09, short __w08,
short __w07, short __w06, short __w05, short __w04,
short __w03, short __w02, short __w01, short __w00)
{
return _mm256_set_epi16(__w00, __w01, __w02, __w03,
__w04, __w05, __w06, __w07,
__w08, __w09, __w10, __w11,
__w12, __w13, __w14, __w15);
}
/// Constructs a 256-bit integer vector, initialized in reverse order
/// with the specified 8-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic is a utility function and does not correspond to a specific
/// instruction.
///
/// \param __b31
/// An 8-bit integral value used to initialize bits [7:0] of the result.
/// \param __b30
/// An 8-bit integral value used to initialize bits [15:8] of the result.
/// \param __b29
/// An 8-bit integral value used to initialize bits [23:16] of the result.
/// \param __b28
/// An 8-bit integral value used to initialize bits [31:24] of the result.
/// \param __b27
/// An 8-bit integral value used to initialize bits [39:32] of the result.
/// \param __b26
/// An 8-bit integral value used to initialize bits [47:40] of the result.
/// \param __b25
/// An 8-bit integral value used to initialize bits [55:48] of the result.
/// \param __b24
/// An 8-bit integral value used to initialize bits [63:56] of the result.
/// \param __b23
/// An 8-bit integral value used to initialize bits [71:64] of the result.
/// \param __b22
/// An 8-bit integral value used to initialize bits [79:72] of the result.
/// \param __b21
/// An 8-bit integral value used to initialize bits [87:80] of the result.
/// \param __b20
/// An 8-bit integral value used to initialize bits [95:88] of the result.
/// \param __b19
/// An 8-bit integral value used to initialize bits [103:96] of the result.
/// \param __b18
/// An 8-bit integral value used to initialize bits [111:104] of the result.
/// \param __b17
/// An 8-bit integral value used to initialize bits [119:112] of the result.
/// \param __b16
/// An 8-bit integral value used to initialize bits [127:120] of the result.
/// \param __b15
/// An 8-bit integral value used to initialize bits [135:128] of the result.
/// \param __b14
/// An 8-bit integral value used to initialize bits [143:136] of the result.
/// \param __b13
/// An 8-bit integral value used to initialize bits [151:144] of the result.
/// \param __b12
/// An 8-bit integral value used to initialize bits [159:152] of the result.
/// \param __b11
/// An 8-bit integral value used to initialize bits [167:160] of the result.
/// \param __b10
/// An 8-bit integral value used to initialize bits [175:168] of the result.
/// \param __b09
/// An 8-bit integral value used to initialize bits [183:176] of the result.
/// \param __b08
/// An 8-bit integral value used to initialize bits [191:184] of the result.
/// \param __b07
/// An 8-bit integral value used to initialize bits [199:192] of the result.
/// \param __b06
/// An 8-bit integral value used to initialize bits [207:200] of the result.
/// \param __b05
/// An 8-bit integral value used to initialize bits [215:208] of the result.
/// \param __b04
/// An 8-bit integral value used to initialize bits [223:216] of the result.
/// \param __b03
/// An 8-bit integral value used to initialize bits [231:224] of the result.
/// \param __b02
/// An 8-bit integral value used to initialize bits [239:232] of the result.
/// \param __b01
/// An 8-bit integral value used to initialize bits [247:240] of the result.
/// \param __b00
/// An 8-bit integral value used to initialize bits [255:248] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setr_epi8(char __b31, char __b30, char __b29, char __b28,
char __b27, char __b26, char __b25, char __b24,
char __b23, char __b22, char __b21, char __b20,
char __b19, char __b18, char __b17, char __b16,
char __b15, char __b14, char __b13, char __b12,
char __b11, char __b10, char __b09, char __b08,
char __b07, char __b06, char __b05, char __b04,
char __b03, char __b02, char __b01, char __b00)
{
return _mm256_set_epi8(__b00, __b01, __b02, __b03, __b04, __b05, __b06, __b07,
__b08, __b09, __b10, __b11, __b12, __b13, __b14, __b15,
__b16, __b17, __b18, __b19, __b20, __b21, __b22, __b23,
__b24, __b25, __b26, __b27, __b28, __b29, __b30, __b31);
}
/// Constructs a 256-bit integer vector, initialized in reverse order
/// with the specified 64-bit integral values.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPUNPCKLQDQ+VINSERTF128 </c>
/// instruction.
///
/// \param __a
/// A 64-bit integral value used to initialize bits [63:0] of the result.
/// \param __b
/// A 64-bit integral value used to initialize bits [127:64] of the result.
/// \param __c
/// A 64-bit integral value used to initialize bits [191:128] of the result.
/// \param __d
/// A 64-bit integral value used to initialize bits [255:192] of the result.
/// \returns An initialized 256-bit integer vector.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setr_epi64x(long long __a, long long __b, long long __c, long long __d)
{
return _mm256_set_epi64x(__d, __c, __b, __a);
}
/* Create vectors with repeated elements */
/// Constructs a 256-bit floating-point vector of [4 x double], with each
/// of the four double-precision floating-point vector elements set to the
/// specified double-precision floating-point value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDDUP+VINSERTF128 </c> instruction.
///
/// \param __w
/// A double-precision floating-point value used to initialize each vector
/// element of the result.
/// \returns An initialized 256-bit floating-point vector of [4 x double].
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_set1_pd(double __w)
{
return _mm256_set_pd(__w, __w, __w, __w);
}
/// Constructs a 256-bit floating-point vector of [8 x float], with each
/// of the eight single-precision floating-point vector elements set to the
/// specified single-precision floating-point value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPS+VINSERTF128 </c>
/// instruction.
///
/// \param __w
/// A single-precision floating-point value used to initialize each vector
/// element of the result.
/// \returns An initialized 256-bit floating-point vector of [8 x float].
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_set1_ps(float __w)
{
return _mm256_set_ps(__w, __w, __w, __w, __w, __w, __w, __w);
}
/// Constructs a 256-bit integer vector of [8 x i32], with each of the
/// 32-bit integral vector elements set to the specified 32-bit integral
/// value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPERMILPS+VINSERTF128 </c>
/// instruction.
///
/// \param __i
/// A 32-bit integral value used to initialize each vector element of the
/// result.
/// \returns An initialized 256-bit integer vector of [8 x i32].
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set1_epi32(int __i)
{
return _mm256_set_epi32(__i, __i, __i, __i, __i, __i, __i, __i);
}
/// Constructs a 256-bit integer vector of [16 x i16], with each of the
/// 16-bit integral vector elements set to the specified 16-bit integral
/// value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPSHUFB+VINSERTF128 </c> instruction.
///
/// \param __w
/// A 16-bit integral value used to initialize each vector element of the
/// result.
/// \returns An initialized 256-bit integer vector of [16 x i16].
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set1_epi16(short __w)
{
return _mm256_set_epi16(__w, __w, __w, __w, __w, __w, __w, __w,
__w, __w, __w, __w, __w, __w, __w, __w);
}
/// Constructs a 256-bit integer vector of [32 x i8], with each of the
/// 8-bit integral vector elements set to the specified 8-bit integral value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VPSHUFB+VINSERTF128 </c> instruction.
///
/// \param __b
/// An 8-bit integral value used to initialize each vector element of the
/// result.
/// \returns An initialized 256-bit integer vector of [32 x i8].
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set1_epi8(char __b)
{
return _mm256_set_epi8(__b, __b, __b, __b, __b, __b, __b, __b,
__b, __b, __b, __b, __b, __b, __b, __b,
__b, __b, __b, __b, __b, __b, __b, __b,
__b, __b, __b, __b, __b, __b, __b, __b);
}
/// Constructs a 256-bit integer vector of [4 x i64], with each of the
/// 64-bit integral vector elements set to the specified 64-bit integral
/// value.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VMOVDDUP+VINSERTF128 </c> instruction.
///
/// \param __q
/// A 64-bit integral value used to initialize each vector element of the
/// result.
/// \returns An initialized 256-bit integer vector of [4 x i64].
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set1_epi64x(long long __q)
{
return _mm256_set_epi64x(__q, __q, __q, __q);
}
/* Create __zeroed vectors */
/// Constructs a 256-bit floating-point vector of [4 x double] with all
/// vector elements initialized to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VXORPS </c> instruction.
///
/// \returns A 256-bit vector of [4 x double] with all elements set to zero.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_setzero_pd(void)
{
return __extension__ (__m256d){ 0, 0, 0, 0 };
}
/// Constructs a 256-bit floating-point vector of [8 x float] with all
/// vector elements initialized to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VXORPS </c> instruction.
///
/// \returns A 256-bit vector of [8 x float] with all elements set to zero.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_setzero_ps(void)
{
return __extension__ (__m256){ 0, 0, 0, 0, 0, 0, 0, 0 };
}
/// Constructs a 256-bit integer vector initialized to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VXORPS </c> instruction.
///
/// \returns A 256-bit integer vector initialized to zero.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setzero_si256(void)
{
return __extension__ (__m256i)(__v4di){ 0, 0, 0, 0 };
}
/* Cast between vector types */
/// Casts a 256-bit floating-point vector of [4 x double] into a 256-bit
/// floating-point vector of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [4 x double].
/// \returns A 256-bit floating-point vector of [8 x float] containing the same
/// bitwise pattern as the parameter.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_castpd_ps(__m256d __a)
{
return (__m256)__a;
}
/// Casts a 256-bit floating-point vector of [4 x double] into a 256-bit
/// integer vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [4 x double].
/// \returns A 256-bit integer vector containing the same bitwise pattern as the
/// parameter.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_castpd_si256(__m256d __a)
{
return (__m256i)__a;
}
/// Casts a 256-bit floating-point vector of [8 x float] into a 256-bit
/// floating-point vector of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [8 x float].
/// \returns A 256-bit floating-point vector of [4 x double] containing the same
/// bitwise pattern as the parameter.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_castps_pd(__m256 __a)
{
return (__m256d)__a;
}
/// Casts a 256-bit floating-point vector of [8 x float] into a 256-bit
/// integer vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [8 x float].
/// \returns A 256-bit integer vector containing the same bitwise pattern as the
/// parameter.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_castps_si256(__m256 __a)
{
return (__m256i)__a;
}
/// Casts a 256-bit integer vector into a 256-bit floating-point vector
/// of [8 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \returns A 256-bit floating-point vector of [8 x float] containing the same
/// bitwise pattern as the parameter.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_castsi256_ps(__m256i __a)
{
return (__m256)__a;
}
/// Casts a 256-bit integer vector into a 256-bit floating-point vector
/// of [4 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \returns A 256-bit floating-point vector of [4 x double] containing the same
/// bitwise pattern as the parameter.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_castsi256_pd(__m256i __a)
{
return (__m256d)__a;
}
/// Returns the lower 128 bits of a 256-bit floating-point vector of
/// [4 x double] as a 128-bit floating-point vector of [2 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [4 x double].
/// \returns A 128-bit floating-point vector of [2 x double] containing the
/// lower 128 bits of the parameter.
static __inline __m128d __DEFAULT_FN_ATTRS
_mm256_castpd256_pd128(__m256d __a)
{
return __builtin_shufflevector((__v4df)__a, (__v4df)__a, 0, 1);
}
/// Returns the lower 128 bits of a 256-bit floating-point vector of
/// [8 x float] as a 128-bit floating-point vector of [4 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit floating-point vector of [8 x float].
/// \returns A 128-bit floating-point vector of [4 x float] containing the
/// lower 128 bits of the parameter.
static __inline __m128 __DEFAULT_FN_ATTRS
_mm256_castps256_ps128(__m256 __a)
{
return __builtin_shufflevector((__v8sf)__a, (__v8sf)__a, 0, 1, 2, 3);
}
/// Truncates a 256-bit integer vector into a 128-bit integer vector.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 256-bit integer vector.
/// \returns A 128-bit integer vector containing the lower 128 bits of the
/// parameter.
static __inline __m128i __DEFAULT_FN_ATTRS
_mm256_castsi256_si128(__m256i __a)
{
return __builtin_shufflevector((__v4di)__a, (__v4di)__a, 0, 1);
}
/// Constructs a 256-bit floating-point vector of [4 x double] from a
/// 128-bit floating-point vector of [2 x double].
///
/// The lower 128 bits contain the value of the source vector. The contents
/// of the upper 128 bits are undefined.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \returns A 256-bit floating-point vector of [4 x double]. The lower 128 bits
/// contain the value of the parameter. The contents of the upper 128 bits
/// are undefined.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_castpd128_pd256(__m128d __a)
{
return __builtin_shufflevector((__v2df)__a, (__v2df)__a, 0, 1, -1, -1);
}
/// Constructs a 256-bit floating-point vector of [8 x float] from a
/// 128-bit floating-point vector of [4 x float].
///
/// The lower 128 bits contain the value of the source vector. The contents
/// of the upper 128 bits are undefined.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \returns A 256-bit floating-point vector of [8 x float]. The lower 128 bits
/// contain the value of the parameter. The contents of the upper 128 bits
/// are undefined.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_castps128_ps256(__m128 __a)
{
return __builtin_shufflevector((__v4sf)__a, (__v4sf)__a, 0, 1, 2, 3, -1, -1, -1, -1);
}
/// Constructs a 256-bit integer vector from a 128-bit integer vector.
///
/// The lower 128 bits contain the value of the source vector. The contents
/// of the upper 128 bits are undefined.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit integer vector.
/// \returns A 256-bit integer vector. The lower 128 bits contain the value of
/// the parameter. The contents of the upper 128 bits are undefined.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_castsi128_si256(__m128i __a)
{
return __builtin_shufflevector((__v2di)__a, (__v2di)__a, 0, 1, -1, -1);
}
/// Constructs a 256-bit floating-point vector of [4 x double] from a
/// 128-bit floating-point vector of [2 x double]. The lower 128 bits
/// contain the value of the source vector. The upper 128 bits are set
/// to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit vector of [2 x double].
/// \returns A 256-bit floating-point vector of [4 x double]. The lower 128 bits
/// contain the value of the parameter. The upper 128 bits are set to zero.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_zextpd128_pd256(__m128d __a)
{
return __builtin_shufflevector((__v2df)__a, (__v2df)_mm_setzero_pd(), 0, 1, 2, 3);
}
/// Constructs a 256-bit floating-point vector of [8 x float] from a
/// 128-bit floating-point vector of [4 x float]. The lower 128 bits contain
/// the value of the source vector. The upper 128 bits are set to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit vector of [4 x float].
/// \returns A 256-bit floating-point vector of [8 x float]. The lower 128 bits
/// contain the value of the parameter. The upper 128 bits are set to zero.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_zextps128_ps256(__m128 __a)
{
return __builtin_shufflevector((__v4sf)__a, (__v4sf)_mm_setzero_ps(), 0, 1, 2, 3, 4, 5, 6, 7);
}
/// Constructs a 256-bit integer vector from a 128-bit integer vector.
/// The lower 128 bits contain the value of the source vector. The upper
/// 128 bits are set to zero.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic has no corresponding instruction.
///
/// \param __a
/// A 128-bit integer vector.
/// \returns A 256-bit integer vector. The lower 128 bits contain the value of
/// the parameter. The upper 128 bits are set to zero.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_zextsi128_si256(__m128i __a)
{
return __builtin_shufflevector((__v2di)__a, (__v2di)_mm_setzero_si128(), 0, 1, 2, 3);
}
/*
Vector insert.
We use macros rather than inlines because we only want to accept
invocations where the immediate M is a constant expression.
*/
/// Constructs a new 256-bit vector of [8 x float] by first duplicating
/// a 256-bit vector of [8 x float] given in the first parameter, and then
/// replacing either the upper or the lower 128 bits with the contents of a
/// 128-bit vector of [4 x float] in the second parameter.
///
/// The immediate integer parameter determines between the upper or the lower
/// 128 bits.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256 _mm256_insertf128_ps(__m256 V1, __m128 V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param V1
/// A 256-bit vector of [8 x float]. This vector is copied to the result
/// first, and then either the upper or the lower 128 bits of the result will
/// be replaced by the contents of \a V2.
/// \param V2
/// A 128-bit vector of [4 x float]. The contents of this parameter are
/// written to either the upper or the lower 128 bits of the result depending
/// on the value of parameter \a M.
/// \param M
/// An immediate integer. The least significant bit determines how the values
/// from the two parameters are interleaved: \n
/// If bit [0] of \a M is 0, \a V2 are copied to bits [127:0] of the result,
/// and bits [255:128] of \a V1 are copied to bits [255:128] of the
/// result. \n
/// If bit [0] of \a M is 1, \a V2 are copied to bits [255:128] of the
/// result, and bits [127:0] of \a V1 are copied to bits [127:0] of the
/// result.
/// \returns A 256-bit vector of [8 x float] containing the interleaved values.
#define _mm256_insertf128_ps(V1, V2, M) \
(__m256)__builtin_ia32_vinsertf128_ps256((__v8sf)(__m256)(V1), \
(__v4sf)(__m128)(V2), (int)(M))
/// Constructs a new 256-bit vector of [4 x double] by first duplicating
/// a 256-bit vector of [4 x double] given in the first parameter, and then
/// replacing either the upper or the lower 128 bits with the contents of a
/// 128-bit vector of [2 x double] in the second parameter.
///
/// The immediate integer parameter determines between the upper or the lower
/// 128 bits.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256d _mm256_insertf128_pd(__m256d V1, __m128d V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param V1
/// A 256-bit vector of [4 x double]. This vector is copied to the result
/// first, and then either the upper or the lower 128 bits of the result will
/// be replaced by the contents of \a V2.
/// \param V2
/// A 128-bit vector of [2 x double]. The contents of this parameter are
/// written to either the upper or the lower 128 bits of the result depending
/// on the value of parameter \a M.
/// \param M
/// An immediate integer. The least significant bit determines how the values
/// from the two parameters are interleaved: \n
/// If bit [0] of \a M is 0, \a V2 are copied to bits [127:0] of the result,
/// and bits [255:128] of \a V1 are copied to bits [255:128] of the
/// result. \n
/// If bit [0] of \a M is 1, \a V2 are copied to bits [255:128] of the
/// result, and bits [127:0] of \a V1 are copied to bits [127:0] of the
/// result.
/// \returns A 256-bit vector of [4 x double] containing the interleaved values.
#define _mm256_insertf128_pd(V1, V2, M) \
(__m256d)__builtin_ia32_vinsertf128_pd256((__v4df)(__m256d)(V1), \
(__v2df)(__m128d)(V2), (int)(M))
/// Constructs a new 256-bit integer vector by first duplicating a
/// 256-bit integer vector given in the first parameter, and then replacing
/// either the upper or the lower 128 bits with the contents of a 128-bit
/// integer vector in the second parameter.
///
/// The immediate integer parameter determines between the upper or the lower
/// 128 bits.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m256i _mm256_insertf128_si256(__m256i V1, __m128i V2, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param V1
/// A 256-bit integer vector. This vector is copied to the result first, and
/// then either the upper or the lower 128 bits of the result will be
/// replaced by the contents of \a V2.
/// \param V2
/// A 128-bit integer vector. The contents of this parameter are written to
/// either the upper or the lower 128 bits of the result depending on the
/// value of parameter \a M.
/// \param M
/// An immediate integer. The least significant bit determines how the values
/// from the two parameters are interleaved: \n
/// If bit [0] of \a M is 0, \a V2 are copied to bits [127:0] of the result,
/// and bits [255:128] of \a V1 are copied to bits [255:128] of the
/// result. \n
/// If bit [0] of \a M is 1, \a V2 are copied to bits [255:128] of the
/// result, and bits [127:0] of \a V1 are copied to bits [127:0] of the
/// result.
/// \returns A 256-bit integer vector containing the interleaved values.
#define _mm256_insertf128_si256(V1, V2, M) \
(__m256i)__builtin_ia32_vinsertf128_si256((__v8si)(__m256i)(V1), \
(__v4si)(__m128i)(V2), (int)(M))
/*
Vector extract.
We use macros rather than inlines because we only want to accept
invocations where the immediate M is a constant expression.
*/
/// Extracts either the upper or the lower 128 bits from a 256-bit vector
/// of [8 x float], as determined by the immediate integer parameter, and
/// returns the extracted bits as a 128-bit vector of [4 x float].
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128 _mm256_extractf128_ps(__m256 V, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction.
///
/// \param V
/// A 256-bit vector of [8 x float].
/// \param M
/// An immediate integer. The least significant bit determines which bits are
/// extracted from the first parameter: \n
/// If bit [0] of \a M is 0, bits [127:0] of \a V are copied to the
/// result. \n
/// If bit [0] of \a M is 1, bits [255:128] of \a V are copied to the result.
/// \returns A 128-bit vector of [4 x float] containing the extracted bits.
#define _mm256_extractf128_ps(V, M) \
(__m128)__builtin_ia32_vextractf128_ps256((__v8sf)(__m256)(V), (int)(M))
/// Extracts either the upper or the lower 128 bits from a 256-bit vector
/// of [4 x double], as determined by the immediate integer parameter, and
/// returns the extracted bits as a 128-bit vector of [2 x double].
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128d _mm256_extractf128_pd(__m256d V, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction.
///
/// \param V
/// A 256-bit vector of [4 x double].
/// \param M
/// An immediate integer. The least significant bit determines which bits are
/// extracted from the first parameter: \n
/// If bit [0] of \a M is 0, bits [127:0] of \a V are copied to the
/// result. \n
/// If bit [0] of \a M is 1, bits [255:128] of \a V are copied to the result.
/// \returns A 128-bit vector of [2 x double] containing the extracted bits.
#define _mm256_extractf128_pd(V, M) \
(__m128d)__builtin_ia32_vextractf128_pd256((__v4df)(__m256d)(V), (int)(M))
/// Extracts either the upper or the lower 128 bits from a 256-bit
/// integer vector, as determined by the immediate integer parameter, and
/// returns the extracted bits as a 128-bit integer vector.
///
/// \headerfile <x86intrin.h>
///
/// \code
/// __m128i _mm256_extractf128_si256(__m256i V, const int M);
/// \endcode
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction.
///
/// \param V
/// A 256-bit integer vector.
/// \param M
/// An immediate integer. The least significant bit determines which bits are
/// extracted from the first parameter: \n
/// If bit [0] of \a M is 0, bits [127:0] of \a V are copied to the
/// result. \n
/// If bit [0] of \a M is 1, bits [255:128] of \a V are copied to the result.
/// \returns A 128-bit integer vector containing the extracted bits.
#define _mm256_extractf128_si256(V, M) \
(__m128i)__builtin_ia32_vextractf128_si256((__v8si)(__m256i)(V), (int)(M))
/* SIMD load ops (unaligned) */
/// Loads two 128-bit floating-point vectors of [4 x float] from
/// unaligned memory locations and constructs a 256-bit floating-point vector
/// of [8 x float] by concatenating the two 128-bit vectors.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to load instructions followed by the
/// <c> VINSERTF128 </c> instruction.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location containing 4 consecutive
/// single-precision floating-point values. These values are to be copied to
/// bits[255:128] of the result. The address of the memory location does not
/// have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location containing 4 consecutive
/// single-precision floating-point values. These values are to be copied to
/// bits[127:0] of the result. The address of the memory location does not
/// have to be aligned.
/// \returns A 256-bit floating-point vector of [8 x float] containing the
/// concatenated result.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_loadu2_m128(float const *__addr_hi, float const *__addr_lo)
{
__m256 __v256 = _mm256_castps128_ps256(_mm_loadu_ps(__addr_lo));
return _mm256_insertf128_ps(__v256, _mm_loadu_ps(__addr_hi), 1);
}
/// Loads two 128-bit floating-point vectors of [2 x double] from
/// unaligned memory locations and constructs a 256-bit floating-point vector
/// of [4 x double] by concatenating the two 128-bit vectors.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to load instructions followed by the
/// <c> VINSERTF128 </c> instruction.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location containing two consecutive
/// double-precision floating-point values. These values are to be copied to
/// bits[255:128] of the result. The address of the memory location does not
/// have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location containing two consecutive
/// double-precision floating-point values. These values are to be copied to
/// bits[127:0] of the result. The address of the memory location does not
/// have to be aligned.
/// \returns A 256-bit floating-point vector of [4 x double] containing the
/// concatenated result.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_loadu2_m128d(double const *__addr_hi, double const *__addr_lo)
{
__m256d __v256 = _mm256_castpd128_pd256(_mm_loadu_pd(__addr_lo));
return _mm256_insertf128_pd(__v256, _mm_loadu_pd(__addr_hi), 1);
}
/// Loads two 128-bit integer vectors from unaligned memory locations and
/// constructs a 256-bit integer vector by concatenating the two 128-bit
/// vectors.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to load instructions followed by the
/// <c> VINSERTF128 </c> instruction.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location containing a 128-bit integer
/// vector. This vector is to be copied to bits[255:128] of the result. The
/// address of the memory location does not have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location containing a 128-bit integer
/// vector. This vector is to be copied to bits[127:0] of the result. The
/// address of the memory location does not have to be aligned.
/// \returns A 256-bit integer vector containing the concatenated result.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_loadu2_m128i(__m128i const *__addr_hi, __m128i const *__addr_lo)
{
__m256i __v256 = _mm256_castsi128_si256(_mm_loadu_si128(__addr_lo));
return _mm256_insertf128_si256(__v256, _mm_loadu_si128(__addr_hi), 1);
}
/* SIMD store ops (unaligned) */
/// Stores the upper and lower 128 bits of a 256-bit floating-point
/// vector of [8 x float] into two different unaligned memory locations.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction and the
/// store instructions.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location. Bits[255:128] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location. Bits[127:0] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __a
/// A 256-bit floating-point vector of [8 x float].
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu2_m128(float *__addr_hi, float *__addr_lo, __m256 __a)
{
__m128 __v128;
__v128 = _mm256_castps256_ps128(__a);
_mm_storeu_ps(__addr_lo, __v128);
__v128 = _mm256_extractf128_ps(__a, 1);
_mm_storeu_ps(__addr_hi, __v128);
}
/// Stores the upper and lower 128 bits of a 256-bit floating-point
/// vector of [4 x double] into two different unaligned memory locations.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction and the
/// store instructions.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location. Bits[255:128] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location. Bits[127:0] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __a
/// A 256-bit floating-point vector of [4 x double].
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu2_m128d(double *__addr_hi, double *__addr_lo, __m256d __a)
{
__m128d __v128;
__v128 = _mm256_castpd256_pd128(__a);
_mm_storeu_pd(__addr_lo, __v128);
__v128 = _mm256_extractf128_pd(__a, 1);
_mm_storeu_pd(__addr_hi, __v128);
}
/// Stores the upper and lower 128 bits of a 256-bit integer vector into
/// two different unaligned memory locations.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VEXTRACTF128 </c> instruction and the
/// store instructions.
///
/// \param __addr_hi
/// A pointer to a 128-bit memory location. Bits[255:128] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __addr_lo
/// A pointer to a 128-bit memory location. Bits[127:0] of \a __a are to be
/// copied to this memory location. The address of this memory location does
/// not have to be aligned.
/// \param __a
/// A 256-bit integer vector.
static __inline void __DEFAULT_FN_ATTRS
_mm256_storeu2_m128i(__m128i *__addr_hi, __m128i *__addr_lo, __m256i __a)
{
__m128i __v128;
__v128 = _mm256_castsi256_si128(__a);
_mm_storeu_si128(__addr_lo, __v128);
__v128 = _mm256_extractf128_si256(__a, 1);
_mm_storeu_si128(__addr_hi, __v128);
}
/// Constructs a 256-bit floating-point vector of [8 x float] by
/// concatenating two 128-bit floating-point vectors of [4 x float].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __hi
/// A 128-bit floating-point vector of [4 x float] to be copied to the upper
/// 128 bits of the result.
/// \param __lo
/// A 128-bit floating-point vector of [4 x float] to be copied to the lower
/// 128 bits of the result.
/// \returns A 256-bit floating-point vector of [8 x float] containing the
/// concatenated result.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_set_m128 (__m128 __hi, __m128 __lo)
{
return (__m256) __builtin_shufflevector((__v4sf)__lo, (__v4sf)__hi, 0, 1, 2, 3, 4, 5, 6, 7);
}
/// Constructs a 256-bit floating-point vector of [4 x double] by
/// concatenating two 128-bit floating-point vectors of [2 x double].
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __hi
/// A 128-bit floating-point vector of [2 x double] to be copied to the upper
/// 128 bits of the result.
/// \param __lo
/// A 128-bit floating-point vector of [2 x double] to be copied to the lower
/// 128 bits of the result.
/// \returns A 256-bit floating-point vector of [4 x double] containing the
/// concatenated result.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_set_m128d (__m128d __hi, __m128d __lo)
{
return (__m256d)_mm256_set_m128((__m128)__hi, (__m128)__lo);
}
/// Constructs a 256-bit integer vector by concatenating two 128-bit
/// integer vectors.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __hi
/// A 128-bit integer vector to be copied to the upper 128 bits of the
/// result.
/// \param __lo
/// A 128-bit integer vector to be copied to the lower 128 bits of the
/// result.
/// \returns A 256-bit integer vector containing the concatenated result.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_set_m128i (__m128i __hi, __m128i __lo)
{
return (__m256i)_mm256_set_m128((__m128)__hi, (__m128)__lo);
}
/// Constructs a 256-bit floating-point vector of [8 x float] by
/// concatenating two 128-bit floating-point vectors of [4 x float]. This is
/// similar to _mm256_set_m128, but the order of the input parameters is
/// swapped.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __lo
/// A 128-bit floating-point vector of [4 x float] to be copied to the lower
/// 128 bits of the result.
/// \param __hi
/// A 128-bit floating-point vector of [4 x float] to be copied to the upper
/// 128 bits of the result.
/// \returns A 256-bit floating-point vector of [8 x float] containing the
/// concatenated result.
static __inline __m256 __DEFAULT_FN_ATTRS
_mm256_setr_m128 (__m128 __lo, __m128 __hi)
{
return _mm256_set_m128(__hi, __lo);
}
/// Constructs a 256-bit floating-point vector of [4 x double] by
/// concatenating two 128-bit floating-point vectors of [2 x double]. This is
/// similar to _mm256_set_m128d, but the order of the input parameters is
/// swapped.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __lo
/// A 128-bit floating-point vector of [2 x double] to be copied to the lower
/// 128 bits of the result.
/// \param __hi
/// A 128-bit floating-point vector of [2 x double] to be copied to the upper
/// 128 bits of the result.
/// \returns A 256-bit floating-point vector of [4 x double] containing the
/// concatenated result.
static __inline __m256d __DEFAULT_FN_ATTRS
_mm256_setr_m128d (__m128d __lo, __m128d __hi)
{
return (__m256d)_mm256_set_m128((__m128)__hi, (__m128)__lo);
}
/// Constructs a 256-bit integer vector by concatenating two 128-bit
/// integer vectors. This is similar to _mm256_set_m128i, but the order of
/// the input parameters is swapped.
///
/// \headerfile <x86intrin.h>
///
/// This intrinsic corresponds to the <c> VINSERTF128 </c> instruction.
///
/// \param __lo
/// A 128-bit integer vector to be copied to the lower 128 bits of the
/// result.
/// \param __hi
/// A 128-bit integer vector to be copied to the upper 128 bits of the
/// result.
/// \returns A 256-bit integer vector containing the concatenated result.
static __inline __m256i __DEFAULT_FN_ATTRS
_mm256_setr_m128i (__m128i __lo, __m128i __hi)
{
return (__m256i)_mm256_set_m128((__m128)__hi, (__m128)__lo);
}
#undef __DEFAULT_FN_ATTRS
#endif /* __AVXINTRIN_H */