clang/lib/Headers/amxcomplexintrin.h - llvm-project - Git at Google

 /*===--------- amxcomplexintrin.h - AMXCOMPLEX intrinsics -*- C++ -*---------===
  *
  * Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
  * See https://llvm.org/LICENSE.txt for license information.
  * SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
  *
  *===------------------------------------------------------------------------===
  */

 #ifndef __IMMINTRIN_H
 #error "Never use <amxcomplexintrin.h> directly; include <immintrin.h> instead."
 #endif // __IMMINTRIN_H

 #ifndef __AMX_COMPLEXINTRIN_H
 #define __AMX_COMPLEXINTRIN_H
 #ifdef __x86_64__

 #define __DEFAULT_FN_ATTRS_COMPLEX                                             \
   __attribute__((__always_inline__, __nodebug__, __target__("amx-complex")))

 /// Perform matrix multiplication of two tiles containing complex elements and
 ///    accumulate the results into a packed single precision tile. Each dword
 ///    element in input tiles \a a and \a b is interpreted as a complex number
 ///    with FP16 real part and FP16 imaginary part.
 /// Calculates the imaginary part of the result. For each possible combination
 ///    of (row of \a a, column of \a b), it performs a set of multiplication
 ///    and accumulations on all corresponding complex numbers (one from \a a
 ///    and one from \a b). The imaginary part of the \a a element is multiplied
 ///    with the real part of the corresponding \a b element, and the real part
 ///    of the \a a element is multiplied with the imaginary part of the
 ///    corresponding \a b elements. The two accumulated results are added, and
 ///    then accumulated into the corresponding row and column of \a dst.
 ///
 /// \headerfile <x86intrin.h>
 ///
 /// \code
 /// void _tile_cmmimfp16ps(__tile dst, __tile a, __tile b);
 /// \endcode
 ///
 /// \code{.operation}
 /// FOR m := 0 TO dst.rows - 1
 ///	tmp := dst.row[m]
 ///	FOR k := 0 TO (a.colsb / 4) - 1
 ///		FOR n := 0 TO (dst.colsb / 4) - 1
 ///			tmp.fp32[n] += FP32(a.row[m].fp16[2*k+0]) * FP32(b.row[k].fp16[2*n+1])
 ///			tmp.fp32[n] += FP32(a.row[m].fp16[2*k+1]) * FP32(b.row[k].fp16[2*n+0])
 ///		ENDFOR
 ///	ENDFOR
 ///	write_row_and_zero(dst, m, tmp, dst.colsb)
 /// ENDFOR
 /// zero_upper_rows(dst, dst.rows)
 /// zero_tileconfig_start()
 /// \endcode
 ///
 /// This intrinsic corresponds to the \c TCMMIMFP16PS instruction.
 ///
 /// \param dst
 ///    The destination tile. Max size is 1024 Bytes.
 /// \param a
 ///    The 1st source tile. Max size is 1024 Bytes.
 /// \param b
 ///    The 2nd source tile. Max size is 1024 Bytes.
 #define _tile_cmmimfp16ps(dst, a, b) __builtin_ia32_tcmmimfp16ps(dst, a, b)

 /// Perform matrix multiplication of two tiles containing complex elements and
 ///    accumulate the results into a packed single precision tile. Each dword
 ///    element in input tiles \a a and \a b is interpreted as a complex number
 ///    with FP16 real part and FP16 imaginary part.
 /// Calculates the real part of the result. For each possible combination
 ///    of (row of \a a, column of \a b), it performs a set of multiplication
 ///    and accumulations on all corresponding complex numbers (one from \a a
 ///    and one from \a b). The real part of the \a a element is multiplied
 ///    with the real part of the corresponding \a b element, and the negated
 ///    imaginary part of the \a a element is multiplied with the imaginary
 ///    part of the corresponding \a b elements. The two accumulated results
 ///    are added, and then accumulated into the corresponding row and column
 ///    of \a dst.
 ///
 /// \headerfile <x86intrin.h>
 ///
 /// \code
 /// void _tile_cmmrlfp16ps(__tile dst, __tile a, __tile b);
 /// \endcode
 ///
 /// \code{.operation}
 /// FOR m := 0 TO dst.rows - 1
 ///	tmp := dst.row[m]
 ///	FOR k := 0 TO (a.colsb / 4) - 1
 ///		FOR n := 0 TO (dst.colsb / 4) - 1
 ///			tmp.fp32[n] += FP32(a.row[m].fp16[2*k+0]) * FP32(b.row[k].fp16[2*n+0])
 ///			tmp.fp32[n] += FP32(-a.row[m].fp16[2*k+1]) * FP32(b.row[k].fp16[2*n+1])
 ///		ENDFOR
 ///	ENDFOR
 ///	write_row_and_zero(dst, m, tmp, dst.colsb)
 /// ENDFOR
 /// zero_upper_rows(dst, dst.rows)
 /// zero_tileconfig_start()
 /// \endcode
 ///
 /// This intrinsic corresponds to the \c TCMMIMFP16PS instruction.
 ///
 /// \param dst
 ///    The destination tile. Max size is 1024 Bytes.
 /// \param a
 ///    The 1st source tile. Max size is 1024 Bytes.
 /// \param b
 ///    The 2nd source tile. Max size is 1024 Bytes.
 #define _tile_cmmrlfp16ps(dst, a, b) __builtin_ia32_tcmmrlfp16ps(dst, a, b)

 static __inline__ _tile1024i __DEFAULT_FN_ATTRS_COMPLEX
 _tile_cmmimfp16ps_internal(unsigned short m, unsigned short n, unsigned short k,
                            _tile1024i dst, _tile1024i src1, _tile1024i src2) {
   return __builtin_ia32_tcmmimfp16ps_internal(m, n, k, dst, src1, src2);
 }

 static __inline__ _tile1024i __DEFAULT_FN_ATTRS_COMPLEX
 _tile_cmmrlfp16ps_internal(unsigned short m, unsigned short n, unsigned short k,
                            _tile1024i dst, _tile1024i src1, _tile1024i src2) {
   return __builtin_ia32_tcmmrlfp16ps_internal(m, n, k, dst, src1, src2);
 }

 /// Perform matrix multiplication of two tiles containing complex elements and
 /// accumulate the results into a packed single precision tile. Each dword
 /// element in input tiles src0 and src1 is interpreted as a complex number with
 /// FP16 real part and FP16 imaginary part.
 /// This function calculates the imaginary part of the result.
 ///
 /// \headerfile <immintrin.h>
 ///
 /// This intrinsic corresponds to the <c> TCMMIMFP16PS </c> instruction.
 ///
 /// \param dst
 ///    The destination tile. Max size is 1024 Bytes.
 /// \param src0
 ///    The 1st source tile. Max size is 1024 Bytes.
 /// \param src1
 ///    The 2nd source tile. Max size is 1024 Bytes.
 __DEFAULT_FN_ATTRS_COMPLEX
 static void __tile_cmmimfp16ps(__tile1024i *dst, __tile1024i src0,
                                __tile1024i src1) {
   dst->tile = _tile_cmmimfp16ps_internal(src0.row, src1.col, src0.col,
                                          dst->tile, src0.tile, src1.tile);
 }

 /// Perform matrix multiplication of two tiles containing complex elements and
 /// accumulate the results into a packed single precision tile. Each dword
 /// element in input tiles src0 and src1 is interpreted as a complex number with
 /// FP16 real part and FP16 imaginary part.
 /// This function calculates the real part of the result.
 ///
 /// \headerfile <immintrin.h>
 ///
 /// This intrinsic corresponds to the <c> TCMMRLFP16PS </c> instruction.
 ///
 /// \param dst
 ///    The destination tile. Max size is 1024 Bytes.
 /// \param src0
 ///    The 1st source tile. Max size is 1024 Bytes.
 /// \param src1
 ///    The 2nd source tile. Max size is 1024 Bytes.
 __DEFAULT_FN_ATTRS_COMPLEX
 static void __tile_cmmrlfp16ps(__tile1024i *dst, __tile1024i src0,
                                __tile1024i src1) {
   dst->tile = _tile_cmmrlfp16ps_internal(src0.row, src1.col, src0.col,
                                          dst->tile, src0.tile, src1.tile);
 }

 #endif // __x86_64__
 #endif // __AMX_COMPLEXINTRIN_H
	/===--------- amxcomplexintrin.h - AMXCOMPLEX intrinsics -- C++ -*---------===
	*
	* Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	* See https://llvm.org/LICENSE.txt for license information.
	* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	*
	*===------------------------------------------------------------------------===
	*/

	#ifndef __IMMINTRIN_H
	#error "Never use <amxcomplexintrin.h> directly; include <immintrin.h> instead."
	#endif // __IMMINTRIN_H

	#ifndef __AMX_COMPLEXINTRIN_H
	#define __AMX_COMPLEXINTRIN_H
	#ifdef __x86_64__

	#define __DEFAULT_FN_ATTRS_COMPLEX \
	__attribute__((__always_inline__, __nodebug__, __target__("amx-complex")))

	/// Perform matrix multiplication of two tiles containing complex elements and
	/// accumulate the results into a packed single precision tile. Each dword
	/// element in input tiles \a a and \a b is interpreted as a complex number
	/// with FP16 real part and FP16 imaginary part.
	/// Calculates the imaginary part of the result. For each possible combination
	/// of (row of \a a, column of \a b), it performs a set of multiplication
	/// and accumulations on all corresponding complex numbers (one from \a a
	/// and one from \a b). The imaginary part of the \a a element is multiplied
	/// with the real part of the corresponding \a b element, and the real part
	/// of the \a a element is multiplied with the imaginary part of the
	/// corresponding \a b elements. The two accumulated results are added, and
	/// then accumulated into the corresponding row and column of \a dst.
	///
	/// \headerfile <x86intrin.h>
	///
	/// \code
	/// void _tile_cmmimfp16ps(__tile dst, __tile a, __tile b);
	/// \endcode
	///
	/// \code{.operation}
	/// FOR m := 0 TO dst.rows - 1
	/// tmp := dst.row[m]
	/// FOR k := 0 TO (a.colsb / 4) - 1
	/// FOR n := 0 TO (dst.colsb / 4) - 1
	/// tmp.fp32[n] += FP32(a.row[m].fp16[2k+0]) FP32(b.row[k].fp16[2*n+1])
	/// tmp.fp32[n] += FP32(a.row[m].fp16[2k+1]) FP32(b.row[k].fp16[2*n+0])
	/// ENDFOR
	/// ENDFOR
	/// write_row_and_zero(dst, m, tmp, dst.colsb)
	/// ENDFOR
	/// zero_upper_rows(dst, dst.rows)
	/// zero_tileconfig_start()
	/// \endcode
	///
	/// This intrinsic corresponds to the \c TCMMIMFP16PS instruction.
	///
	/// \param dst
	/// The destination tile. Max size is 1024 Bytes.
	/// \param a
	/// The 1st source tile. Max size is 1024 Bytes.
	/// \param b
	/// The 2nd source tile. Max size is 1024 Bytes.
	#define _tile_cmmimfp16ps(dst, a, b) __builtin_ia32_tcmmimfp16ps(dst, a, b)

	/// Perform matrix multiplication of two tiles containing complex elements and
	/// accumulate the results into a packed single precision tile. Each dword
	/// element in input tiles \a a and \a b is interpreted as a complex number
	/// with FP16 real part and FP16 imaginary part.
	/// Calculates the real part of the result. For each possible combination
	/// of (row of \a a, column of \a b), it performs a set of multiplication
	/// and accumulations on all corresponding complex numbers (one from \a a
	/// and one from \a b). The real part of the \a a element is multiplied
	/// with the real part of the corresponding \a b element, and the negated
	/// imaginary part of the \a a element is multiplied with the imaginary
	/// part of the corresponding \a b elements. The two accumulated results
	/// are added, and then accumulated into the corresponding row and column
	/// of \a dst.
	///
	/// \headerfile <x86intrin.h>
	///
	/// \code
	/// void _tile_cmmrlfp16ps(__tile dst, __tile a, __tile b);
	/// \endcode
	///
	/// \code{.operation}
	/// FOR m := 0 TO dst.rows - 1
	/// tmp := dst.row[m]
	/// FOR k := 0 TO (a.colsb / 4) - 1
	/// FOR n := 0 TO (dst.colsb / 4) - 1
	/// tmp.fp32[n] += FP32(a.row[m].fp16[2k+0]) FP32(b.row[k].fp16[2*n+0])
	/// tmp.fp32[n] += FP32(-a.row[m].fp16[2k+1]) FP32(b.row[k].fp16[2*n+1])
	/// ENDFOR
	/// ENDFOR
	/// write_row_and_zero(dst, m, tmp, dst.colsb)
	/// ENDFOR
	/// zero_upper_rows(dst, dst.rows)
	/// zero_tileconfig_start()
	/// \endcode
	///
	/// This intrinsic corresponds to the \c TCMMIMFP16PS instruction.
	///
	/// \param dst
	/// The destination tile. Max size is 1024 Bytes.
	/// \param a
	/// The 1st source tile. Max size is 1024 Bytes.
	/// \param b
	/// The 2nd source tile. Max size is 1024 Bytes.
	#define _tile_cmmrlfp16ps(dst, a, b) __builtin_ia32_tcmmrlfp16ps(dst, a, b)

	static __inline__ _tile1024i __DEFAULT_FN_ATTRS_COMPLEX
	_tile_cmmimfp16ps_internal(unsigned short m, unsigned short n, unsigned short k,
	_tile1024i dst, _tile1024i src1, _tile1024i src2) {
	return __builtin_ia32_tcmmimfp16ps_internal(m, n, k, dst, src1, src2);
	}

	static __inline__ _tile1024i __DEFAULT_FN_ATTRS_COMPLEX
	_tile_cmmrlfp16ps_internal(unsigned short m, unsigned short n, unsigned short k,
	_tile1024i dst, _tile1024i src1, _tile1024i src2) {
	return __builtin_ia32_tcmmrlfp16ps_internal(m, n, k, dst, src1, src2);
	}

	/// Perform matrix multiplication of two tiles containing complex elements and
	/// accumulate the results into a packed single precision tile. Each dword
	/// element in input tiles src0 and src1 is interpreted as a complex number with
	/// FP16 real part and FP16 imaginary part.
	/// This function calculates the imaginary part of the result.
	///
	/// \headerfile <immintrin.h>
	///
	/// This intrinsic corresponds to the <c> TCMMIMFP16PS </c> instruction.
	///
	/// \param dst
	/// The destination tile. Max size is 1024 Bytes.
	/// \param src0
	/// The 1st source tile. Max size is 1024 Bytes.
	/// \param src1
	/// The 2nd source tile. Max size is 1024 Bytes.
	__DEFAULT_FN_ATTRS_COMPLEX
	static void __tile_cmmimfp16ps(__tile1024i *dst, __tile1024i src0,
	__tile1024i src1) {
	dst->tile = _tile_cmmimfp16ps_internal(src0.row, src1.col, src0.col,
	dst->tile, src0.tile, src1.tile);
	}

	/// Perform matrix multiplication of two tiles containing complex elements and
	/// accumulate the results into a packed single precision tile. Each dword
	/// element in input tiles src0 and src1 is interpreted as a complex number with
	/// FP16 real part and FP16 imaginary part.
	/// This function calculates the real part of the result.
	///
	/// \headerfile <immintrin.h>
	///
	/// This intrinsic corresponds to the <c> TCMMRLFP16PS </c> instruction.
	///
	/// \param dst
	/// The destination tile. Max size is 1024 Bytes.
	/// \param src0
	/// The 1st source tile. Max size is 1024 Bytes.
	/// \param src1
	/// The 2nd source tile. Max size is 1024 Bytes.
	__DEFAULT_FN_ATTRS_COMPLEX
	static void __tile_cmmrlfp16ps(__tile1024i *dst, __tile1024i src0,
	__tile1024i src1) {
	dst->tile = _tile_cmmrlfp16ps_internal(src0.row, src1.col, src0.col,
	dst->tile, src0.tile, src1.tile);
	}

	#endif // __x86_64__
	#endif // __AMX_COMPLEXINTRIN_H