cosmopolitan/third_party/intel/clang/amxcomplexintrin.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[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
Release Cosmopolitan v3.8.0 This change switches c++ exception handling from sjlj to standard dwarf. It's needed because clang for aarch64 doesn't support sjlj. It turns out that libunwind had a bare-metal configuration that made this easy to do. This change gets the new experimental cosmocc -mclang flag in a state of working so well that it can now be used to build all of llamafile and it goes 3x faster in terms of build latency, without trading away any perf. The int_fast16_t and int_fast32_t types are now always defined as 32-bit in the interest of having more abi consistency between cosmocc -mgcc and -mclang mode. 2024-08-31 03:12:26 +00:00			`/===--------- 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`