From 202532502562a2acb843b9f0804534f5e22730a2 Mon Sep 17 00:00:00 2001 From: Steven Munroe Date: Fri, 25 Aug 2017 15:11:50 +0000 Subject: [PATCH] Part 2/3 for contributing PPC64LE support for X86 SSE instrisics. Part 2/3 for contributing PPC64LE support for X86 SSE instrisics. This patch includes the new (for PPC) xmmintrin.h, changes x86intrin.h to include xmmintrin.h and associated config.gcc changes. From-SVN: r251356 --- gcc/ChangeLog | 6 + gcc/config.gcc | 1 + gcc/config/rs6000/x86intrin.h | 2 + gcc/config/rs6000/xmmintrin.h | 1821 +++++++++++++++++++++++++++++++++++++++++ 4 files changed, 1830 insertions(+) create mode 100644 gcc/config/rs6000/xmmintrin.h diff --git a/gcc/ChangeLog b/gcc/ChangeLog index d509afb..5a425e3 100644 --- a/gcc/ChangeLog +++ b/gcc/ChangeLog @@ -1,3 +1,9 @@ +2017-08-25 Steven Munroe + + * config.gcc (powerpc*-*-*): Add xmmintrin.h and mm_malloc.h. + * config/rs6000/xmmintrin.h: New file. + * config/rs6000/x86intrin.h [__ALTIVEC__]: Include xmmintrin.h. + 2017-08-25 Bill Schmidt PR target/81504 diff --git a/gcc/config.gcc b/gcc/config.gcc index 446cab3..cc56c57 100644 --- a/gcc/config.gcc +++ b/gcc/config.gcc @@ -457,6 +457,7 @@ powerpc*-*-*) extra_objs="rs6000-string.o rs6000-p8swap.o" extra_headers="ppc-asm.h altivec.h htmintrin.h htmxlintrin.h" extra_headers="${extra_headers} bmi2intrin.h bmiintrin.h" + extra_headers="${extra_headers} xmmintrin.h mm_malloc.h" extra_headers="${extra_headers} mmintrin.h x86intrin.h" extra_headers="${extra_headers} ppu_intrinsics.h spu2vmx.h vec_types.h si2vmx.h" extra_headers="${extra_headers} paired.h" diff --git a/gcc/config/rs6000/x86intrin.h b/gcc/config/rs6000/x86intrin.h index 1526a7d..624e498 100644 --- a/gcc/config/rs6000/x86intrin.h +++ b/gcc/config/rs6000/x86intrin.h @@ -37,6 +37,8 @@ #ifdef __ALTIVEC__ #include + +#include #endif /* __ALTIVEC__ */ #include diff --git a/gcc/config/rs6000/xmmintrin.h b/gcc/config/rs6000/xmmintrin.h new file mode 100644 index 0000000..d7f87b5 --- /dev/null +++ b/gcc/config/rs6000/xmmintrin.h @@ -0,0 +1,1821 @@ +/* Copyright (C) 2002-2017 Free Software Foundation, Inc. + + This file is part of GCC. + + GCC is free software; you can redistribute it and/or modify + it under the terms of the GNU General Public License as published by + the Free Software Foundation; either version 3, or (at your option) + any later version. + + GCC is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + GNU General Public License for more details. + + Under Section 7 of GPL version 3, you are granted additional + permissions described in the GCC Runtime Library Exception, version + 3.1, as published by the Free Software Foundation. + + You should have received a copy of the GNU General Public License and + a copy of the GCC Runtime Library Exception along with this program; + see the files COPYING3 and COPYING.RUNTIME respectively. If not, see + . */ + +/* Implemented from the specification included in the Intel C++ Compiler + User Guide and Reference, version 9.0. */ + +#ifndef NO_WARN_X86_INTRINSICS +/* This header is distributed to simplify porting x86_64 code that + makes explicit use of Intel intrinsics to powerpc64le. + It is the user's responsibility to determine if the results are + acceptable and make additional changes as necessary. + Note that much code that uses Intel intrinsics can be rewritten in + standard C or GNU C extensions, which are more portable and better + optimized across multiple targets. + + In the specific case of X86 SSE (__m128) intrinsics, the PowerPC + VMX/VSX ISA is a good match for vector float SIMD operations. + However scalar float operations in vector (XMM) registers require + the POWER8 VSX ISA (2.07) level. Also there are important + differences for data format and placement of float scalars in the + vector register. For PowerISA Scalar floats in FPRs (left most + 64-bits of the low 32 VSRs) is in double format, while X86_64 SSE + uses the right most 32-bits of the XMM. These differences require + extra steps on POWER to match the SSE scalar float semantics. + + Most SSE scalar float intrinsic operations can be performed more + efficiently as C language float scalar operations or optimized to + use vector SIMD operations. We recommend this for new applications. + + Another difference is the format and details of the X86_64 MXSCR vs + the PowerISA FPSCR / VSCR registers. We recommend applications + replace direct access to the MXSCR with the more portable + Posix APIs. */ +#warning "Please read comment above. Use -DNO_WARN_X86_INTRINSICS to disable this warning." +#endif + +#ifndef _XMMINTRIN_H_INCLUDED +#define _XMMINTRIN_H_INCLUDED + +#include +#include + +/* We need type definitions from the MMX header file. */ +#include + +/* Get _mm_malloc () and _mm_free (). */ +#include + +/* The Intel API is flexible enough that we must allow aliasing with other + vector types, and their scalar components. */ +typedef float __m128 __attribute__ ((__vector_size__ (16), __may_alias__)); + +/* Internal data types for implementing the intrinsics. */ +typedef float __v4sf __attribute__ ((__vector_size__ (16))); + +/* Create an undefined vector. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_undefined_ps (void) +{ + __m128 __Y = __Y; + return __Y; +} + +/* Create a vector of zeros. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_setzero_ps (void) +{ + return __extension__ (__m128){ 0.0f, 0.0f, 0.0f, 0.0f }; +} + +/* Load four SPFP values from P. The address must be 16-byte aligned. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_load_ps (float const *__P) +{ + assert(((unsigned long)__P & 0xfUL) == 0UL); + return ((__m128)vec_ld(0, (__v4sf*)__P)); +} + +/* Load four SPFP values from P. The address need not be 16-byte aligned. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_loadu_ps (float const *__P) +{ + return (vec_vsx_ld(0, __P)); +} + +/* Load four SPFP values in reverse order. The address must be aligned. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_loadr_ps (float const *__P) +{ + __v4sf __tmp; + __m128 result; + static const __vector unsigned char permute_vector = + { 0x1C, 0x1D, 0x1E, 0x1F, 0x18, 0x19, 0x1A, 0x1B, 0x14, 0x15, 0x16, + 0x17, 0x10, 0x11, 0x12, 0x13 }; + + __tmp = vec_ld (0, (__v4sf *) __P); + result = (__m128) vec_perm (__tmp, __tmp, permute_vector); + return result; +} + +/* Create a vector with all four elements equal to F. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_set1_ps (float __F) +{ + return __extension__ (__m128)(__v4sf){ __F, __F, __F, __F }; +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_set_ps1 (float __F) +{ + return _mm_set1_ps (__F); +} + +/* Create the vector [Z Y X W]. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_set_ps (const float __Z, const float __Y, const float __X, const float __W) +{ + return __extension__ (__m128)(__v4sf){ __W, __X, __Y, __Z }; +} + +/* Create the vector [W X Y Z]. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_setr_ps (float __Z, float __Y, float __X, float __W) +{ + return __extension__ (__m128)(__v4sf){ __Z, __Y, __X, __W }; +} + +/* Store four SPFP values. The address must be 16-byte aligned. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_store_ps (float *__P, __m128 __A) +{ + assert(((unsigned long)__P & 0xfUL) == 0UL); + vec_st((__v4sf)__A, 0, (__v4sf*)__P); +} + +/* Store four SPFP values. The address need not be 16-byte aligned. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_storeu_ps (float *__P, __m128 __A) +{ + *(__m128 *)__P = __A; +} + +/* Store four SPFP values in reverse order. The address must be aligned. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_storer_ps (float *__P, __m128 __A) +{ + __v4sf __tmp; + static const __vector unsigned char permute_vector = + { 0x1C, 0x1D, 0x1E, 0x1F, 0x18, 0x19, 0x1A, 0x1B, 0x14, 0x15, 0x16, + 0x17, 0x10, 0x11, 0x12, 0x13 }; + + __tmp = (__m128) vec_perm (__A, __A, permute_vector); + + _mm_store_ps (__P, __tmp); +} + +/* Store the lower SPFP value across four words. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_store1_ps (float *__P, __m128 __A) +{ + __v4sf __va = vec_splat((__v4sf)__A, 0); + _mm_store_ps (__P, __va); +} + +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_store_ps1 (float *__P, __m128 __A) +{ + _mm_store1_ps (__P, __A); +} + +/* Create a vector with element 0 as F and the rest zero. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_set_ss (float __F) +{ + return __extension__ (__m128)(__v4sf){ __F, 0.0f, 0.0f, 0.0f }; +} + +/* Sets the low SPFP value of A from the low value of B. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_move_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + + return (vec_sel ((__v4sf)__A, (__v4sf)__B, mask)); +} + +/* Create a vector with element 0 as *P and the rest zero. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_load_ss (float const *__P) +{ + return _mm_set_ss (*__P); +} + +/* Stores the lower SPFP value. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_store_ss (float *__P, __m128 __A) +{ + *__P = ((__v4sf)__A)[0]; +} + +/* Perform the respective operation on the lower SPFP (single-precision + floating-point) values of A and B; the upper three SPFP values are + passed through from A. */ + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_add_ss (__m128 __A, __m128 __B) +{ +#ifdef _ARCH_PWR7 + __m128 a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + results. So to insure we don't generate spurious exceptions + (from the upper double values) we splat the lower double + before we to the operation. */ + a = vec_splat (__A, 0); + b = vec_splat (__B, 0); + c = a + b; + /* Then we merge the lower float result with the original upper + float elements from __A. */ + return (vec_sel (__A, c, mask)); +#else + __A[0] = __A[0] + __B[0]; + return (__A); +#endif +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sub_ss (__m128 __A, __m128 __B) +{ +#ifdef _ARCH_PWR7 + __m128 a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + results. So to insure we don't generate spurious exceptions + (from the upper double values) we splat the lower double + before we to the operation. */ + a = vec_splat (__A, 0); + b = vec_splat (__B, 0); + c = a - b; + /* Then we merge the lower float result with the original upper + float elements from __A. */ + return (vec_sel (__A, c, mask)); +#else + __A[0] = __A[0] - __B[0]; + return (__A); +#endif +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_mul_ss (__m128 __A, __m128 __B) +{ +#ifdef _ARCH_PWR7 + __m128 a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + results. So to insure we don't generate spurious exceptions + (from the upper double values) we splat the lower double + before we to the operation. */ + a = vec_splat (__A, 0); + b = vec_splat (__B, 0); + c = a * b; + /* Then we merge the lower float result with the original upper + float elements from __A. */ + return (vec_sel (__A, c, mask)); +#else + __A[0] = __A[0] * __B[0]; + return (__A); +#endif +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_div_ss (__m128 __A, __m128 __B) +{ +#ifdef _ARCH_PWR7 + __m128 a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + results. So to insure we don't generate spurious exceptions + (from the upper double values) we splat the lower double + before we to the operation. */ + a = vec_splat (__A, 0); + b = vec_splat (__B, 0); + c = a / b; + /* Then we merge the lower float result with the original upper + float elements from __A. */ + return (vec_sel (__A, c, mask)); +#else + __A[0] = __A[0] / __B[0]; + return (__A); +#endif +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sqrt_ss (__m128 __A) +{ + __m128 a, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + * results. So to insure we don't generate spurious exceptions + * (from the upper double values) we splat the lower double + * before we to the operation. */ + a = vec_splat (__A, 0); + c = vec_sqrt (a); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return (vec_sel (__A, c, mask)); +} + +/* Perform the respective operation on the four SPFP values in A and B. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_add_ps (__m128 __A, __m128 __B) +{ + return (__m128) ((__v4sf)__A + (__v4sf)__B); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sub_ps (__m128 __A, __m128 __B) +{ + return (__m128) ((__v4sf)__A - (__v4sf)__B); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_mul_ps (__m128 __A, __m128 __B) +{ + return (__m128) ((__v4sf)__A * (__v4sf)__B); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_div_ps (__m128 __A, __m128 __B) +{ + return (__m128) ((__v4sf)__A / (__v4sf)__B); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sqrt_ps (__m128 __A) +{ + return (vec_sqrt ((__v4sf)__A)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_rcp_ps (__m128 __A) +{ + return (vec_re ((__v4sf)__A)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_rsqrt_ps (__m128 __A) +{ + return (vec_rsqrte (__A)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_rcp_ss (__m128 __A) +{ + __m128 a, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + * results. So to insure we don't generate spurious exceptions + * (from the upper double values) we splat the lower double + * before we to the operation. */ + a = vec_splat (__A, 0); + c = _mm_rcp_ps (a); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return (vec_sel (__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_rsqrt_ss (__m128 __A) +{ + __m128 a, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower double) + * results. So to insure we don't generate spurious exceptions + * (from the upper double values) we splat the lower double + * before we to the operation. */ + a = vec_splat (__A, 0); + c = vec_rsqrte (a); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return (vec_sel (__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_min_ss (__m128 __A, __m128 __B) +{ + __v4sf a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower float) + * results. So to insure we don't generate spurious exceptions + * (from the upper float values) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf)__A, 0); + b = vec_splat ((__v4sf)__B, 0); + c = vec_min (a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return (vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_max_ss (__m128 __A, __m128 __B) +{ + __v4sf a, b, c; + static const __vector unsigned int mask = {0xffffffff, 0, 0, 0}; + /* PowerISA VSX does not allow partial (for just lower float) + * results. So to insure we don't generate spurious exceptions + * (from the upper float values) we splat the lower float + * before we to the operation. */ + a = vec_splat (__A, 0); + b = vec_splat (__B, 0); + c = vec_max (a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return (vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_min_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_min ((__v4sf)__A,(__v4sf) __B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_max_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_max ((__v4sf)__A, (__v4sf)__B)); +} + +/* Perform logical bit-wise operations on 128-bit values. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_and_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_and ((__v4sf)__A, (__v4sf)__B)); +// return __builtin_ia32_andps (__A, __B); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_andnot_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_andc ((__v4sf)__B, (__v4sf)__A)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_or_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_or ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_xor_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_xor ((__v4sf)__A, (__v4sf)__B)); +} + +/* Perform a comparison on the four SPFP values of A and B. For each + element, if the comparison is true, place a mask of all ones in the + result, otherwise a mask of zeros. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpeq_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmpeq ((__v4sf)__A,(__v4sf) __B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmplt_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmplt ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmple_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmple ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpgt_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmpgt ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpge_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmpge ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpneq_ps (__m128 __A, __m128 __B) +{ + __v4sf temp = (__v4sf ) vec_cmpeq ((__v4sf) __A, (__v4sf)__B); + return ((__m128)vec_nor (temp, temp)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnlt_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmpge ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnle_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmpgt ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpngt_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmple ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnge_ps (__m128 __A, __m128 __B) +{ + return ((__m128)vec_cmplt ((__v4sf)__A, (__v4sf)__B)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpord_ps (__m128 __A, __m128 __B) +{ + __vector unsigned int a, b; + __vector unsigned int c, d; + static const __vector unsigned int float_exp_mask = + { 0x7f800000, 0x7f800000, 0x7f800000, 0x7f800000 }; + + a = (__vector unsigned int) vec_abs ((__v4sf)__A); + b = (__vector unsigned int) vec_abs ((__v4sf)__B); + c = (__vector unsigned int) vec_cmpgt (float_exp_mask, a); + d = (__vector unsigned int) vec_cmpgt (float_exp_mask, b); + return ((__m128 ) vec_and (c, d)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpunord_ps (__m128 __A, __m128 __B) +{ + __vector unsigned int a, b; + __vector unsigned int c, d; + static const __vector unsigned int float_exp_mask = + { 0x7f800000, 0x7f800000, 0x7f800000, 0x7f800000 }; + + a = (__vector unsigned int) vec_abs ((__v4sf)__A); + b = (__vector unsigned int) vec_abs ((__v4sf)__B); + c = (__vector unsigned int) vec_cmpgt (a, float_exp_mask); + d = (__vector unsigned int) vec_cmpgt (b, float_exp_mask); + return ((__m128 ) vec_or (c, d)); +} + +/* Perform a comparison on the lower SPFP values of A and B. If the + comparison is true, place a mask of all ones in the result, otherwise a + mask of zeros. The upper three SPFP values are passed through from A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpeq_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpeq(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmplt_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmplt(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmple_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmple(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpgt_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpgt(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpge_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpge(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpneq_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpeq(a, b); + c = vec_nor (c, c); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnlt_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpge(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnle_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmpgt(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpngt_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we to the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmple(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpnge_ss (__m128 __A, __m128 __B) +{ + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + __v4sf a, b, c; + /* PowerISA VMX does not allow partial (for just element 0) + * results. So to insure we don't generate spurious exceptions + * (from the upper elements) we splat the lower float + * before we do the operation. */ + a = vec_splat ((__v4sf) __A, 0); + b = vec_splat ((__v4sf) __B, 0); + c = (__v4sf) vec_cmplt(a, b); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpord_ss (__m128 __A, __m128 __B) +{ + __vector unsigned int a, b; + __vector unsigned int c, d; + static const __vector unsigned int float_exp_mask = + { 0x7f800000, 0x7f800000, 0x7f800000, 0x7f800000 }; + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + + a = (__vector unsigned int) vec_abs ((__v4sf)__A); + b = (__vector unsigned int) vec_abs ((__v4sf)__B); + c = (__vector unsigned int) vec_cmpgt (float_exp_mask, a); + d = (__vector unsigned int) vec_cmpgt (float_exp_mask, b); + c = vec_and (c, d); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, (__v4sf)c, mask)); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cmpunord_ss (__m128 __A, __m128 __B) +{ + __vector unsigned int a, b; + __vector unsigned int c, d; + static const __vector unsigned int float_exp_mask = + { 0x7f800000, 0x7f800000, 0x7f800000, 0x7f800000 }; + static const __vector unsigned int mask = + { 0xffffffff, 0, 0, 0 }; + + a = (__vector unsigned int) vec_abs ((__v4sf)__A); + b = (__vector unsigned int) vec_abs ((__v4sf)__B); + c = (__vector unsigned int) vec_cmpgt (a, float_exp_mask); + d = (__vector unsigned int) vec_cmpgt (b, float_exp_mask); + c = vec_or (c, d); + /* Then we merge the lower float result with the original upper + * float elements from __A. */ + return ((__m128)vec_sel ((__v4sf)__A, (__v4sf)c, mask)); +} + +/* Compare the lower SPFP values of A and B and return 1 if true + and 0 if false. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comieq_ss (__m128 __A, __m128 __B) +{ + return (__A[0] == __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comilt_ss (__m128 __A, __m128 __B) +{ + return (__A[0] < __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comile_ss (__m128 __A, __m128 __B) +{ + return (__A[0] <= __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comigt_ss (__m128 __A, __m128 __B) +{ + return (__A[0] > __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comige_ss (__m128 __A, __m128 __B) +{ + return (__A[0] >= __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_comineq_ss (__m128 __A, __m128 __B) +{ + return (__A[0] != __B[0]); +} + +/* FIXME + * The __mm_ucomi??_ss implementations below are exactly the same as + * __mm_comi??_ss because GCC for PowerPC only generates unordered + * compares (scalar and vector). + * Technically __mm_comieq_ss et al should be using the ordered + * compare and signal for QNaNs. + * The __mm_ucomieq_sd et all should be OK, as is. + */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomieq_ss (__m128 __A, __m128 __B) +{ + return (__A[0] == __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomilt_ss (__m128 __A, __m128 __B) +{ + return (__A[0] < __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomile_ss (__m128 __A, __m128 __B) +{ + return (__A[0] <= __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomigt_ss (__m128 __A, __m128 __B) +{ + return (__A[0] > __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomige_ss (__m128 __A, __m128 __B) +{ + return (__A[0] >= __B[0]); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_ucomineq_ss (__m128 __A, __m128 __B) +{ + return (__A[0] != __B[0]); +} + +extern __inline float __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtss_f32 (__m128 __A) +{ + return ((__v4sf)__A)[0]; +} + +/* Convert the lower SPFP value to a 32-bit integer according to the current + rounding mode. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtss_si32 (__m128 __A) +{ + __m64 res = 0; +#ifdef _ARCH_PWR8 + __m128 vtmp; + __asm__( + "xxsldwi %x1,%x2,%x2,3;\n" + "xscvspdp %x1,%x1;\n" + "fctiw %1,%1;\n" + "mfvsrd %0,%x1;\n" + : "=r" (res), + "=&wi" (vtmp) + : "wa" (__A) + : ); +#else + res = __builtin_rint(__A[0]); +#endif + return (res); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvt_ss2si (__m128 __A) +{ + return _mm_cvtss_si32 (__A); +} + +/* Convert the lower SPFP value to a 32-bit integer according to the + current rounding mode. */ + +/* Intel intrinsic. */ +extern __inline long long __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtss_si64 (__m128 __A) +{ + __m64 res = 0; +#ifdef _ARCH_PWR8 + __m128 vtmp; + __asm__( + "xxsldwi %x1,%x2,%x2,3;\n" + "xscvspdp %x1,%x1;\n" + "fctid %1,%1;\n" + "mfvsrd %0,%x1;\n" + : "=r" (res), + "=&wi" (vtmp) + : "wa" (__A) + : ); +#else + res = __builtin_llrint(__A[0]); +#endif + return (res); +} + +/* Microsoft intrinsic. */ +extern __inline long long __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtss_si64x (__m128 __A) +{ + return _mm_cvtss_si64 ((__v4sf) __A); +} + +/* Constants for use with _mm_prefetch. */ +enum _mm_hint +{ + /* _MM_HINT_ET is _MM_HINT_T with set 3rd bit. */ + _MM_HINT_ET0 = 7, + _MM_HINT_ET1 = 6, + _MM_HINT_T0 = 3, + _MM_HINT_T1 = 2, + _MM_HINT_T2 = 1, + _MM_HINT_NTA = 0 +}; + +/* Loads one cache line from address P to a location "closer" to the + processor. The selector I specifies the type of prefetch operation. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_prefetch (const void *__P, enum _mm_hint __I) +{ + /* Current PowerPC will ignores the hint parameters. */ + __builtin_prefetch (__P); +} + +/* Convert the two lower SPFP values to 32-bit integers according to the + current rounding mode. Return the integers in packed form. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtps_pi32 (__m128 __A) +{ + /* Splat two lower SPFP values to both halves. */ + __v4sf temp, rounded; + __vector __m64 result; + + /* Splat two lower SPFP values to both halves. */ + temp = (__v4sf) vec_splat ((__vector long long)__A, 0); + rounded = vec_rint(temp); + result = (__vector __m64) vec_cts (rounded, 0); + + return ((__m64) __builtin_unpack_vector_int128 ((__vector __int128)result, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvt_ps2pi (__m128 __A) +{ + return _mm_cvtps_pi32 (__A); +} + +/* Truncate the lower SPFP value to a 32-bit integer. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvttss_si32 (__m128 __A) +{ + /* Extract the lower float element. */ + float temp = __A[0]; + /* truncate to 32-bit integer and return. */ + return temp; +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtt_ss2si (__m128 __A) +{ + return _mm_cvttss_si32 (__A); +} + +/* Intel intrinsic. */ +extern __inline long long __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvttss_si64 (__m128 __A) +{ + /* Extract the lower float element. */ + float temp = __A[0]; + /* truncate to 32-bit integer and return. */ + return temp; +} + +/* Microsoft intrinsic. */ +extern __inline long long __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvttss_si64x (__m128 __A) +{ + /* Extract the lower float element. */ + float temp = __A[0]; + /* truncate to 32-bit integer and return. */ + return temp; +} + +/* Truncate the two lower SPFP values to 32-bit integers. Return the + integers in packed form. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvttps_pi32 (__m128 __A) +{ + __v4sf temp; + __vector __m64 result; + + /* Splat two lower SPFP values to both halves. */ + temp = (__v4sf) vec_splat ((__vector long long)__A, 0); + result = (__vector __m64) vec_cts (temp, 0); + + return ((__m64) __builtin_unpack_vector_int128 ((__vector __int128)result, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtt_ps2pi (__m128 __A) +{ + return _mm_cvttps_pi32 (__A); +} + +/* Convert B to a SPFP value and insert it as element zero in A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtsi32_ss (__m128 __A, int __B) +{ + float temp = __B; + __A[0] = temp; + + return __A; +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvt_si2ss (__m128 __A, int __B) +{ + return _mm_cvtsi32_ss (__A, __B); +} + +/* Convert B to a SPFP value and insert it as element zero in A. */ +/* Intel intrinsic. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtsi64_ss (__m128 __A, long long __B) +{ + float temp = __B; + __A[0] = temp; + + return __A; +} + +/* Microsoft intrinsic. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtsi64x_ss (__m128 __A, long long __B) +{ + return _mm_cvtsi64_ss (__A, __B); +} + +/* Convert the two 32-bit values in B to SPFP form and insert them + as the two lower elements in A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtpi32_ps (__m128 __A, __m64 __B) +{ + __vector signed int vm1; + __vector float vf1; + + vm1 = (__vector signed int) __builtin_pack_vector_int128 (__B, __B); + vf1 = (__vector float) vec_ctf (vm1, 0); + + return ((__m128) (__vector __m64) + { ((__vector __m64)vf1) [0], ((__vector __m64)__A) [1]}); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvt_pi2ps (__m128 __A, __m64 __B) +{ + return _mm_cvtpi32_ps (__A, __B); +} + +/* Convert the four signed 16-bit values in A to SPFP form. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtpi16_ps (__m64 __A) +{ + __vector signed short vs8; + __vector signed int vi4; + __vector float vf1; + + vs8 = (__vector signed short) __builtin_pack_vector_int128 (__A, __A); + vi4 = vec_vupklsh (vs8); + vf1 = (__vector float) vec_ctf (vi4, 0); + + return (__m128) vf1; +} + +/* Convert the four unsigned 16-bit values in A to SPFP form. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtpu16_ps (__m64 __A) +{ + const __vector unsigned short zero = + { 0, 0, 0, 0, 0, 0, 0, 0 }; + __vector unsigned short vs8; + __vector unsigned int vi4; + __vector float vf1; + + vs8 = (__vector unsigned short) __builtin_pack_vector_int128 (__A, __A); + vi4 = (__vector unsigned int) vec_vmrglh (vs8, zero); + vf1 = (__vector float) vec_ctf (vi4, 0); + + return (__m128) vf1; +} + +/* Convert the low four signed 8-bit values in A to SPFP form. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtpi8_ps (__m64 __A) +{ + __vector signed char vc16; + __vector signed short vs8; + __vector signed int vi4; + __vector float vf1; + + vc16 = (__vector signed char) __builtin_pack_vector_int128 (__A, __A); + vs8 = vec_vupkhsb (vc16); + vi4 = vec_vupkhsh (vs8); + vf1 = (__vector float) vec_ctf (vi4, 0); + + return (__m128) vf1; +} + +/* Convert the low four unsigned 8-bit values in A to SPFP form. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) + +_mm_cvtpu8_ps (__m64 __A) +{ + const __vector unsigned char zero = + { 0, 0, 0, 0, 0, 0, 0, 0 }; + __vector unsigned char vc16; + __vector unsigned short vs8; + __vector unsigned int vi4; + __vector float vf1; + + vc16 = (__vector unsigned char) __builtin_pack_vector_int128 (__A, __A); + vs8 = (__vector unsigned short) vec_vmrglb (vc16, zero); + vi4 = (__vector unsigned int) vec_vmrghh (vs8, + (__vector unsigned short) zero); + vf1 = (__vector float) vec_ctf (vi4, 0); + + return (__m128) vf1; +} + +/* Convert the four signed 32-bit values in A and B to SPFP form. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtpi32x2_ps(__m64 __A, __m64 __B) +{ + __vector signed int vi4; + __vector float vf4; + + vi4 = (__vector signed int) __builtin_pack_vector_int128 (__B, __A); + vf4 = (__vector float) vec_ctf (vi4, 0); + return (__m128) vf4; +} + +/* Convert the four SPFP values in A to four signed 16-bit integers. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtps_pi16(__m128 __A) +{ + __v4sf rounded; + __vector signed int temp; + __vector __m64 result; + + rounded = vec_rint(__A); + temp = vec_cts (rounded, 0); + result = (__vector __m64) vec_pack (temp, temp); + + return ((__m64) __builtin_unpack_vector_int128 ((__vector __int128)result, 0)); +} + +/* Convert the four SPFP values in A to four signed 8-bit integers. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_cvtps_pi8(__m128 __A) +{ + __v4sf rounded; + __vector signed int tmp_i; + static const __vector signed int zero = {0, 0, 0, 0}; + __vector signed short tmp_s; + __vector signed char res_v; + __m64 result; + + rounded = vec_rint(__A); + tmp_i = vec_cts (rounded, 0); + tmp_s = vec_pack (tmp_i, zero); + res_v = vec_pack (tmp_s, tmp_s); + result = (__m64) __builtin_unpack_vector_int128 ((__vector __int128)res_v, 0); + + return (result); +} + +/* Selects four specific SPFP values from A and B based on MASK. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) + +_mm_shuffle_ps (__m128 __A, __m128 __B, int const __mask) +{ + unsigned long element_selector_10 = __mask & 0x03; + unsigned long element_selector_32 = (__mask >> 2) & 0x03; + unsigned long element_selector_54 = (__mask >> 4) & 0x03; + unsigned long element_selector_76 = (__mask >> 6) & 0x03; + static const unsigned int permute_selectors[4] = + { +#ifdef __LITTLE_ENDIAN__ + 0x03020100, 0x07060504, 0x0B0A0908, 0x0F0E0D0C +#elif __BIG_ENDIAN__ + 0x0C0D0E0F, 0x08090A0B, 0x04050607, 0x00010203 +#endif + }; + __vector unsigned int t; + +#ifdef __LITTLE_ENDIAN__ + t[0] = permute_selectors[element_selector_10]; + t[1] = permute_selectors[element_selector_32]; + t[2] = permute_selectors[element_selector_54] + 0x10101010; + t[3] = permute_selectors[element_selector_76] + 0x10101010; +#elif __BIG_ENDIAN__ + t[3] = permute_selectors[element_selector_10] + 0x10101010; + t[2] = permute_selectors[element_selector_32] + 0x10101010; + t[1] = permute_selectors[element_selector_54]; + t[0] = permute_selectors[element_selector_76]; +#endif + return vec_perm ((__v4sf) __A, (__v4sf)__B, (__vector unsigned char)t); +} + +/* Selects and interleaves the upper two SPFP values from A and B. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_unpackhi_ps (__m128 __A, __m128 __B) +{ + return (__m128) vec_vmrglw ((__v4sf) __A, (__v4sf)__B); +} + +/* Selects and interleaves the lower two SPFP values from A and B. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_unpacklo_ps (__m128 __A, __m128 __B) +{ + return (__m128) vec_vmrghw ((__v4sf) __A, (__v4sf)__B); +} + +/* Sets the upper two SPFP values with 64-bits of data loaded from P; + the lower two values are passed through from A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_loadh_pi (__m128 __A, __m64 const *__P) +{ + __vector __m64 __a = (__vector __m64)__A; + __vector __m64 __p = vec_splats(*__P); + __a [1] = __p [1]; + + return (__m128)__a; +} + +/* Stores the upper two SPFP values of A into P. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_storeh_pi (__m64 *__P, __m128 __A) +{ + __vector __m64 __a = (__vector __m64) __A; + + *__P = __a[1]; +} + +/* Moves the upper two values of B into the lower two values of A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_movehl_ps (__m128 __A, __m128 __B) +{ + return (__m128) vec_mergel ((__vector __m64)__B, (__vector __m64)__A); +} + +/* Moves the lower two values of B into the upper two values of A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_movelh_ps (__m128 __A, __m128 __B) +{ + return (__m128) vec_mergeh ((__vector __m64)__A, (__vector __m64)__B); +} + +/* Sets the lower two SPFP values with 64-bits of data loaded from P; + the upper two values are passed through from A. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_loadl_pi (__m128 __A, __m64 const *__P) +{ + __vector __m64 __a = (__vector __m64)__A; + __vector __m64 __p = vec_splats(*__P); + __a [0] = __p [0]; + + return (__m128)__a; +} + +/* Stores the lower two SPFP values of A into P. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_storel_pi (__m64 *__P, __m128 __A) +{ + __vector __m64 __a = (__vector __m64) __A; + + *__P = __a[0]; +} + +#ifdef _ARCH_PWR8 +/* Intrinsic functions that require PowerISA 2.07 minimum. */ + +/* Creates a 4-bit mask from the most significant bits of the SPFP values. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_movemask_ps (__m128 __A) +{ + __vector __m64 result; + static const __vector unsigned int perm_mask = + { +#ifdef __LITTLE_ENDIAN__ + 0x00204060, 0x80808080, 0x80808080, 0x80808080 +#elif __BIG_ENDIAN__ + 0x80808080, 0x80808080, 0x80808080, 0x00204060 +#endif + }; + + result = (__vector __m64) vec_vbpermq ((__vector unsigned char) __A, + (__vector unsigned char) perm_mask); + +#ifdef __LITTLE_ENDIAN__ + return result[1]; +#elif __BIG_ENDIAN__ + return result[0]; +#endif +} +#endif /* _ARCH_PWR8 */ + +/* Create a vector with all four elements equal to *P. */ +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_load1_ps (float const *__P) +{ + return _mm_set1_ps (*__P); +} + +extern __inline __m128 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_load_ps1 (float const *__P) +{ + return _mm_load1_ps (__P); +} + +/* Extracts one of the four words of A. The selector N must be immediate. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_extract_pi16 (__m64 const __A, int const __N) +{ + const int shiftr = (__N & 3) * 16; + + return ((__A >> shiftr) & 0xffff); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pextrw (__m64 const __A, int const __N) +{ + return _mm_extract_pi16 (__A, __N); +} + +/* Inserts word D into one of four words of A. The selector N must be + immediate. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_insert_pi16 (__m64 const __A, int const __D, int const __N) +{ + const int shiftl = (__N & 3) * 16; + const __m64 shiftD = (const __m64) __D << shiftl; + const __m64 mask = 0xffffUL << shiftl; + __m64 result = (__A & (~mask)) | (shiftD & mask); + + return (result); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pinsrw (__m64 const __A, int const __D, int const __N) +{ + return _mm_insert_pi16 (__A, __D, __N); +} + +/* Compute the element-wise maximum of signed 16-bit values. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) + +_mm_max_pi16 (__m64 __A, __m64 __B) +{ +#if _ARCH_PWR8 + __vector signed short a, b, r; + __vector bool short c; + + a = (__vector signed short)vec_splats (__A); + b = (__vector signed short)vec_splats (__B); + c = (__vector bool short)vec_cmpgt (a, b); + r = vec_sel (b, a, c); + return (__builtin_unpack_vector_int128 ((__vector __int128_t)r, 0)); +#else + __m64_union m1, m2, res; + + m1.as_m64 = __A; + m2.as_m64 = __B; + + res.as_short[0] = + (m1.as_short[0] > m2.as_short[0]) ? m1.as_short[0] : m2.as_short[0]; + res.as_short[1] = + (m1.as_short[1] > m2.as_short[1]) ? m1.as_short[1] : m2.as_short[1]; + res.as_short[2] = + (m1.as_short[2] > m2.as_short[2]) ? m1.as_short[2] : m2.as_short[2]; + res.as_short[3] = + (m1.as_short[3] > m2.as_short[3]) ? m1.as_short[3] : m2.as_short[3]; + + return (__m64) res.as_m64; +#endif +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pmaxsw (__m64 __A, __m64 __B) +{ + return _mm_max_pi16 (__A, __B); +} + +/* Compute the element-wise maximum of unsigned 8-bit values. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_max_pu8 (__m64 __A, __m64 __B) +{ +#if _ARCH_PWR8 + __vector unsigned char a, b, r; + __vector bool char c; + + a = (__vector unsigned char)vec_splats (__A); + b = (__vector unsigned char)vec_splats (__B); + c = (__vector bool char)vec_cmpgt (a, b); + r = vec_sel (b, a, c); + return (__builtin_unpack_vector_int128 ((__vector __int128_t)r, 0)); +#else + __m64_union m1, m2, res; + long i; + + m1.as_m64 = __A; + m2.as_m64 = __B; + + + for (i = 0; i < 8; i++) + res.as_char[i] = + ((unsigned char) m1.as_char[i] > (unsigned char) m2.as_char[i]) ? + m1.as_char[i] : m2.as_char[i]; + + return (__m64) res.as_m64; +#endif +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pmaxub (__m64 __A, __m64 __B) +{ + return _mm_max_pu8 (__A, __B); +} + +/* Compute the element-wise minimum of signed 16-bit values. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_min_pi16 (__m64 __A, __m64 __B) +{ +#if _ARCH_PWR8 + __vector signed short a, b, r; + __vector bool short c; + + a = (__vector signed short)vec_splats (__A); + b = (__vector signed short)vec_splats (__B); + c = (__vector bool short)vec_cmplt (a, b); + r = vec_sel (b, a, c); + return (__builtin_unpack_vector_int128 ((__vector __int128_t)r, 0)); +#else + __m64_union m1, m2, res; + + m1.as_m64 = __A; + m2.as_m64 = __B; + + res.as_short[0] = + (m1.as_short[0] < m2.as_short[0]) ? m1.as_short[0] : m2.as_short[0]; + res.as_short[1] = + (m1.as_short[1] < m2.as_short[1]) ? m1.as_short[1] : m2.as_short[1]; + res.as_short[2] = + (m1.as_short[2] < m2.as_short[2]) ? m1.as_short[2] : m2.as_short[2]; + res.as_short[3] = + (m1.as_short[3] < m2.as_short[3]) ? m1.as_short[3] : m2.as_short[3]; + + return (__m64) res.as_m64; +#endif +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pminsw (__m64 __A, __m64 __B) +{ + return _mm_min_pi16 (__A, __B); +} + +/* Compute the element-wise minimum of unsigned 8-bit values. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_min_pu8 (__m64 __A, __m64 __B) +{ +#if _ARCH_PWR8 + __vector unsigned char a, b, r; + __vector bool char c; + + a = (__vector unsigned char)vec_splats (__A); + b = (__vector unsigned char)vec_splats (__B); + c = (__vector bool char)vec_cmplt (a, b); + r = vec_sel (b, a, c); + return (__builtin_unpack_vector_int128 ((__vector __int128_t)r, 0)); +#else + __m64_union m1, m2, res; + long i; + + m1.as_m64 = __A; + m2.as_m64 = __B; + + + for (i = 0; i < 8; i++) + res.as_char[i] = + ((unsigned char) m1.as_char[i] < (unsigned char) m2.as_char[i]) ? + m1.as_char[i] : m2.as_char[i]; + + return (__m64) res.as_m64; +#endif +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pminub (__m64 __A, __m64 __B) +{ + return _mm_min_pu8 (__A, __B); +} + +/* Create an 8-bit mask of the signs of 8-bit values. */ +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_movemask_pi8 (__m64 __A) +{ + unsigned long p = 0x0008101820283038UL; // permute control for sign bits + + return __builtin_bpermd (p, __A); +} + +extern __inline int __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pmovmskb (__m64 __A) +{ + return _mm_movemask_pi8 (__A); +} + +/* Multiply four unsigned 16-bit values in A by four unsigned 16-bit values + in B and produce the high 16 bits of the 32-bit results. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_mulhi_pu16 (__m64 __A, __m64 __B) +{ + __vector unsigned short a, b; + __vector unsigned short c; + __vector unsigned int w0, w1; + __vector unsigned char xform1 = { + 0x02, 0x03, 0x12, 0x13, 0x06, 0x07, 0x16, 0x17, + 0x0A, 0x0B, 0x1A, 0x1B, 0x0E, 0x0F, 0x1E, 0x1F + }; + + a = (__vector unsigned short)vec_splats (__A); + b = (__vector unsigned short)vec_splats (__B); + + w0 = vec_vmuleuh (a, b); + w1 = vec_vmulouh (a, b); + c = (__vector unsigned short)vec_perm (w0, w1, xform1); + + return (__builtin_unpack_vector_int128 ((__vector __int128)c, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pmulhuw (__m64 __A, __m64 __B) +{ + return _mm_mulhi_pu16 (__A, __B); +} + +/* Return a combination of the four 16-bit values in A. The selector + must be an immediate. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_shuffle_pi16 (__m64 __A, int const __N) +{ + unsigned long element_selector_10 = __N & 0x03; + unsigned long element_selector_32 = (__N >> 2) & 0x03; + unsigned long element_selector_54 = (__N >> 4) & 0x03; + unsigned long element_selector_76 = (__N >> 6) & 0x03; + static const unsigned short permute_selectors[4] = + { +#ifdef __LITTLE_ENDIAN__ + 0x0908, 0x0B0A, 0x0D0C, 0x0F0E +#elif __BIG_ENDIAN__ + 0x0607, 0x0405, 0x0203, 0x0001 +#endif + }; + __m64_union t; + __vector __m64 a, p, r; + +#ifdef __LITTLE_ENDIAN__ + t.as_short[0] = permute_selectors[element_selector_10]; + t.as_short[1] = permute_selectors[element_selector_32]; + t.as_short[2] = permute_selectors[element_selector_54]; + t.as_short[3] = permute_selectors[element_selector_76]; +#elif __BIG_ENDIAN__ + t.as_short[3] = permute_selectors[element_selector_10]; + t.as_short[2] = permute_selectors[element_selector_32]; + t.as_short[1] = permute_selectors[element_selector_54]; + t.as_short[0] = permute_selectors[element_selector_76]; +#endif + p = vec_splats (t.as_m64); + a = vec_splats (__A); + r = vec_perm (a, a, (__vector unsigned char)p); + return (__builtin_unpack_vector_int128 ((__vector __int128)r, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pshufw (__m64 __A, int const __N) +{ + return _mm_shuffle_pi16 (__A, __N); +} + +/* Conditionally store byte elements of A into P. The high bit of each + byte in the selector N determines whether the corresponding byte from + A is stored. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_maskmove_si64 (__m64 __A, __m64 __N, char *__P) +{ + __m64 hibit = 0x8080808080808080UL; + __m64 mask, tmp; + __m64 *p = (__m64*)__P; + + tmp = *p; + mask = _mm_cmpeq_pi8 ((__N & hibit), hibit); + tmp = (tmp & (~mask)) | (__A & mask); + *p = tmp; +} + +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_maskmovq (__m64 __A, __m64 __N, char *__P) +{ + _mm_maskmove_si64 (__A, __N, __P); +} + +/* Compute the rounded averages of the unsigned 8-bit values in A and B. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_avg_pu8 (__m64 __A, __m64 __B) +{ + __vector unsigned char a, b, c; + + a = (__vector unsigned char)vec_splats (__A); + b = (__vector unsigned char)vec_splats (__B); + c = vec_avg (a, b); + return (__builtin_unpack_vector_int128 ((__vector __int128)c, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pavgb (__m64 __A, __m64 __B) +{ + return _mm_avg_pu8 (__A, __B); +} + +/* Compute the rounded averages of the unsigned 16-bit values in A and B. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_avg_pu16 (__m64 __A, __m64 __B) +{ + __vector unsigned short a, b, c; + + a = (__vector unsigned short)vec_splats (__A); + b = (__vector unsigned short)vec_splats (__B); + c = vec_avg (a, b); + return (__builtin_unpack_vector_int128 ((__vector __int128)c, 0)); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_pavgw (__m64 __A, __m64 __B) +{ + return _mm_avg_pu16 (__A, __B); +} + +/* Compute the sum of the absolute differences of the unsigned 8-bit + values in A and B. Return the value in the lower 16-bit word; the + upper words are cleared. */ +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sad_pu8 (__m64 __A, __m64 __B) +{ + __vector unsigned char a, b; + __vector unsigned char vmin, vmax, vabsdiff; + __vector signed int vsum; + const __vector unsigned int zero = + { 0, 0, 0, 0 }; + unsigned short result; + + a = (__vector unsigned char) __builtin_pack_vector_int128 (0UL, __A); + b = (__vector unsigned char) __builtin_pack_vector_int128 (0UL, __B); + vmin = vec_min (a, b); + vmax = vec_max (a, b); + vabsdiff = vec_sub (vmax, vmin); + /* Sum four groups of bytes into integers. */ + vsum = (__vector signed int) vec_sum4s (vabsdiff, zero); + /* Sum across four integers with integer result. */ + vsum = vec_sums (vsum, (__vector signed int) zero); + /* The sum is in the right most 32-bits of the vector result. + Transfer to a GPR and truncate to 16 bits. */ + result = vsum[3]; + return (result); +} + +extern __inline __m64 __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_m_psadbw (__m64 __A, __m64 __B) +{ + return _mm_sad_pu8 (__A, __B); +} + +/* Stores the data in A to the address P without polluting the caches. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_stream_pi (__m64 *__P, __m64 __A) +{ + /* Use the data cache block touch for store transient. */ + __asm__ ( + " dcbtstt 0,%0" + : + : "b" (__P) + : "memory" + ); + *__P = __A; +} + +/* Likewise. The address must be 16-byte aligned. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_stream_ps (float *__P, __m128 __A) +{ + /* Use the data cache block touch for store transient. */ + __asm__ ( + " dcbtstt 0,%0" + : + : "b" (__P) + : "memory" + ); + _mm_store_ps (__P, __A); +} + +/* Guarantees that every preceding store is globally visible before + any subsequent store. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_sfence (void) +{ + /* Generate a light weight sync. */ + __atomic_thread_fence (__ATOMIC_RELEASE); +} + +/* The execution of the next instruction is delayed by an implementation + specific amount of time. The instruction does not modify the + architectural state. This is after the pop_options pragma because + it does not require SSE support in the processor--the encoding is a + nop on processors that do not support it. */ +extern __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__)) +_mm_pause (void) +{ + /* There is no exact match with this construct, but the following is + close to the desired effect. */ +#if _ARCH_PWR8 + /* On power8 and later processors we can depend on Program Priority + (PRI) and associated "very low" PPI setting. Since we don't know + what PPI this thread is running at we: 1) save the current PRI + from the PPR SPR into a local GRP, 2) set the PRI to "very low* + via the special or 31,31,31 encoding. 3) issue an "isync" to + insure the PRI change takes effect before we execute any more + instructions. + Now we can execute a lwsync (release barrier) while we execute + this thread at "very low" PRI. Finally we restore the original + PRI and continue execution. */ + unsigned long __PPR; + + __asm__ volatile ( + " mfppr %0;" + " or 31,31,31;" + " isync;" + " lwsync;" + " isync;" + " mtppr %0;" + : "=r" (__PPR) + : + : "memory" + ); +#else + /* For older processor where we may not even have Program Priority + controls we can only depend on Heavy Weight Sync. */ + __atomic_thread_fence (__ATOMIC_SEQ_CST); +#endif +} + +/* Transpose the 4x4 matrix composed of row[0-3]. */ +#define _MM_TRANSPOSE4_PS(row0, row1, row2, row3) \ +do { \ + __v4sf __r0 = (row0), __r1 = (row1), __r2 = (row2), __r3 = (row3); \ + __v4sf __t0 = vec_vmrghw (__r0, __r1); \ + __v4sf __t1 = vec_vmrghw (__r2, __r3); \ + __v4sf __t2 = vec_vmrglw (__r0, __r1); \ + __v4sf __t3 = vec_vmrglw (__r2, __r3); \ + (row0) = (__v4sf)vec_mergeh ((__vector long long)__t0, \ + (__vector long long)__t1); \ + (row1) = (__v4sf)vec_mergel ((__vector long long)__t0, \ + (__vector long long)__t1); \ + (row2) = (__v4sf)vec_mergeh ((__vector long long)__t2, \ + (__vector long long)__t3); \ + (row3) = (__v4sf)vec_mergel ((__vector long long)__t2, \ + (__vector long long)__t3); \ +} while (0) + +/* For backward source compatibility. */ +//# include + +#endif /* _XMMINTRIN_H_INCLUDED */ -- 2.7.4