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libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
// -*- C++ -*-
//===---------------------------- cmath -----------------------------------===//
//
Update more file headers across all of the LLVM projects in the monorepo to reflect the new license. These used slightly different spellings that defeated my regular expressions. We understand that people may be surprised that we're moving the header entirely to discuss the new license. We checked this carefully with the Foundation's lawyer and we believe this is the correct approach. Essentially, all code in the project is now made available by the LLVM project under our new license, so you will see that the license headers include that license only. Some of our contributors have contributed code under our old license, and accordingly, we have retained a copy of our old license notice in the top-level files in each project and repository. llvm-svn: 351648
2019-01-19 18:56:40 +08:00
// 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
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
//
//===----------------------------------------------------------------------===//
#ifndef _LIBCPP_CMATH
#define _LIBCPP_CMATH
/*
cmath synopsis
Macros:
HUGE_VAL
HUGE_VALF // C99
HUGE_VALL // C99
INFINITY // C99
NAN // C99
FP_INFINITE // C99
FP_NAN // C99
FP_NORMAL // C99
FP_SUBNORMAL // C99
FP_ZERO // C99
FP_FAST_FMA // C99
FP_FAST_FMAF // C99
FP_FAST_FMAL // C99
FP_ILOGB0 // C99
FP_ILOGBNAN // C99
MATH_ERRNO // C99
MATH_ERREXCEPT // C99
math_errhandling // C99
namespace std
{
Types:
float_t // C99
double_t // C99
// C90
floating_point abs(floating_point x);
floating_point acos (arithmetic x);
float acosf(float x);
long double acosl(long double x);
floating_point asin (arithmetic x);
float asinf(float x);
long double asinl(long double x);
floating_point atan (arithmetic x);
float atanf(float x);
long double atanl(long double x);
floating_point atan2 (arithmetic y, arithmetic x);
float atan2f(float y, float x);
long double atan2l(long double y, long double x);
floating_point ceil (arithmetic x);
float ceilf(float x);
long double ceill(long double x);
floating_point cos (arithmetic x);
float cosf(float x);
long double cosl(long double x);
floating_point cosh (arithmetic x);
float coshf(float x);
long double coshl(long double x);
floating_point exp (arithmetic x);
float expf(float x);
long double expl(long double x);
floating_point fabs (arithmetic x);
float fabsf(float x);
long double fabsl(long double x);
floating_point floor (arithmetic x);
float floorf(float x);
long double floorl(long double x);
floating_point fmod (arithmetic x, arithmetic y);
float fmodf(float x, float y);
long double fmodl(long double x, long double y);
floating_point frexp (arithmetic value, int* exp);
float frexpf(float value, int* exp);
long double frexpl(long double value, int* exp);
floating_point ldexp (arithmetic value, int exp);
float ldexpf(float value, int exp);
long double ldexpl(long double value, int exp);
floating_point log (arithmetic x);
float logf(float x);
long double logl(long double x);
floating_point log10 (arithmetic x);
float log10f(float x);
long double log10l(long double x);
floating_point modf (floating_point value, floating_point* iptr);
float modff(float value, float* iptr);
long double modfl(long double value, long double* iptr);
floating_point pow (arithmetic x, arithmetic y);
float powf(float x, float y);
long double powl(long double x, long double y);
floating_point sin (arithmetic x);
float sinf(float x);
long double sinl(long double x);
floating_point sinh (arithmetic x);
float sinhf(float x);
long double sinhl(long double x);
floating_point sqrt (arithmetic x);
float sqrtf(float x);
long double sqrtl(long double x);
floating_point tan (arithmetic x);
float tanf(float x);
long double tanl(long double x);
floating_point tanh (arithmetic x);
float tanhf(float x);
long double tanhl(long double x);
// C99
Make <cmath> classification macros work with integral types. llvm-svn: 172461
2013-01-15 04:56:22 +08:00
bool signbit(arithmetic x);
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
Make <cmath> classification macros work with integral types. llvm-svn: 172461
2013-01-15 04:56:22 +08:00
int fpclassify(arithmetic x);
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
Make <cmath> classification macros work with integral types. llvm-svn: 172461
2013-01-15 04:56:22 +08:00
bool isfinite(arithmetic x);
bool isinf(arithmetic x);
bool isnan(arithmetic x);
bool isnormal(arithmetic x);
Fixing whitespace problems llvm-svn: 111750
2010-08-22 08:02:43 +08:00
Make <cmath> classification macros work with integral types. llvm-svn: 172461
2013-01-15 04:56:22 +08:00
bool isgreater(arithmetic x, arithmetic y);
bool isgreaterequal(arithmetic x, arithmetic y);
bool isless(arithmetic x, arithmetic y);
bool islessequal(arithmetic x, arithmetic y);
bool islessgreater(arithmetic x, arithmetic y);
bool isunordered(arithmetic x, arithmetic y);
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
floating_point acosh (arithmetic x);
float acoshf(float x);
long double acoshl(long double x);
floating_point asinh (arithmetic x);
float asinhf(float x);
long double asinhl(long double x);
floating_point atanh (arithmetic x);
float atanhf(float x);
long double atanhl(long double x);
floating_point cbrt (arithmetic x);
float cbrtf(float x);
long double cbrtl(long double x);
floating_point copysign (arithmetic x, arithmetic y);
float copysignf(float x, float y);
long double copysignl(long double x, long double y);
floating_point erf (arithmetic x);
float erff(float x);
long double erfl(long double x);
floating_point erfc (arithmetic x);
float erfcf(float x);
long double erfcl(long double x);
floating_point exp2 (arithmetic x);
float exp2f(float x);
long double exp2l(long double x);
floating_point expm1 (arithmetic x);
float expm1f(float x);
long double expm1l(long double x);
floating_point fdim (arithmetic x, arithmetic y);
float fdimf(float x, float y);
long double fdiml(long double x, long double y);
floating_point fma (arithmetic x, arithmetic y, arithmetic z);
float fmaf(float x, float y, float z);
long double fmal(long double x, long double y, long double z);
floating_point fmax (arithmetic x, arithmetic y);
float fmaxf(float x, float y);
long double fmaxl(long double x, long double y);
floating_point fmin (arithmetic x, arithmetic y);
float fminf(float x, float y);
long double fminl(long double x, long double y);
floating_point hypot (arithmetic x, arithmetic y);
float hypotf(float x, float y);
long double hypotl(long double x, long double y);
Implement P0030R1: Introduce a 3-Argument Overload to std::hypot llvm-svn: 269772
2016-05-17 22:52:19 +08:00
double hypot(double x, double y, double z); // C++17
float hypot(float x, float y, float z); // C++17
long double hypot(long double x, long double y, long double z); // C++17
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
int ilogb (arithmetic x);
int ilogbf(float x);
int ilogbl(long double x);
floating_point lgamma (arithmetic x);
float lgammaf(float x);
long double lgammal(long double x);
long long llrint (arithmetic x);
long long llrintf(float x);
long long llrintl(long double x);
long long llround (arithmetic x);
long long llroundf(float x);
long long llroundl(long double x);
floating_point log1p (arithmetic x);
float log1pf(float x);
long double log1pl(long double x);
floating_point log2 (arithmetic x);
float log2f(float x);
long double log2l(long double x);
floating_point logb (arithmetic x);
float logbf(float x);
long double logbl(long double x);
long lrint (arithmetic x);
long lrintf(float x);
long lrintl(long double x);
long lround (arithmetic x);
long lroundf(float x);
long lroundl(long double x);
double nan (const char* str);
float nanf(const char* str);
long double nanl(const char* str);
floating_point nearbyint (arithmetic x);
float nearbyintf(float x);
long double nearbyintl(long double x);
floating_point nextafter (arithmetic x, arithmetic y);
float nextafterf(float x, float y);
long double nextafterl(long double x, long double y);
floating_point nexttoward (arithmetic x, long double y);
float nexttowardf(float x, long double y);
long double nexttowardl(long double x, long double y);
floating_point remainder (arithmetic x, arithmetic y);
float remainderf(float x, float y);
long double remainderl(long double x, long double y);
floating_point remquo (arithmetic x, arithmetic y, int* pquo);
float remquof(float x, float y, int* pquo);
long double remquol(long double x, long double y, int* pquo);
floating_point rint (arithmetic x);
float rintf(float x);
long double rintl(long double x);
floating_point round (arithmetic x);
float roundf(float x);
long double roundl(long double x);
floating_point scalbln (arithmetic x, long ex);
float scalblnf(float x, long ex);
long double scalblnl(long double x, long ex);
floating_point scalbn (arithmetic x, int ex);
float scalbnf(float x, int ex);
long double scalbnl(long double x, int ex);
floating_point tgamma (arithmetic x);
float tgammaf(float x);
long double tgammal(long double x);
floating_point trunc (arithmetic x);
float truncf(float x);
long double truncl(long double x);
[libc++] [LWG3201] Update status page: lerp should be marked noexcept. Summary: Update status page and test synopsis. Add synopsis in <cmath>. Reviewed By: ldionne, #libc Differential Revision: https://reviews.llvm.org/D80456
2020-05-26 04:26:50 +08:00
constexpr float lerp(float a, float b, float t) noexcept; // C++20
constexpr double lerp(double a, double b, double t) noexcept; // C++20
constexpr long double lerp(long double a, long double b, long double t) noexcept; // C++20
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
} // std
*/
#include <__config>
#include <math.h>
Implement the infrastructure for feature-test macros. Very few actual feature test macros, though. Reviewed as: https://reviews.llvm.org/D51955 llvm-svn: 342073
2018-09-13 03:41:40 +08:00
#include <version>
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
#include <type_traits>
Windows port work by Ruben Van Boxem llvm-svn: 143105
2011-10-28 00:24:42 +08:00
Windows support by Ruben Van Boxem. llvm-svn: 142235
2011-10-18 04:05:10 +08:00
#if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
#pragma GCC system_header
Windows support by Ruben Van Boxem. llvm-svn: 142235
2011-10-18 04:05:10 +08:00
#endif
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
_LIBCPP_PUSH_MACROS
#include <__undef_macros>
http://llvm.org/bugs/show_bug.cgi?id=9854. Also created an emulated hexfloat literal for use in some of the tests. <sigh> And cleaned up some harmless but irritating warnings in the tests. llvm-svn: 131318
2011-05-14 05:52:40 +08:00
_LIBCPP_BEGIN_NAMESPACE_STD
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
[libc++] Use the using_if_exists attribute when provided As discussed on cfe-dev [1], use the using_if_exists Clang attribute when the compiler supports it. This makes it easier to port libc++ on top of new platforms that don't fully support the C Standard library. Previously, libc++ would fail to build when trying to import a missing declaration in a <cXXXX> header. With the attribute, the declaration will simply not be imported into namespace std, and hence it won't be available for libc++ to use. In many cases, the declarations were *not* actually required for libc++ to work (they were only surfaced for users to use them as std::XXXX), so not importing them into namespace std is acceptable. The same thing could be achieved by conscious usage of `#ifdef` along with platform detection, however that quickly creates a maintenance problem as libc++ is ported to new platforms. Furthermore, this problem is exacerbated when mixed with vendor internal-only platforms, which can lead to difficulties maintaining a downstream fork of the library. For the time being, we only use the using_if_exists attribute when it is supported. At some point in the future, we will start removing #ifdef paths that are unnecessary when the attribute is supported, and folks who need those #ifdef paths will be required to use a compiler that supports the attribute. [1]: http://lists.llvm.org/pipermail/cfe-dev/2020-June/066038.html Differential Revision: https://reviews.llvm.org/D90257
2021-06-02 22:41:37 +08:00
using ::signbit _LIBCPP_USING_IF_EXISTS;
using ::fpclassify _LIBCPP_USING_IF_EXISTS;
using ::isfinite _LIBCPP_USING_IF_EXISTS;
using ::isinf _LIBCPP_USING_IF_EXISTS;
using ::isnan _LIBCPP_USING_IF_EXISTS;
using ::isnormal _LIBCPP_USING_IF_EXISTS;
using ::isgreater _LIBCPP_USING_IF_EXISTS;
using ::isgreaterequal _LIBCPP_USING_IF_EXISTS;
using ::isless _LIBCPP_USING_IF_EXISTS;
using ::islessequal _LIBCPP_USING_IF_EXISTS;
using ::islessgreater _LIBCPP_USING_IF_EXISTS;
using ::isunordered _LIBCPP_USING_IF_EXISTS;
using ::isunordered _LIBCPP_USING_IF_EXISTS;
using ::float_t _LIBCPP_USING_IF_EXISTS;
using ::double_t _LIBCPP_USING_IF_EXISTS;
using ::abs _LIBCPP_USING_IF_EXISTS;
using ::acos _LIBCPP_USING_IF_EXISTS;
using ::acosf _LIBCPP_USING_IF_EXISTS;
using ::asin _LIBCPP_USING_IF_EXISTS;
using ::asinf _LIBCPP_USING_IF_EXISTS;
using ::atan _LIBCPP_USING_IF_EXISTS;
using ::atanf _LIBCPP_USING_IF_EXISTS;
using ::atan2 _LIBCPP_USING_IF_EXISTS;
using ::atan2f _LIBCPP_USING_IF_EXISTS;
using ::ceil _LIBCPP_USING_IF_EXISTS;
using ::ceilf _LIBCPP_USING_IF_EXISTS;
using ::cos _LIBCPP_USING_IF_EXISTS;
using ::cosf _LIBCPP_USING_IF_EXISTS;
using ::cosh _LIBCPP_USING_IF_EXISTS;
using ::coshf _LIBCPP_USING_IF_EXISTS;
using ::exp _LIBCPP_USING_IF_EXISTS;
using ::expf _LIBCPP_USING_IF_EXISTS;
using ::fabs _LIBCPP_USING_IF_EXISTS;
using ::fabsf _LIBCPP_USING_IF_EXISTS;
using ::floor _LIBCPP_USING_IF_EXISTS;
using ::floorf _LIBCPP_USING_IF_EXISTS;
using ::fmod _LIBCPP_USING_IF_EXISTS;
using ::fmodf _LIBCPP_USING_IF_EXISTS;
using ::frexp _LIBCPP_USING_IF_EXISTS;
using ::frexpf _LIBCPP_USING_IF_EXISTS;
using ::ldexp _LIBCPP_USING_IF_EXISTS;
using ::ldexpf _LIBCPP_USING_IF_EXISTS;
using ::log _LIBCPP_USING_IF_EXISTS;
using ::logf _LIBCPP_USING_IF_EXISTS;
using ::log10 _LIBCPP_USING_IF_EXISTS;
using ::log10f _LIBCPP_USING_IF_EXISTS;
using ::modf _LIBCPP_USING_IF_EXISTS;
using ::modff _LIBCPP_USING_IF_EXISTS;
using ::pow _LIBCPP_USING_IF_EXISTS;
using ::powf _LIBCPP_USING_IF_EXISTS;
using ::sin _LIBCPP_USING_IF_EXISTS;
using ::sinf _LIBCPP_USING_IF_EXISTS;
using ::sinh _LIBCPP_USING_IF_EXISTS;
using ::sinhf _LIBCPP_USING_IF_EXISTS;
using ::sqrt _LIBCPP_USING_IF_EXISTS;
using ::sqrtf _LIBCPP_USING_IF_EXISTS;
using ::tan _LIBCPP_USING_IF_EXISTS;
using ::tanf _LIBCPP_USING_IF_EXISTS;
using ::tanh _LIBCPP_USING_IF_EXISTS;
using ::tanhf _LIBCPP_USING_IF_EXISTS;
using ::acosh _LIBCPP_USING_IF_EXISTS;
using ::acoshf _LIBCPP_USING_IF_EXISTS;
using ::asinh _LIBCPP_USING_IF_EXISTS;
using ::asinhf _LIBCPP_USING_IF_EXISTS;
using ::atanh _LIBCPP_USING_IF_EXISTS;
using ::atanhf _LIBCPP_USING_IF_EXISTS;
using ::cbrt _LIBCPP_USING_IF_EXISTS;
using ::cbrtf _LIBCPP_USING_IF_EXISTS;
using ::copysign _LIBCPP_USING_IF_EXISTS;
using ::copysignf _LIBCPP_USING_IF_EXISTS;
using ::erf _LIBCPP_USING_IF_EXISTS;
using ::erff _LIBCPP_USING_IF_EXISTS;
using ::erfc _LIBCPP_USING_IF_EXISTS;
using ::erfcf _LIBCPP_USING_IF_EXISTS;
using ::exp2 _LIBCPP_USING_IF_EXISTS;
using ::exp2f _LIBCPP_USING_IF_EXISTS;
using ::expm1 _LIBCPP_USING_IF_EXISTS;
using ::expm1f _LIBCPP_USING_IF_EXISTS;
using ::fdim _LIBCPP_USING_IF_EXISTS;
using ::fdimf _LIBCPP_USING_IF_EXISTS;
using ::fmaf _LIBCPP_USING_IF_EXISTS;
using ::fma _LIBCPP_USING_IF_EXISTS;
using ::fmax _LIBCPP_USING_IF_EXISTS;
using ::fmaxf _LIBCPP_USING_IF_EXISTS;
using ::fmin _LIBCPP_USING_IF_EXISTS;
using ::fminf _LIBCPP_USING_IF_EXISTS;
using ::hypot _LIBCPP_USING_IF_EXISTS;
using ::hypotf _LIBCPP_USING_IF_EXISTS;
using ::ilogb _LIBCPP_USING_IF_EXISTS;
using ::ilogbf _LIBCPP_USING_IF_EXISTS;
using ::lgamma _LIBCPP_USING_IF_EXISTS;
using ::lgammaf _LIBCPP_USING_IF_EXISTS;
using ::llrint _LIBCPP_USING_IF_EXISTS;
using ::llrintf _LIBCPP_USING_IF_EXISTS;
using ::llround _LIBCPP_USING_IF_EXISTS;
using ::llroundf _LIBCPP_USING_IF_EXISTS;
using ::log1p _LIBCPP_USING_IF_EXISTS;
using ::log1pf _LIBCPP_USING_IF_EXISTS;
using ::log2 _LIBCPP_USING_IF_EXISTS;
using ::log2f _LIBCPP_USING_IF_EXISTS;
using ::logb _LIBCPP_USING_IF_EXISTS;
using ::logbf _LIBCPP_USING_IF_EXISTS;
using ::lrint _LIBCPP_USING_IF_EXISTS;
using ::lrintf _LIBCPP_USING_IF_EXISTS;
using ::lround _LIBCPP_USING_IF_EXISTS;
using ::lroundf _LIBCPP_USING_IF_EXISTS;
using ::nan _LIBCPP_USING_IF_EXISTS;
using ::nanf _LIBCPP_USING_IF_EXISTS;
using ::nearbyint _LIBCPP_USING_IF_EXISTS;
using ::nearbyintf _LIBCPP_USING_IF_EXISTS;
using ::nextafter _LIBCPP_USING_IF_EXISTS;
using ::nextafterf _LIBCPP_USING_IF_EXISTS;
using ::nexttoward _LIBCPP_USING_IF_EXISTS;
using ::nexttowardf _LIBCPP_USING_IF_EXISTS;
using ::remainder _LIBCPP_USING_IF_EXISTS;
using ::remainderf _LIBCPP_USING_IF_EXISTS;
using ::remquo _LIBCPP_USING_IF_EXISTS;
using ::remquof _LIBCPP_USING_IF_EXISTS;
using ::rint _LIBCPP_USING_IF_EXISTS;
using ::rintf _LIBCPP_USING_IF_EXISTS;
using ::round _LIBCPP_USING_IF_EXISTS;
using ::roundf _LIBCPP_USING_IF_EXISTS;
using ::scalbln _LIBCPP_USING_IF_EXISTS;
using ::scalblnf _LIBCPP_USING_IF_EXISTS;
using ::scalbn _LIBCPP_USING_IF_EXISTS;
using ::scalbnf _LIBCPP_USING_IF_EXISTS;
using ::tgamma _LIBCPP_USING_IF_EXISTS;
using ::tgammaf _LIBCPP_USING_IF_EXISTS;
using ::trunc _LIBCPP_USING_IF_EXISTS;
using ::truncf _LIBCPP_USING_IF_EXISTS;
using ::acosl _LIBCPP_USING_IF_EXISTS;
using ::asinl _LIBCPP_USING_IF_EXISTS;
using ::atanl _LIBCPP_USING_IF_EXISTS;
using ::atan2l _LIBCPP_USING_IF_EXISTS;
using ::ceill _LIBCPP_USING_IF_EXISTS;
using ::cosl _LIBCPP_USING_IF_EXISTS;
using ::coshl _LIBCPP_USING_IF_EXISTS;
using ::expl _LIBCPP_USING_IF_EXISTS;
using ::fabsl _LIBCPP_USING_IF_EXISTS;
using ::floorl _LIBCPP_USING_IF_EXISTS;
using ::fmodl _LIBCPP_USING_IF_EXISTS;
using ::frexpl _LIBCPP_USING_IF_EXISTS;
using ::ldexpl _LIBCPP_USING_IF_EXISTS;
using ::logl _LIBCPP_USING_IF_EXISTS;
using ::log10l _LIBCPP_USING_IF_EXISTS;
using ::modfl _LIBCPP_USING_IF_EXISTS;
using ::powl _LIBCPP_USING_IF_EXISTS;
using ::sinl _LIBCPP_USING_IF_EXISTS;
using ::sinhl _LIBCPP_USING_IF_EXISTS;
using ::sqrtl _LIBCPP_USING_IF_EXISTS;
using ::tanl _LIBCPP_USING_IF_EXISTS;
using ::tanhl _LIBCPP_USING_IF_EXISTS;
using ::acoshl _LIBCPP_USING_IF_EXISTS;
using ::asinhl _LIBCPP_USING_IF_EXISTS;
using ::atanhl _LIBCPP_USING_IF_EXISTS;
using ::cbrtl _LIBCPP_USING_IF_EXISTS;
using ::copysignl _LIBCPP_USING_IF_EXISTS;
using ::erfl _LIBCPP_USING_IF_EXISTS;
using ::erfcl _LIBCPP_USING_IF_EXISTS;
using ::exp2l _LIBCPP_USING_IF_EXISTS;
using ::expm1l _LIBCPP_USING_IF_EXISTS;
using ::fdiml _LIBCPP_USING_IF_EXISTS;
using ::fmal _LIBCPP_USING_IF_EXISTS;
using ::fmaxl _LIBCPP_USING_IF_EXISTS;
using ::fminl _LIBCPP_USING_IF_EXISTS;
using ::hypotl _LIBCPP_USING_IF_EXISTS;
using ::ilogbl _LIBCPP_USING_IF_EXISTS;
using ::lgammal _LIBCPP_USING_IF_EXISTS;
using ::llrintl _LIBCPP_USING_IF_EXISTS;
using ::llroundl _LIBCPP_USING_IF_EXISTS;
using ::log1pl _LIBCPP_USING_IF_EXISTS;
using ::log2l _LIBCPP_USING_IF_EXISTS;
using ::logbl _LIBCPP_USING_IF_EXISTS;
using ::lrintl _LIBCPP_USING_IF_EXISTS;
using ::lroundl _LIBCPP_USING_IF_EXISTS;
using ::nanl _LIBCPP_USING_IF_EXISTS;
using ::nearbyintl _LIBCPP_USING_IF_EXISTS;
using ::nextafterl _LIBCPP_USING_IF_EXISTS;
using ::nexttowardl _LIBCPP_USING_IF_EXISTS;
using ::remainderl _LIBCPP_USING_IF_EXISTS;
using ::remquol _LIBCPP_USING_IF_EXISTS;
using ::rintl _LIBCPP_USING_IF_EXISTS;
using ::roundl _LIBCPP_USING_IF_EXISTS;
using ::scalblnl _LIBCPP_USING_IF_EXISTS;
using ::scalbnl _LIBCPP_USING_IF_EXISTS;
using ::tgammal _LIBCPP_USING_IF_EXISTS;
using ::truncl _LIBCPP_USING_IF_EXISTS;
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
Implement P0030R1: Introduce a 3-Argument Overload to std::hypot llvm-svn: 269772
2016-05-17 22:52:19 +08:00
#if _LIBCPP_STD_VER > 14
inline _LIBCPP_INLINE_VISIBILITY float hypot( float x, float y, float z ) { return sqrt(x*x + y*y + z*z); }
inline _LIBCPP_INLINE_VISIBILITY double hypot( double x, double y, double z ) { return sqrt(x*x + y*y + z*z); }
inline _LIBCPP_INLINE_VISIBILITY long double hypot( long double x, long double y, long double z ) { return sqrt(x*x + y*y + z*z); }
template <class _A1, class _A2, class _A3>
inline _LIBCPP_INLINE_VISIBILITY
[libc++] Use enable_if_t instead of _EnableIf I just ran into a compiler error involving __bind_back and some overloads that were being disabled with _EnableIf. I noticed that the error message was quite bad and did not mention the reason for the overload being excluded. Specifically, the error looked like this: candidate template ignored: substitution failure [with _Args = <ContiguousView>]: no member named '_EnableIfImpl' in 'std::_MetaBase<false>' Instead, when using enable_if or enable_if_t, the compiler is clever and can produce better diagnostics, like so: candidate template ignored: requirement 'is_invocable_v< std::__bind_back_op<1, std::integer_sequence<unsigned long, 0>>, std::ranges::views::__transform::__fn &, std::tuple<PlusOne> &, ContiguousView>' was not satisfied [with _Args = <ContiguousView>] Basically, it tries to do a poor man's implementation of concepts, which is already a lot better than simply complaining about substitution failure. Hence, this commit uses enable_if_t instead of _EnableIf whenever possible. That is both more straightforward than using the internal helper, and also leads to better error messages in those cases. I understand the motivation for _EnableIf's implementation was to improve compile-time performance, however I believe striving to improve error messages is even more important for our QOI, hence this patch. Furthermore, it is unclear that _EnableIf actually improved compile-time performance in any noticeable way (see discussion in the review for details). Differential Revision: https://reviews.llvm.org/D108216
2021-08-18 00:26:09 +08:00
typename enable_if_t
Implement P0030R1: Introduce a 3-Argument Overload to std::hypot llvm-svn: 269772
2016-05-17 22:52:19 +08:00
<
Remove some additional unnecessary std:: in cmath Unlike in math.h, as Eric pointed out in the review of D18639, we don't need the std:: in cmath. llvm-svn: 283052
2016-10-02 04:38:44 +08:00
is_arithmetic<_A1>::value &&
is_arithmetic<_A2>::value &&
is_arithmetic<_A3>::value,
__promote<_A1, _A2, _A3>
Implement P0030R1: Introduce a 3-Argument Overload to std::hypot llvm-svn: 269772
2016-05-17 22:52:19 +08:00
>::type
hypot(_A1 __lcpp_x, _A2 __lcpp_y, _A3 __lcpp_z) _NOEXCEPT
{
Remove some additional unnecessary std:: in cmath Unlike in math.h, as Eric pointed out in the review of D18639, we don't need the std:: in cmath. llvm-svn: 283052
2016-10-02 04:38:44 +08:00
typedef typename __promote<_A1, _A2, _A3>::type __result_type;
static_assert((!(is_same<_A1, __result_type>::value &&
is_same<_A2, __result_type>::value &&
is_same<_A3, __result_type>::value)), "");
Implement P0030R1: Introduce a 3-Argument Overload to std::hypot llvm-svn: 269772
2016-05-17 22:52:19 +08:00
return hypot((__result_type)__lcpp_x, (__result_type)__lcpp_y, (__result_type)__lcpp_z);
}
#endif
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isnan_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
#if __has_builtin(__builtin_isnan)
return __builtin_isnan(__lcpp_x);
#else
return isnan(__lcpp_x);
#endif
}
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<!is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isnan_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
return isnan(__lcpp_x);
}
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isinf_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
#if __has_builtin(__builtin_isinf)
return __builtin_isinf(__lcpp_x);
#else
return isinf(__lcpp_x);
#endif
}
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<!is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isinf_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
return isinf(__lcpp_x);
}
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isfinite_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
#if __has_builtin(__builtin_isfinite)
return __builtin_isfinite(__lcpp_x);
#else
return isfinite(__lcpp_x);
#endif
}
template <class _A1>
[libc++] Take 2: Replace uses of _LIBCPP_ALWAYS_INLINE by _LIBCPP_INLINE_VISIBILITY Summary: We never actually mean to always inline a function -- all the uses of the macro I could find are actually attempts to control the visibility of symbols. This is better described by _LIBCPP_INLINE_VISIBILITY, which is actually always defined the same. This change is orthogonal to the decision of what we're actually going to do with _LIBCPP_INLINE_VISIBILITY -- it just simplifies things by having one canonical way of doing things. Note that this commit had originally been applied in r336369 and then reverted in r336382 because of unforeseen problems. Both of these problems have now been fixed. Reviewers: EricWF, mclow.lists Subscribers: christof, dexonsmith, erikvanderpoel Differential Revision: https://reviews.llvm.org/D48892 llvm-svn: 336866
2018-07-12 07:14:33 +08:00
_LIBCPP_INLINE_VISIBILITY
[CUDA] Mark __libcpp_{isnan,isinf,isfinite} as constexpr. Summary: This makes these functions available on host and device, which is necessary to compile <complex> for the device. Reviewers: hfinkel, EricWF Subscribers: cfe-commits Differential Revision: https://reviews.llvm.org/D25403 llvm-svn: 287012
2016-11-16 03:15:57 +08:00
_LIBCPP_CONSTEXPR typename enable_if<!is_floating_point<_A1>::value, bool>::type
cmath: Support clang's -fdelayed-template-parsing r283051 added some functions to cmath (in namespace std) that have the same name as functions in math.h (in the global namespace). Clang's limited support for `-fdelayed-template-parsing` chokes on this. Rename the ones in `cmath` and their uses in `complex` and the test. rdar://problem/32848355 llvm-svn: 307357
2017-07-07 13:13:36 +08:00
__libcpp_isfinite_or_builtin(_A1 __lcpp_x) _NOEXCEPT
Use __builtin_isnan/isinf/isfinite in complex The libc-provided isnan/isinf/isfinite macro implementations are specifically designed to function correctly, even in the presence of -ffast-math (or, more specifically, -ffinite-math-only). As such, on most implementation, these either always turn into external function calls (e.g. glibc) or are specifically function calls when FINITE_MATH_ONLY is defined (e.g. Darwin). Our implementation of complex arithmetic makes heavy use of isnan/isinf/isfinite to deal with corner cases involving non-finite quantities. This was problematic in two respects: 1. On systems where these are always function calls (e.g. Linux/glibc), there was a performance penalty 2. When compiling with -ffast-math, there was a significant performance penalty (in fact, on Darwin and systems with similar implementations, the code may in fact be slower than not using -ffast-math, because the inline definitions provided by libc become unavailable to prevent the checks from being optimized out). Eliding these inf/nan checks in -ffast-math mode is consistent with what happens with libstdc++, and in my experience, what users expect. This is critical to getting high-performance code when using complex<T>. This change replaces uses of those functions on basic floating-point types with calls to __builtin_isnan/isinf/isfinite, which Clang will always expand inline. When using -ffast-math (or -ffinite-math-only), the optimizer will remove the checks as expected. Differential Revision: https://reviews.llvm.org/D18639 llvm-svn: 283051
2016-10-02 04:38:31 +08:00
{
return isfinite(__lcpp_x);
}
Implement 'lerp'; which is the last bit of P0811. Mark that paper as complete. llvm-svn: 359211
2019-04-26 01:44:18 +08:00
#if _LIBCPP_STD_VER > 17
template <typename _Fp>
constexpr
_Fp __lerp(_Fp __a, _Fp __b, _Fp __t) noexcept {
if ((__a <= 0 && __b >= 0) || (__a >= 0 && __b <= 0))
return __t * __b + (1 - __t) * __a;
if (__t == 1) return __b;
const _Fp __x = __a + __t * (__b - __a);
[libc++] Fix a few warnings in system headers with GCC This isn't fixing all of them, but at least it's making some progress. Differential Revision: https://reviews.llvm.org/D106283
2021-07-28 05:30:47 +08:00
if ((__t > 1) == (__b > __a))
[libc++] Remove hard tabs, U+00AD, and U+200B from all libc++ headers. NFCI.
2021-04-18 05:03:20 +08:00
return __b < __x ? __x : __b;
Implement 'lerp'; which is the last bit of P0811. Mark that paper as complete. llvm-svn: 359211
2019-04-26 01:44:18 +08:00
else
[libc++] Remove hard tabs, U+00AD, and U+200B from all libc++ headers. NFCI.
2021-04-18 05:03:20 +08:00
return __x < __b ? __x : __b;
Implement 'lerp'; which is the last bit of P0811. Mark that paper as complete. llvm-svn: 359211
2019-04-26 01:44:18 +08:00
}
constexpr float
lerp(float __a, float __b, float __t) _NOEXCEPT { return __lerp(__a, __b, __t); }
constexpr double
lerp(double __a, double __b, double __t) _NOEXCEPT { return __lerp(__a, __b, __t); }
constexpr long double
lerp(long double __a, long double __b, long double __t) _NOEXCEPT { return __lerp(__a, __b, __t); }
#endif // _LIBCPP_STD_VER > 17
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
template <class _IntT, class _FloatT,
bool _FloatBigger = (numeric_limits<_FloatT>::digits > numeric_limits<_IntT>::digits),
int _Bits = (numeric_limits<_IntT>::digits - numeric_limits<_FloatT>::digits)>
_LIBCPP_INLINE_VISIBILITY
_LIBCPP_CONSTEXPR _IntT __max_representable_int_for_float() _NOEXCEPT {
static_assert(is_floating_point<_FloatT>::value, "must be a floating point type");
static_assert(is_integral<_IntT>::value, "must be an integral type");
static_assert(numeric_limits<_FloatT>::radix == 2, "FloatT has incorrect radix");
[libc++] Harden usage of static_assert against C++03 In C++03, we emulate static_assert with a macro, and we must parenthesize multiple arguments. llvm-svn: 373328
2019-10-01 20:12:21 +08:00
static_assert((_IsSame<_FloatT, float>::value || _IsSame<_FloatT, double>::value
|| _IsSame<_FloatT,long double>::value), "unsupported floating point type");
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
return _FloatBigger ? numeric_limits<_IntT>::max() : (numeric_limits<_IntT>::max() >> _Bits << _Bits);
}
// Convert a floating point number to the specified integral type after
// clamping to the integral types representable range.
//
// The behavior is undefined if `__r` is NaN.
template <class _IntT, class _RealT>
_LIBCPP_INLINE_VISIBILITY
_IntT __clamp_to_integral(_RealT __r) _NOEXCEPT {
[libc++] Consistently replace `std::` qualification with `_VSTD::` or nothing. NFCI. I used a lot of `git grep` to find places where `std::` was being used outside of comments and assert-messages. There were three outcomes: - Qualified function calls, e.g. `std::move` becomes `_VSTD::move`. This is the most common case. - Typenames that don't need qualification, e.g. `std::allocator` becomes `allocator`. Leaving these as `_VSTD::allocator` would also be fine, but I decided that removing the qualification is more consistent with existing practice. - Names that specifically need un-versioned `std::` qualification, or that I wasn't sure about. For example, I didn't touch any code in <atomic>, <math.h>, <new>, or any ext/ or experimental/ headers; and I didn't touch any instances of `std::type_info`. In some deduction guides, we were accidentally using `class Alloc = typename std::allocator<T>`, despite `std::allocator<T>`'s type-ness not being template-dependent. Because `std::allocator` is a qualified name, this did parse as we intended; but what we meant was simply `class Alloc = allocator<T>`. Differential Revision: https://reviews.llvm.org/D92250
2020-11-28 00:02:06 +08:00
using _Lim = numeric_limits<_IntT>;
const _IntT _MaxVal = __max_representable_int_for_float<_IntT, _RealT>();
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
if (__r >= ::nextafter(static_cast<_RealT>(_MaxVal), INFINITY)) {
return _Lim::max();
} else if (__r <= _Lim::lowest()) {
return _Lim::min();
}
return static_cast<_IntT>(__r);
}
libcxx initial import llvm-svn: 103490
2010-05-12 03:42:16 +08:00
_LIBCPP_END_NAMESPACE_STD
[libc++] Move __clamp_to_integral to <cmath>, and harden against min()/max() macros llvm-svn: 370900
2019-09-04 21:35:03 +08:00
_LIBCPP_POP_MACROS
[libc++] NFC: Normalize `#endif //` comment indentation
2021-04-21 00:03:32 +08:00
#endif // _LIBCPP_CMATH