mirror of
https://github.com/ziglang/zig.git
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1861036f3b
release/17.x branch, commit 8f4dd44097c9ae25dd203d5ac87f3b48f854bba8
843 lines
26 KiB
C++
Vendored
843 lines
26 KiB
C++
Vendored
/*===---- __clang_hip_cmath.h - HIP cmath decls -----------------------------===
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*
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* Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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* See https://llvm.org/LICENSE.txt for license information.
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* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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*
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*===-----------------------------------------------------------------------===
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*/
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#ifndef __CLANG_HIP_CMATH_H__
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#define __CLANG_HIP_CMATH_H__
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#if !defined(__HIP__) && !defined(__OPENMP_AMDGCN__)
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#error "This file is for HIP and OpenMP AMDGCN device compilation only."
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#endif
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#if !defined(__HIPCC_RTC__)
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#if defined(__cplusplus)
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#include <limits>
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#include <type_traits>
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#include <utility>
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#endif
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#include <limits.h>
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#include <stdint.h>
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#endif // !defined(__HIPCC_RTC__)
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#pragma push_macro("__DEVICE__")
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#pragma push_macro("__CONSTEXPR__")
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#ifdef __OPENMP_AMDGCN__
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#define __DEVICE__ static __attribute__((always_inline, nothrow))
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#define __CONSTEXPR__ constexpr
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#else
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#define __DEVICE__ static __device__ inline __attribute__((always_inline))
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#define __CONSTEXPR__
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#endif // __OPENMP_AMDGCN__
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// Start with functions that cannot be defined by DEF macros below.
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#if defined(__cplusplus)
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#if defined __OPENMP_AMDGCN__
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__DEVICE__ __CONSTEXPR__ float fabs(float __x) { return ::fabsf(__x); }
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__DEVICE__ __CONSTEXPR__ float sin(float __x) { return ::sinf(__x); }
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__DEVICE__ __CONSTEXPR__ float cos(float __x) { return ::cosf(__x); }
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#endif
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__DEVICE__ __CONSTEXPR__ double abs(double __x) { return ::fabs(__x); }
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__DEVICE__ __CONSTEXPR__ float abs(float __x) { return ::fabsf(__x); }
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__DEVICE__ __CONSTEXPR__ long long abs(long long __n) { return ::llabs(__n); }
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__DEVICE__ __CONSTEXPR__ long abs(long __n) { return ::labs(__n); }
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__DEVICE__ __CONSTEXPR__ float fma(float __x, float __y, float __z) {
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return ::fmaf(__x, __y, __z);
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}
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#if !defined(__HIPCC_RTC__)
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// The value returned by fpclassify is platform dependent, therefore it is not
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// supported by hipRTC.
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__DEVICE__ __CONSTEXPR__ int fpclassify(float __x) {
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return __builtin_fpclassify(FP_NAN, FP_INFINITE, FP_NORMAL, FP_SUBNORMAL,
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FP_ZERO, __x);
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}
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__DEVICE__ __CONSTEXPR__ int fpclassify(double __x) {
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return __builtin_fpclassify(FP_NAN, FP_INFINITE, FP_NORMAL, FP_SUBNORMAL,
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FP_ZERO, __x);
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}
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#endif // !defined(__HIPCC_RTC__)
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__DEVICE__ __CONSTEXPR__ float frexp(float __arg, int *__exp) {
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return ::frexpf(__arg, __exp);
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}
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#if defined(__OPENMP_AMDGCN__)
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// For OpenMP we work around some old system headers that have non-conforming
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// `isinf(float)` and `isnan(float)` implementations that return an `int`. We do
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// this by providing two versions of these functions, differing only in the
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// return type. To avoid conflicting definitions we disable implicit base
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// function generation. That means we will end up with two specializations, one
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// per type, but only one has a base function defined by the system header.
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#pragma omp begin declare variant match( \
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implementation = {extension(disable_implicit_base)})
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// FIXME: We lack an extension to customize the mangling of the variants, e.g.,
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// add a suffix. This means we would clash with the names of the variants
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// (note that we do not create implicit base functions here). To avoid
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// this clash we add a new trait to some of them that is always true
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// (this is LLVM after all ;)). It will only influence the mangled name
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// of the variants inside the inner region and avoid the clash.
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#pragma omp begin declare variant match(implementation = {vendor(llvm)})
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__DEVICE__ __CONSTEXPR__ int isinf(float __x) { return ::__isinff(__x); }
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__DEVICE__ __CONSTEXPR__ int isinf(double __x) { return ::__isinf(__x); }
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__DEVICE__ __CONSTEXPR__ int isfinite(float __x) { return ::__finitef(__x); }
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__DEVICE__ __CONSTEXPR__ int isfinite(double __x) { return ::__finite(__x); }
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__DEVICE__ __CONSTEXPR__ int isnan(float __x) { return ::__isnanf(__x); }
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__DEVICE__ __CONSTEXPR__ int isnan(double __x) { return ::__isnan(__x); }
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#pragma omp end declare variant
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#endif // defined(__OPENMP_AMDGCN__)
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__DEVICE__ __CONSTEXPR__ bool isinf(float __x) { return ::__isinff(__x); }
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__DEVICE__ __CONSTEXPR__ bool isinf(double __x) { return ::__isinf(__x); }
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__DEVICE__ __CONSTEXPR__ bool isfinite(float __x) { return ::__finitef(__x); }
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__DEVICE__ __CONSTEXPR__ bool isfinite(double __x) { return ::__finite(__x); }
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__DEVICE__ __CONSTEXPR__ bool isnan(float __x) { return ::__isnanf(__x); }
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__DEVICE__ __CONSTEXPR__ bool isnan(double __x) { return ::__isnan(__x); }
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#if defined(__OPENMP_AMDGCN__)
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#pragma omp end declare variant
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#endif // defined(__OPENMP_AMDGCN__)
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__DEVICE__ __CONSTEXPR__ bool isgreater(float __x, float __y) {
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return __builtin_isgreater(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isgreater(double __x, double __y) {
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return __builtin_isgreater(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isgreaterequal(float __x, float __y) {
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return __builtin_isgreaterequal(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isgreaterequal(double __x, double __y) {
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return __builtin_isgreaterequal(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isless(float __x, float __y) {
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return __builtin_isless(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isless(double __x, double __y) {
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return __builtin_isless(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool islessequal(float __x, float __y) {
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return __builtin_islessequal(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool islessequal(double __x, double __y) {
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return __builtin_islessequal(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool islessgreater(float __x, float __y) {
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return __builtin_islessgreater(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool islessgreater(double __x, double __y) {
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return __builtin_islessgreater(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isnormal(float __x) {
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return __builtin_isnormal(__x);
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}
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__DEVICE__ __CONSTEXPR__ bool isnormal(double __x) {
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return __builtin_isnormal(__x);
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}
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__DEVICE__ __CONSTEXPR__ bool isunordered(float __x, float __y) {
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return __builtin_isunordered(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ bool isunordered(double __x, double __y) {
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return __builtin_isunordered(__x, __y);
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}
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__DEVICE__ __CONSTEXPR__ float modf(float __x, float *__iptr) {
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return ::modff(__x, __iptr);
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}
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__DEVICE__ __CONSTEXPR__ float pow(float __base, int __iexp) {
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return ::powif(__base, __iexp);
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}
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__DEVICE__ __CONSTEXPR__ double pow(double __base, int __iexp) {
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return ::powi(__base, __iexp);
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}
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__DEVICE__ __CONSTEXPR__ float remquo(float __x, float __y, int *__quo) {
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return ::remquof(__x, __y, __quo);
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}
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__DEVICE__ __CONSTEXPR__ float scalbln(float __x, long int __n) {
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return ::scalblnf(__x, __n);
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}
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__DEVICE__ __CONSTEXPR__ bool signbit(float __x) { return ::__signbitf(__x); }
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__DEVICE__ __CONSTEXPR__ bool signbit(double __x) { return ::__signbit(__x); }
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// Notably missing above is nexttoward. We omit it because
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// ocml doesn't provide an implementation, and we don't want to be in the
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// business of implementing tricky libm functions in this header.
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// Other functions.
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__DEVICE__ __CONSTEXPR__ _Float16 fma(_Float16 __x, _Float16 __y,
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_Float16 __z) {
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return __builtin_fmaf16(__x, __y, __z);
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}
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__DEVICE__ __CONSTEXPR__ _Float16 pow(_Float16 __base, int __iexp) {
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return __ocml_pown_f16(__base, __iexp);
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}
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#ifndef __OPENMP_AMDGCN__
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// BEGIN DEF_FUN and HIP_OVERLOAD
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// BEGIN DEF_FUN
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#pragma push_macro("__DEF_FUN1")
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#pragma push_macro("__DEF_FUN2")
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#pragma push_macro("__DEF_FUN2_FI")
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// Define cmath functions with float argument and returns __retty.
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#define __DEF_FUN1(__retty, __func) \
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__DEVICE__ __CONSTEXPR__ __retty __func(float __x) { return __func##f(__x); }
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// Define cmath functions with two float arguments and returns __retty.
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#define __DEF_FUN2(__retty, __func) \
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__DEVICE__ __CONSTEXPR__ __retty __func(float __x, float __y) { \
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return __func##f(__x, __y); \
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}
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// Define cmath functions with a float and an int argument and returns __retty.
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#define __DEF_FUN2_FI(__retty, __func) \
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__DEVICE__ __CONSTEXPR__ __retty __func(float __x, int __y) { \
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return __func##f(__x, __y); \
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}
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__DEF_FUN1(float, acos)
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__DEF_FUN1(float, acosh)
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__DEF_FUN1(float, asin)
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__DEF_FUN1(float, asinh)
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__DEF_FUN1(float, atan)
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__DEF_FUN2(float, atan2)
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__DEF_FUN1(float, atanh)
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__DEF_FUN1(float, cbrt)
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__DEF_FUN1(float, ceil)
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__DEF_FUN2(float, copysign)
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__DEF_FUN1(float, cos)
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__DEF_FUN1(float, cosh)
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__DEF_FUN1(float, erf)
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__DEF_FUN1(float, erfc)
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__DEF_FUN1(float, exp)
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__DEF_FUN1(float, exp2)
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__DEF_FUN1(float, expm1)
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__DEF_FUN1(float, fabs)
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__DEF_FUN2(float, fdim)
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__DEF_FUN1(float, floor)
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__DEF_FUN2(float, fmax)
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__DEF_FUN2(float, fmin)
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__DEF_FUN2(float, fmod)
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__DEF_FUN2(float, hypot)
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__DEF_FUN1(int, ilogb)
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__DEF_FUN2_FI(float, ldexp)
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__DEF_FUN1(float, lgamma)
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__DEF_FUN1(float, log)
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__DEF_FUN1(float, log10)
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__DEF_FUN1(float, log1p)
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__DEF_FUN1(float, log2)
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__DEF_FUN1(float, logb)
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__DEF_FUN1(long long, llrint)
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__DEF_FUN1(long long, llround)
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__DEF_FUN1(long, lrint)
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__DEF_FUN1(long, lround)
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__DEF_FUN1(float, nearbyint)
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__DEF_FUN2(float, nextafter)
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__DEF_FUN2(float, pow)
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__DEF_FUN2(float, remainder)
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__DEF_FUN1(float, rint)
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__DEF_FUN1(float, round)
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__DEF_FUN2_FI(float, scalbn)
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__DEF_FUN1(float, sin)
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__DEF_FUN1(float, sinh)
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__DEF_FUN1(float, sqrt)
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__DEF_FUN1(float, tan)
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__DEF_FUN1(float, tanh)
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__DEF_FUN1(float, tgamma)
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__DEF_FUN1(float, trunc)
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#pragma pop_macro("__DEF_FUN1")
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#pragma pop_macro("__DEF_FUN2")
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#pragma pop_macro("__DEF_FUN2_FI")
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// END DEF_FUN
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// BEGIN HIP_OVERLOAD
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#pragma push_macro("__HIP_OVERLOAD1")
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#pragma push_macro("__HIP_OVERLOAD2")
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// __hip_enable_if::type is a type function which returns __T if __B is true.
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template <bool __B, class __T = void> struct __hip_enable_if {};
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template <class __T> struct __hip_enable_if<true, __T> { typedef __T type; };
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namespace __hip {
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template <class _Tp> struct is_integral {
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enum { value = 0 };
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};
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template <> struct is_integral<bool> {
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enum { value = 1 };
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};
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template <> struct is_integral<char> {
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enum { value = 1 };
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};
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template <> struct is_integral<signed char> {
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enum { value = 1 };
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};
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template <> struct is_integral<unsigned char> {
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enum { value = 1 };
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};
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template <> struct is_integral<wchar_t> {
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enum { value = 1 };
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};
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template <> struct is_integral<short> {
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enum { value = 1 };
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};
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template <> struct is_integral<unsigned short> {
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enum { value = 1 };
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};
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template <> struct is_integral<int> {
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enum { value = 1 };
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};
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template <> struct is_integral<unsigned int> {
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enum { value = 1 };
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};
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template <> struct is_integral<long> {
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enum { value = 1 };
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};
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template <> struct is_integral<unsigned long> {
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enum { value = 1 };
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};
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template <> struct is_integral<long long> {
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enum { value = 1 };
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};
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template <> struct is_integral<unsigned long long> {
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enum { value = 1 };
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};
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// ToDo: specializes is_arithmetic<_Float16>
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template <class _Tp> struct is_arithmetic {
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enum { value = 0 };
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};
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template <> struct is_arithmetic<bool> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<char> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<signed char> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<unsigned char> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<wchar_t> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<short> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<unsigned short> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<int> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<unsigned int> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<long> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<unsigned long> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<long long> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<unsigned long long> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<float> {
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enum { value = 1 };
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};
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template <> struct is_arithmetic<double> {
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enum { value = 1 };
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};
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struct true_type {
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static const __constant__ bool value = true;
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};
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struct false_type {
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static const __constant__ bool value = false;
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};
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template <typename __T, typename __U> struct is_same : public false_type {};
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template <typename __T> struct is_same<__T, __T> : public true_type {};
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template <typename __T> struct add_rvalue_reference { typedef __T &&type; };
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template <typename __T> typename add_rvalue_reference<__T>::type declval();
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// decltype is only available in C++11 and above.
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#if __cplusplus >= 201103L
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// __hip_promote
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template <class _Tp> struct __numeric_type {
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static void __test(...);
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static _Float16 __test(_Float16);
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static float __test(float);
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static double __test(char);
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static double __test(int);
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static double __test(unsigned);
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static double __test(long);
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static double __test(unsigned long);
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static double __test(long long);
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static double __test(unsigned long long);
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static double __test(double);
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// No support for long double, use double instead.
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static double __test(long double);
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typedef decltype(__test(declval<_Tp>())) type;
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static const bool value = !is_same<type, void>::value;
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};
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template <> struct __numeric_type<void> { static const bool value = true; };
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template <class _A1, class _A2 = void, class _A3 = void,
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bool = __numeric_type<_A1>::value &&__numeric_type<_A2>::value
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&&__numeric_type<_A3>::value>
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class __promote_imp {
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public:
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static const bool value = false;
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};
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template <class _A1, class _A2, class _A3>
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class __promote_imp<_A1, _A2, _A3, true> {
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private:
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typedef typename __promote_imp<_A1>::type __type1;
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typedef typename __promote_imp<_A2>::type __type2;
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typedef typename __promote_imp<_A3>::type __type3;
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public:
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typedef decltype(__type1() + __type2() + __type3()) type;
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static const bool value = true;
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};
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template <class _A1, class _A2> class __promote_imp<_A1, _A2, void, true> {
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private:
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typedef typename __promote_imp<_A1>::type __type1;
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typedef typename __promote_imp<_A2>::type __type2;
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public:
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typedef decltype(__type1() + __type2()) type;
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static const bool value = true;
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};
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template <class _A1> class __promote_imp<_A1, void, void, true> {
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public:
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typedef typename __numeric_type<_A1>::type type;
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static const bool value = true;
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};
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template <class _A1, class _A2 = void, class _A3 = void>
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class __promote : public __promote_imp<_A1, _A2, _A3> {};
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#endif //__cplusplus >= 201103L
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} // namespace __hip
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// __HIP_OVERLOAD1 is used to resolve function calls with integer argument to
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// avoid compilation error due to ambibuity. e.g. floor(5) is resolved with
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// floor(double).
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#define __HIP_OVERLOAD1(__retty, __fn) \
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template <typename __T> \
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__DEVICE__ __CONSTEXPR__ \
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|
typename __hip_enable_if<__hip::is_integral<__T>::value, __retty>::type \
|
|
__fn(__T __x) { \
|
|
return ::__fn((double)__x); \
|
|
}
|
|
|
|
// __HIP_OVERLOAD2 is used to resolve function calls with mixed float/double
|
|
// or integer argument to avoid compilation error due to ambibuity. e.g.
|
|
// max(5.0f, 6.0) is resolved with max(double, double).
|
|
#if __cplusplus >= 201103L
|
|
#define __HIP_OVERLOAD2(__retty, __fn) \
|
|
template <typename __T1, typename __T2> \
|
|
__DEVICE__ __CONSTEXPR__ typename __hip_enable_if< \
|
|
__hip::is_arithmetic<__T1>::value && __hip::is_arithmetic<__T2>::value, \
|
|
typename __hip::__promote<__T1, __T2>::type>::type \
|
|
__fn(__T1 __x, __T2 __y) { \
|
|
typedef typename __hip::__promote<__T1, __T2>::type __result_type; \
|
|
return __fn((__result_type)__x, (__result_type)__y); \
|
|
}
|
|
#else
|
|
#define __HIP_OVERLOAD2(__retty, __fn) \
|
|
template <typename __T1, typename __T2> \
|
|
__DEVICE__ __CONSTEXPR__ \
|
|
typename __hip_enable_if<__hip::is_arithmetic<__T1>::value && \
|
|
__hip::is_arithmetic<__T2>::value, \
|
|
__retty>::type \
|
|
__fn(__T1 __x, __T2 __y) { \
|
|
return __fn((double)__x, (double)__y); \
|
|
}
|
|
#endif
|
|
|
|
__HIP_OVERLOAD1(double, acos)
|
|
__HIP_OVERLOAD1(double, acosh)
|
|
__HIP_OVERLOAD1(double, asin)
|
|
__HIP_OVERLOAD1(double, asinh)
|
|
__HIP_OVERLOAD1(double, atan)
|
|
__HIP_OVERLOAD2(double, atan2)
|
|
__HIP_OVERLOAD1(double, atanh)
|
|
__HIP_OVERLOAD1(double, cbrt)
|
|
__HIP_OVERLOAD1(double, ceil)
|
|
__HIP_OVERLOAD2(double, copysign)
|
|
__HIP_OVERLOAD1(double, cos)
|
|
__HIP_OVERLOAD1(double, cosh)
|
|
__HIP_OVERLOAD1(double, erf)
|
|
__HIP_OVERLOAD1(double, erfc)
|
|
__HIP_OVERLOAD1(double, exp)
|
|
__HIP_OVERLOAD1(double, exp2)
|
|
__HIP_OVERLOAD1(double, expm1)
|
|
__HIP_OVERLOAD1(double, fabs)
|
|
__HIP_OVERLOAD2(double, fdim)
|
|
__HIP_OVERLOAD1(double, floor)
|
|
__HIP_OVERLOAD2(double, fmax)
|
|
__HIP_OVERLOAD2(double, fmin)
|
|
__HIP_OVERLOAD2(double, fmod)
|
|
#if !defined(__HIPCC_RTC__)
|
|
__HIP_OVERLOAD1(int, fpclassify)
|
|
#endif // !defined(__HIPCC_RTC__)
|
|
__HIP_OVERLOAD2(double, hypot)
|
|
__HIP_OVERLOAD1(int, ilogb)
|
|
__HIP_OVERLOAD1(bool, isfinite)
|
|
__HIP_OVERLOAD2(bool, isgreater)
|
|
__HIP_OVERLOAD2(bool, isgreaterequal)
|
|
__HIP_OVERLOAD1(bool, isinf)
|
|
__HIP_OVERLOAD2(bool, isless)
|
|
__HIP_OVERLOAD2(bool, islessequal)
|
|
__HIP_OVERLOAD2(bool, islessgreater)
|
|
__HIP_OVERLOAD1(bool, isnan)
|
|
__HIP_OVERLOAD1(bool, isnormal)
|
|
__HIP_OVERLOAD2(bool, isunordered)
|
|
__HIP_OVERLOAD1(double, lgamma)
|
|
__HIP_OVERLOAD1(double, log)
|
|
__HIP_OVERLOAD1(double, log10)
|
|
__HIP_OVERLOAD1(double, log1p)
|
|
__HIP_OVERLOAD1(double, log2)
|
|
__HIP_OVERLOAD1(double, logb)
|
|
__HIP_OVERLOAD1(long long, llrint)
|
|
__HIP_OVERLOAD1(long long, llround)
|
|
__HIP_OVERLOAD1(long, lrint)
|
|
__HIP_OVERLOAD1(long, lround)
|
|
__HIP_OVERLOAD1(double, nearbyint)
|
|
__HIP_OVERLOAD2(double, nextafter)
|
|
__HIP_OVERLOAD2(double, pow)
|
|
__HIP_OVERLOAD2(double, remainder)
|
|
__HIP_OVERLOAD1(double, rint)
|
|
__HIP_OVERLOAD1(double, round)
|
|
__HIP_OVERLOAD1(bool, signbit)
|
|
__HIP_OVERLOAD1(double, sin)
|
|
__HIP_OVERLOAD1(double, sinh)
|
|
__HIP_OVERLOAD1(double, sqrt)
|
|
__HIP_OVERLOAD1(double, tan)
|
|
__HIP_OVERLOAD1(double, tanh)
|
|
__HIP_OVERLOAD1(double, tgamma)
|
|
__HIP_OVERLOAD1(double, trunc)
|
|
|
|
// Overload these but don't add them to std, they are not part of cmath.
|
|
__HIP_OVERLOAD2(double, max)
|
|
__HIP_OVERLOAD2(double, min)
|
|
|
|
// Additional Overloads that don't quite match HIP_OVERLOAD.
|
|
#if __cplusplus >= 201103L
|
|
template <typename __T1, typename __T2, typename __T3>
|
|
__DEVICE__ __CONSTEXPR__ typename __hip_enable_if<
|
|
__hip::is_arithmetic<__T1>::value && __hip::is_arithmetic<__T2>::value &&
|
|
__hip::is_arithmetic<__T3>::value,
|
|
typename __hip::__promote<__T1, __T2, __T3>::type>::type
|
|
fma(__T1 __x, __T2 __y, __T3 __z) {
|
|
typedef typename __hip::__promote<__T1, __T2, __T3>::type __result_type;
|
|
return ::fma((__result_type)__x, (__result_type)__y, (__result_type)__z);
|
|
}
|
|
#else
|
|
template <typename __T1, typename __T2, typename __T3>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_arithmetic<__T1>::value &&
|
|
__hip::is_arithmetic<__T2>::value &&
|
|
__hip::is_arithmetic<__T3>::value,
|
|
double>::type
|
|
fma(__T1 __x, __T2 __y, __T3 __z) {
|
|
return ::fma((double)__x, (double)__y, (double)__z);
|
|
}
|
|
#endif
|
|
|
|
template <typename __T>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_integral<__T>::value, double>::type
|
|
frexp(__T __x, int *__exp) {
|
|
return ::frexp((double)__x, __exp);
|
|
}
|
|
|
|
template <typename __T>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_integral<__T>::value, double>::type
|
|
ldexp(__T __x, int __exp) {
|
|
return ::ldexp((double)__x, __exp);
|
|
}
|
|
|
|
template <typename __T>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_integral<__T>::value, double>::type
|
|
modf(__T __x, double *__exp) {
|
|
return ::modf((double)__x, __exp);
|
|
}
|
|
|
|
#if __cplusplus >= 201103L
|
|
template <typename __T1, typename __T2>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_arithmetic<__T1>::value &&
|
|
__hip::is_arithmetic<__T2>::value,
|
|
typename __hip::__promote<__T1, __T2>::type>::type
|
|
remquo(__T1 __x, __T2 __y, int *__quo) {
|
|
typedef typename __hip::__promote<__T1, __T2>::type __result_type;
|
|
return ::remquo((__result_type)__x, (__result_type)__y, __quo);
|
|
}
|
|
#else
|
|
template <typename __T1, typename __T2>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_arithmetic<__T1>::value &&
|
|
__hip::is_arithmetic<__T2>::value,
|
|
double>::type
|
|
remquo(__T1 __x, __T2 __y, int *__quo) {
|
|
return ::remquo((double)__x, (double)__y, __quo);
|
|
}
|
|
#endif
|
|
|
|
template <typename __T>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_integral<__T>::value, double>::type
|
|
scalbln(__T __x, long int __exp) {
|
|
return ::scalbln((double)__x, __exp);
|
|
}
|
|
|
|
template <typename __T>
|
|
__DEVICE__ __CONSTEXPR__
|
|
typename __hip_enable_if<__hip::is_integral<__T>::value, double>::type
|
|
scalbn(__T __x, int __exp) {
|
|
return ::scalbn((double)__x, __exp);
|
|
}
|
|
|
|
#pragma pop_macro("__HIP_OVERLOAD1")
|
|
#pragma pop_macro("__HIP_OVERLOAD2")
|
|
|
|
// END HIP_OVERLOAD
|
|
|
|
// END DEF_FUN and HIP_OVERLOAD
|
|
|
|
#endif // ifndef __OPENMP_AMDGCN__
|
|
#endif // defined(__cplusplus)
|
|
|
|
#ifndef __OPENMP_AMDGCN__
|
|
// Define these overloads inside the namespace our standard library uses.
|
|
#if !defined(__HIPCC_RTC__)
|
|
#ifdef _LIBCPP_BEGIN_NAMESPACE_STD
|
|
_LIBCPP_BEGIN_NAMESPACE_STD
|
|
#else
|
|
namespace std {
|
|
#ifdef _GLIBCXX_BEGIN_NAMESPACE_VERSION
|
|
_GLIBCXX_BEGIN_NAMESPACE_VERSION
|
|
#endif // _GLIBCXX_BEGIN_NAMESPACE_VERSION
|
|
#endif // _LIBCPP_BEGIN_NAMESPACE_STD
|
|
|
|
// Pull the new overloads we defined above into namespace std.
|
|
// using ::abs; - This may be considered for C++.
|
|
using ::acos;
|
|
using ::acosh;
|
|
using ::asin;
|
|
using ::asinh;
|
|
using ::atan;
|
|
using ::atan2;
|
|
using ::atanh;
|
|
using ::cbrt;
|
|
using ::ceil;
|
|
using ::copysign;
|
|
using ::cos;
|
|
using ::cosh;
|
|
using ::erf;
|
|
using ::erfc;
|
|
using ::exp;
|
|
using ::exp2;
|
|
using ::expm1;
|
|
using ::fabs;
|
|
using ::fdim;
|
|
using ::floor;
|
|
using ::fma;
|
|
using ::fmax;
|
|
using ::fmin;
|
|
using ::fmod;
|
|
using ::fpclassify;
|
|
using ::frexp;
|
|
using ::hypot;
|
|
using ::ilogb;
|
|
using ::isfinite;
|
|
using ::isgreater;
|
|
using ::isgreaterequal;
|
|
using ::isless;
|
|
using ::islessequal;
|
|
using ::islessgreater;
|
|
using ::isnormal;
|
|
using ::isunordered;
|
|
using ::ldexp;
|
|
using ::lgamma;
|
|
using ::llrint;
|
|
using ::llround;
|
|
using ::log;
|
|
using ::log10;
|
|
using ::log1p;
|
|
using ::log2;
|
|
using ::logb;
|
|
using ::lrint;
|
|
using ::lround;
|
|
using ::modf;
|
|
// using ::nan; - This may be considered for C++.
|
|
// using ::nanf; - This may be considered for C++.
|
|
// using ::nanl; - This is not yet defined.
|
|
using ::nearbyint;
|
|
using ::nextafter;
|
|
// using ::nexttoward; - Omit this since we do not have a definition.
|
|
using ::pow;
|
|
using ::remainder;
|
|
using ::remquo;
|
|
using ::rint;
|
|
using ::round;
|
|
using ::scalbln;
|
|
using ::scalbn;
|
|
using ::signbit;
|
|
using ::sin;
|
|
using ::sinh;
|
|
using ::sqrt;
|
|
using ::tan;
|
|
using ::tanh;
|
|
using ::tgamma;
|
|
using ::trunc;
|
|
|
|
// Well this is fun: We need to pull these symbols in for libc++, but we can't
|
|
// pull them in with libstdc++, because its ::isinf and ::isnan are different
|
|
// than its std::isinf and std::isnan.
|
|
#ifndef __GLIBCXX__
|
|
using ::isinf;
|
|
using ::isnan;
|
|
#endif
|
|
|
|
// Finally, pull the "foobarf" functions that HIP defines into std.
|
|
using ::acosf;
|
|
using ::acoshf;
|
|
using ::asinf;
|
|
using ::asinhf;
|
|
using ::atan2f;
|
|
using ::atanf;
|
|
using ::atanhf;
|
|
using ::cbrtf;
|
|
using ::ceilf;
|
|
using ::copysignf;
|
|
using ::cosf;
|
|
using ::coshf;
|
|
using ::erfcf;
|
|
using ::erff;
|
|
using ::exp2f;
|
|
using ::expf;
|
|
using ::expm1f;
|
|
using ::fabsf;
|
|
using ::fdimf;
|
|
using ::floorf;
|
|
using ::fmaf;
|
|
using ::fmaxf;
|
|
using ::fminf;
|
|
using ::fmodf;
|
|
using ::frexpf;
|
|
using ::hypotf;
|
|
using ::ilogbf;
|
|
using ::ldexpf;
|
|
using ::lgammaf;
|
|
using ::llrintf;
|
|
using ::llroundf;
|
|
using ::log10f;
|
|
using ::log1pf;
|
|
using ::log2f;
|
|
using ::logbf;
|
|
using ::logf;
|
|
using ::lrintf;
|
|
using ::lroundf;
|
|
using ::modff;
|
|
using ::nearbyintf;
|
|
using ::nextafterf;
|
|
// using ::nexttowardf; - Omit this since we do not have a definition.
|
|
using ::powf;
|
|
using ::remainderf;
|
|
using ::remquof;
|
|
using ::rintf;
|
|
using ::roundf;
|
|
using ::scalblnf;
|
|
using ::scalbnf;
|
|
using ::sinf;
|
|
using ::sinhf;
|
|
using ::sqrtf;
|
|
using ::tanf;
|
|
using ::tanhf;
|
|
using ::tgammaf;
|
|
using ::truncf;
|
|
|
|
#ifdef _LIBCPP_END_NAMESPACE_STD
|
|
_LIBCPP_END_NAMESPACE_STD
|
|
#else
|
|
#ifdef _GLIBCXX_BEGIN_NAMESPACE_VERSION
|
|
_GLIBCXX_END_NAMESPACE_VERSION
|
|
#endif // _GLIBCXX_BEGIN_NAMESPACE_VERSION
|
|
} // namespace std
|
|
#endif // _LIBCPP_END_NAMESPACE_STD
|
|
#endif // !defined(__HIPCC_RTC__)
|
|
|
|
// Define device-side math functions from <ymath.h> on MSVC.
|
|
#if !defined(__HIPCC_RTC__)
|
|
#if defined(_MSC_VER)
|
|
|
|
// Before VS2019, `<ymath.h>` is also included in `<limits>` and other headers.
|
|
// But, from VS2019, it's only included in `<complex>`. Need to include
|
|
// `<ymath.h>` here to ensure C functions declared there won't be markded as
|
|
// `__host__` and `__device__` through `<complex>` wrapper.
|
|
#include <ymath.h>
|
|
|
|
#if defined(__cplusplus)
|
|
extern "C" {
|
|
#endif // defined(__cplusplus)
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) double _Cosh(double x,
|
|
double y) {
|
|
return cosh(x) * y;
|
|
}
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) float _FCosh(float x,
|
|
float y) {
|
|
return coshf(x) * y;
|
|
}
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) short _Dtest(double *p) {
|
|
return fpclassify(*p);
|
|
}
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) short _FDtest(float *p) {
|
|
return fpclassify(*p);
|
|
}
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) double _Sinh(double x,
|
|
double y) {
|
|
return sinh(x) * y;
|
|
}
|
|
__DEVICE__ __CONSTEXPR__ __attribute__((overloadable)) float _FSinh(float x,
|
|
float y) {
|
|
return sinhf(x) * y;
|
|
}
|
|
#if defined(__cplusplus)
|
|
}
|
|
#endif // defined(__cplusplus)
|
|
#endif // defined(_MSC_VER)
|
|
#endif // !defined(__HIPCC_RTC__)
|
|
#endif // ifndef __OPENMP_AMDGCN__
|
|
|
|
#pragma pop_macro("__DEVICE__")
|
|
#pragma pop_macro("__CONSTEXPR__")
|
|
|
|
#endif // __CLANG_HIP_CMATH_H__
|