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

 /*===---- __clang_cuda_runtime_wrapper.h - CUDA runtime support -------------===
  *
  * 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
  *
  *===-----------------------------------------------------------------------===
  */

 /*
  * WARNING: This header is intended to be directly -include'd by
  * the compiler and is not supposed to be included by users.
  *
  * CUDA headers are implemented in a way that currently makes it
  * impossible for user code to #include directly when compiling with
  * Clang. They present different view of CUDA-supplied functions
  * depending on where in NVCC's compilation pipeline the headers are
  * included. Neither of these modes provides function definitions with
  * correct attributes, so we use preprocessor to force the headers
  * into a form that Clang can use.
  *
  * Similarly to NVCC which -include's cuda_runtime.h, Clang -include's
  * this file during every CUDA compilation.
  */

 #ifndef __CLANG_CUDA_RUNTIME_WRAPPER_H__
 #define __CLANG_CUDA_RUNTIME_WRAPPER_H__

 #if defined(__CUDA__) && defined(__clang__)

 // Include some forward declares that must come before cmath.
 #include <__clang_cuda_math_forward_declares.h>

 // Define __CUDACC__ early as libstdc++ standard headers with GNU extensions
 // enabled depend on it to avoid using __float128, which is unsupported in
 // CUDA.
 #define __CUDACC__

 // Include some standard headers to avoid CUDA headers including them
 // while some required macros (like __THROW) are in a weird state.
 #include <cmath>
 #include <cstdlib>
 #include <stdlib.h>
 #include <string.h>
 #undef __CUDACC__

 // Preserve common macros that will be changed below by us or by CUDA
 // headers.
 #pragma push_macro("__THROW")
 #pragma push_macro("__CUDA_ARCH__")

 // WARNING: Preprocessor hacks below are based on specific details of
 // CUDA-7.x headers and are not expected to work with any other
 // version of CUDA headers.
 #include "cuda.h"
 #if !defined(CUDA_VERSION)
 #error "cuda.h did not define CUDA_VERSION"
 #elif CUDA_VERSION < 7000
 #error "Unsupported CUDA version!"
 #endif

 #pragma push_macro("__CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__")
 #if CUDA_VERSION >= 10000
 #define __CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__
 #endif

 // Make largest subset of device functions available during host
 // compilation.
 #ifndef __CUDA_ARCH__
 #define __CUDA_ARCH__ 9999
 #endif

 #include "__clang_cuda_builtin_vars.h"

 // No need for device_launch_parameters.h as __clang_cuda_builtin_vars.h above
 // has taken care of builtin variables declared in the file.
 #define __DEVICE_LAUNCH_PARAMETERS_H__

 // {math,device}_functions.h only have declarations of the
 // functions. We don't need them as we're going to pull in their
 // definitions from .hpp files.
 #define __DEVICE_FUNCTIONS_H__
 #define __MATH_FUNCTIONS_H__
 #define __COMMON_FUNCTIONS_H__
 // device_functions_decls is replaced by __clang_cuda_device_functions.h
 // included below.
 #define __DEVICE_FUNCTIONS_DECLS_H__

 #undef __CUDACC__
 #if CUDA_VERSION < 9000
 #define __CUDABE__
 #else
 #define __CUDACC__
 #define __CUDA_LIBDEVICE__
 #endif
 // Disables definitions of device-side runtime support stubs in
 // cuda_device_runtime_api.h
 #include "host_defines.h"
 #undef __CUDACC__
 #include "driver_types.h"
 #include "host_config.h"

 // Temporarily replace "nv_weak" with weak, so __attribute__((nv_weak)) in
 // cuda_device_runtime_api.h ends up being __attribute__((weak)) which is the
 // functional equivalent of what we need.
 #pragma push_macro("nv_weak")
 #define nv_weak weak
 #undef __CUDABE__
 #undef __CUDA_LIBDEVICE__
 #define __CUDACC__
 #include "cuda_runtime.h"

 #pragma pop_macro("nv_weak")
 #undef __CUDACC__
 #define __CUDABE__

 // CUDA headers use __nvvm_memcpy and __nvvm_memset which Clang does
 // not have at the moment. Emulate them with a builtin memcpy/memset.
 #define __nvvm_memcpy(s, d, n, a) __builtin_memcpy(s, d, n)
 #define __nvvm_memset(d, c, n, a) __builtin_memset(d, c, n)

 #if CUDA_VERSION < 9000
 #include "crt/device_runtime.h"
 #endif
 #include "crt/host_runtime.h"
 // device_runtime.h defines __cxa_* macros that will conflict with
 // cxxabi.h.
 // FIXME: redefine these as __device__ functions.
 #undef __cxa_vec_ctor
 #undef __cxa_vec_cctor
 #undef __cxa_vec_dtor
 #undef __cxa_vec_new
 #undef __cxa_vec_new2
 #undef __cxa_vec_new3
 #undef __cxa_vec_delete2
 #undef __cxa_vec_delete
 #undef __cxa_vec_delete3
 #undef __cxa_pure_virtual

 // math_functions.hpp expects this host function be defined on MacOS, but it
 // ends up not being there because of the games we play here.  Just define it
 // ourselves; it's simple enough.
 #ifdef __APPLE__
 inline __host__ double __signbitd(double x) {
   return std::signbit(x);
 }
 #endif

 // CUDA 9.1 no longer provides declarations for libdevice functions, so we need
 // to provide our own.
 #include <__clang_cuda_libdevice_declares.h>

 // Wrappers for many device-side standard library functions, incl. math
 // functions, became compiler builtins in CUDA-9 and have been removed from the
 // CUDA headers. Clang now provides its own implementation of the wrappers.
 #if CUDA_VERSION >= 9000
 #include <__clang_cuda_device_functions.h>
 #include <__clang_cuda_math.h>
 #endif

 // __THROW is redefined to be empty by device_functions_decls.h in CUDA. Clang's
 // counterpart does not do it, so we need to make it empty here to keep
 // following CUDA includes happy.
 #undef __THROW
 #define __THROW

 // CUDA 8.0.41 relies on __USE_FAST_MATH__ and __CUDA_PREC_DIV's values.
 // Previous versions used to check whether they are defined or not.
 // CU_DEVICE_INVALID macro is only defined in 8.0.41, so we use it
 // here to detect the switch.

 #if defined(CU_DEVICE_INVALID)
 #if !defined(__USE_FAST_MATH__)
 #define __USE_FAST_MATH__ 0
 #endif

 #if !defined(__CUDA_PREC_DIV)
 #define __CUDA_PREC_DIV 0
 #endif
 #endif

 // Temporarily poison __host__ macro to ensure it's not used by any of
 // the headers we're about to include.
 #pragma push_macro("__host__")
 #define __host__ UNEXPECTED_HOST_ATTRIBUTE

 // device_functions.hpp and math_functions*.hpp use 'static
 // __forceinline__' (with no __device__) for definitions of device
 // functions. Temporarily redefine __forceinline__ to include
 // __device__.
 #pragma push_macro("__forceinline__")
 #define __forceinline__ __device__ __inline__ __attribute__((always_inline))
 #if CUDA_VERSION < 9000
 #include "device_functions.hpp"
 #endif

 // math_function.hpp uses the __USE_FAST_MATH__ macro to determine whether we
 // get the slow-but-accurate or fast-but-inaccurate versions of functions like
 // sin and exp.  This is controlled in clang by -fcuda-approx-transcendentals.
 //
 // device_functions.hpp uses __USE_FAST_MATH__ for a different purpose (fast vs.
 // slow divides), so we need to scope our define carefully here.
 #pragma push_macro("__USE_FAST_MATH__")
 #if defined(__CLANG_CUDA_APPROX_TRANSCENDENTALS__)
 #define __USE_FAST_MATH__ 1
 #endif

 #if CUDA_VERSION >= 9000
 #include "crt/math_functions.hpp"
 #else
 #include "math_functions.hpp"
 #endif

 #pragma pop_macro("__USE_FAST_MATH__")

 #if CUDA_VERSION < 9000
 #include "math_functions_dbl_ptx3.hpp"
 #endif
 #pragma pop_macro("__forceinline__")

 // Pull in host-only functions that are only available when neither
 // __CUDACC__ nor __CUDABE__ are defined.
 #undef __MATH_FUNCTIONS_HPP__
 #undef __CUDABE__
 #if CUDA_VERSION < 9000
 #include "math_functions.hpp"
 #endif
 // Alas, additional overloads for these functions are hard to get to.
 // Considering that we only need these overloads for a few functions,
 // we can provide them here.
 static inline float rsqrt(float __a) { return rsqrtf(__a); }
 static inline float rcbrt(float __a) { return rcbrtf(__a); }
 static inline float sinpi(float __a) { return sinpif(__a); }
 static inline float cospi(float __a) { return cospif(__a); }
 static inline void sincospi(float __a, float *__b, float *__c) {
   return sincospif(__a, __b, __c);
 }
 static inline float erfcinv(float __a) { return erfcinvf(__a); }
 static inline float normcdfinv(float __a) { return normcdfinvf(__a); }
 static inline float normcdf(float __a) { return normcdff(__a); }
 static inline float erfcx(float __a) { return erfcxf(__a); }

 #if CUDA_VERSION < 9000
 // For some reason single-argument variant is not always declared by
 // CUDA headers. Alas, device_functions.hpp included below needs it.
 static inline __device__ void __brkpt(int __c) { __brkpt(); }
 #endif

 // Now include *.hpp with definitions of various GPU functions.  Alas,
 // a lot of thins get declared/defined with __host__ attribute which
 // we don't want and we have to define it out. We also have to include
 // {device,math}_functions.hpp again in order to extract the other
 // branch of #if/else inside.
 #define __host__
 #undef __CUDABE__
 #define __CUDACC__
 #if CUDA_VERSION >= 9000
 // Some atomic functions became compiler builtins in CUDA-9 , so we need their
 // declarations.
 #include "device_atomic_functions.h"
 #endif
 #undef __DEVICE_FUNCTIONS_HPP__
 #include "device_atomic_functions.hpp"
 #if CUDA_VERSION >= 9000
 #include "crt/device_functions.hpp"
 #include "crt/device_double_functions.hpp"
 #else
 #include "device_functions.hpp"
 #define __CUDABE__
 #include "device_double_functions.h"
 #undef __CUDABE__
 #endif
 #include "sm_20_atomic_functions.hpp"
 // Predicate functions used in `__builtin_assume` need to have no side effect.
 // However, sm_20_intrinsics.hpp doesn't define them with neither pure nor
 // const attribute. Rename definitions from sm_20_intrinsics.hpp and re-define
 // them as pure ones.
 #pragma push_macro("__isGlobal")
 #pragma push_macro("__isShared")
 #pragma push_macro("__isConstant")
 #pragma push_macro("__isLocal")
 #define __isGlobal __ignored_cuda___isGlobal
 #define __isShared __ignored_cuda___isShared
 #define __isConstant __ignored_cuda___isConstant
 #define __isLocal __ignored_cuda___isLocal
 #include "sm_20_intrinsics.hpp"
 #pragma pop_macro("__isGlobal")
 #pragma pop_macro("__isShared")
 #pragma pop_macro("__isConstant")
 #pragma pop_macro("__isLocal")
 #pragma push_macro("__DEVICE__")
 #define __DEVICE__ static __device__ __forceinline__ __attribute__((const))
 __DEVICE__ unsigned int __isGlobal(const void *p) {
   return __nvvm_isspacep_global(p);
 }
 __DEVICE__ unsigned int __isShared(const void *p) {
   return __nvvm_isspacep_shared(p);
 }
 __DEVICE__ unsigned int __isConstant(const void *p) {
   return __nvvm_isspacep_const(p);
 }
 __DEVICE__ unsigned int __isLocal(const void *p) {
   return __nvvm_isspacep_local(p);
 }
 #pragma pop_macro("__DEVICE__")
 #include "sm_32_atomic_functions.hpp"

 // Don't include sm_30_intrinsics.h and sm_32_intrinsics.h.  These define the
 // __shfl and __ldg intrinsics using inline (volatile) asm, but we want to
 // define them using builtins so that the optimizer can reason about and across
 // these instructions.  In particular, using intrinsics for ldg gets us the
 // [addr+imm] addressing mode, which, although it doesn't actually exist in the
 // hardware, seems to generate faster machine code because ptxas can more easily
 // reason about our code.

 #if CUDA_VERSION >= 8000
 #pragma push_macro("__CUDA_ARCH__")
 #undef __CUDA_ARCH__
 #include "sm_60_atomic_functions.hpp"
 #include "sm_61_intrinsics.hpp"
 #pragma pop_macro("__CUDA_ARCH__")
 #endif

 #undef __MATH_FUNCTIONS_HPP__

 // math_functions.hpp defines ::signbit as a __host__ __device__ function.  This
 // conflicts with libstdc++'s constexpr ::signbit, so we have to rename
 // math_function.hpp's ::signbit.  It's guarded by #undef signbit, but that's
 // conditional on __GNUC__.  :)
 #pragma push_macro("signbit")
 #pragma push_macro("__GNUC__")
 #undef __GNUC__
 #define signbit __ignored_cuda_signbit

 // CUDA-9 omits device-side definitions of some math functions if it sees
 // include guard from math.h wrapper from libstdc++. We have to undo the header
 // guard temporarily to get the definitions we need.
 #pragma push_macro("_GLIBCXX_MATH_H")
 #pragma push_macro("_LIBCPP_VERSION")
 #if CUDA_VERSION >= 9000
 #undef _GLIBCXX_MATH_H
 // We also need to undo another guard that checks for libc++ 3.8+
 #ifdef _LIBCPP_VERSION
 #define _LIBCPP_VERSION 3700
 #endif
 #endif

 #if CUDA_VERSION >= 9000
 #include "crt/math_functions.hpp"
 #else
 #include "math_functions.hpp"
 #endif
 #pragma pop_macro("_GLIBCXX_MATH_H")
 #pragma pop_macro("_LIBCPP_VERSION")
 #pragma pop_macro("__GNUC__")
 #pragma pop_macro("signbit")

 #pragma pop_macro("__host__")

 // __clang_cuda_texture_intrinsics.h must be included first in order to provide
 // implementation for __nv_tex_surf_handler that CUDA's headers depend on.
 // The implementation requires c++11 and only works with CUDA-9 or newer.
 #if __cplusplus >= 201103L && CUDA_VERSION >= 9000
 // clang-format off
 #include <__clang_cuda_texture_intrinsics.h>
 // clang-format on
 #else
 #if CUDA_VERSION >= 9000
 // Provide a hint that texture support needs C++11.
 template <typename T> struct __nv_tex_needs_cxx11 {
   const static bool value = false;
 };
 template <class T>
 __host__ __device__ void __nv_tex_surf_handler(const char *name, T *ptr,
                                                cudaTextureObject_t obj,
                                                float x) {
   _Static_assert(__nv_tex_needs_cxx11<T>::value,
                  "Texture support requires C++11");
 }
 #else
 // Textures in CUDA-8 and older are not supported by clang.There's no
 // convenient way to intercept texture use in these versions, so we can't
 // produce a meaningful error. The source code that attempts to use textures
 // will continue to fail as it does now.
 #endif // CUDA_VERSION
 #endif // __cplusplus >= 201103L && CUDA_VERSION >= 9000
 #include "texture_fetch_functions.h"
 #include "texture_indirect_functions.h"

 // Restore state of __CUDA_ARCH__ and __THROW we had on entry.
 #pragma pop_macro("__CUDA_ARCH__")
 #pragma pop_macro("__THROW")

 // Set up compiler macros expected to be seen during compilation.
 #undef __CUDABE__
 #define __CUDACC__

 extern "C" {
 // Device-side CUDA system calls.
 // http://docs.nvidia.com/cuda/ptx-writers-guide-to-interoperability/index.html#system-calls
 // We need these declarations and wrappers for device-side
 // malloc/free/printf calls to work without relying on
 // -fcuda-disable-target-call-checks option.
 __device__ int vprintf(const char *, const char *);
 __device__ void free(void *) __attribute((nothrow));
 __device__ void *malloc(size_t) __attribute((nothrow)) __attribute__((malloc));

 // __assertfail() used to have a `noreturn` attribute. Unfortunately that
 // contributed to triggering the longstanding bug in ptxas when assert was used
 // in sufficiently convoluted code. See
 // https://bugs.llvm.org/show_bug.cgi?id=27738 for the details.
 __device__ void __assertfail(const char *__message, const char *__file,
                              unsigned __line, const char *__function,
                              size_t __charSize);

 // In order for standard assert() macro on linux to work we need to
 // provide device-side __assert_fail()
 __device__ static inline void __assert_fail(const char *__message,
                                             const char *__file, unsigned __line,
                                             const char *__function) {
   __assertfail(__message, __file, __line, __function, sizeof(char));
 }

 // Clang will convert printf into vprintf, but we still need
 // device-side declaration for it.
 __device__ int printf(const char *, ...);
 } // extern "C"

 // We also need device-side std::malloc and std::free.
 namespace std {
 __device__ static inline void free(void *__ptr) { ::free(__ptr); }
 __device__ static inline void *malloc(size_t __size) {
   return ::malloc(__size);
 }
 } // namespace std

 // Out-of-line implementations from __clang_cuda_builtin_vars.h.  These need to
 // come after we've pulled in the definition of uint3 and dim3.

 __device__ inline __cuda_builtin_threadIdx_t::operator dim3() const {
   return dim3(x, y, z);
 }

 __device__ inline __cuda_builtin_threadIdx_t::operator uint3() const {
   return {x, y, z};
 }

 __device__ inline __cuda_builtin_blockIdx_t::operator dim3() const {
   return dim3(x, y, z);
 }

 __device__ inline __cuda_builtin_blockIdx_t::operator uint3() const {
   return {x, y, z};
 }

 __device__ inline __cuda_builtin_blockDim_t::operator dim3() const {
   return dim3(x, y, z);
 }

 __device__ inline __cuda_builtin_blockDim_t::operator uint3() const {
   return {x, y, z};
 }

 __device__ inline __cuda_builtin_gridDim_t::operator dim3() const {
   return dim3(x, y, z);
 }

 __device__ inline __cuda_builtin_gridDim_t::operator uint3() const {
   return {x, y, z};
 }

 #include <__clang_cuda_cmath.h>
 #include <__clang_cuda_intrinsics.h>
 #include <__clang_cuda_complex_builtins.h>

 // curand_mtgp32_kernel helpfully redeclares blockDim and threadIdx in host
 // mode, giving them their "proper" types of dim3 and uint3.  This is
 // incompatible with the types we give in __clang_cuda_builtin_vars.h.  As as
 // hack, force-include the header (nvcc doesn't include it by default) but
 // redefine dim3 and uint3 to our builtin types.  (Thankfully dim3 and uint3 are
 // only used here for the redeclarations of blockDim and threadIdx.)
 #pragma push_macro("dim3")
 #pragma push_macro("uint3")
 #define dim3 __cuda_builtin_blockDim_t
 #define uint3 __cuda_builtin_threadIdx_t
 #include "curand_mtgp32_kernel.h"
 #pragma pop_macro("dim3")
 #pragma pop_macro("uint3")
 #pragma pop_macro("__USE_FAST_MATH__")
 #pragma pop_macro("__CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__")

 // CUDA runtime uses this undocumented function to access kernel launch
 // configuration. The declaration is in crt/device_functions.h but that file
 // includes a lot of other stuff we don't want. Instead, we'll provide our own
 // declaration for it here.
 #if CUDA_VERSION >= 9020
 extern "C" unsigned __cudaPushCallConfiguration(dim3 gridDim, dim3 blockDim,
                                                 size_t sharedMem = 0,
                                                 void *stream = 0);
 #endif

 #endif // __CUDA__
 #endif // __CLANG_CUDA_RUNTIME_WRAPPER_H__
	/*===---- __clang_cuda_runtime_wrapper.h - CUDA runtime support -------------===
	*
	* 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
	*
	*===-----------------------------------------------------------------------===
	*/

	/*
	* WARNING: This header is intended to be directly -include'd by
	* the compiler and is not supposed to be included by users.
	*
	* CUDA headers are implemented in a way that currently makes it
	* impossible for user code to #include directly when compiling with
	* Clang. They present different view of CUDA-supplied functions
	* depending on where in NVCC's compilation pipeline the headers are
	* included. Neither of these modes provides function definitions with
	* correct attributes, so we use preprocessor to force the headers
	* into a form that Clang can use.
	*
	* Similarly to NVCC which -include's cuda_runtime.h, Clang -include's
	* this file during every CUDA compilation.
	*/

	#ifndef __CLANG_CUDA_RUNTIME_WRAPPER_H__
	#define __CLANG_CUDA_RUNTIME_WRAPPER_H__

	#if defined(__CUDA__) && defined(__clang__)

	// Include some forward declares that must come before cmath.
	#include <__clang_cuda_math_forward_declares.h>

	// Define __CUDACC__ early as libstdc++ standard headers with GNU extensions
	// enabled depend on it to avoid using __float128, which is unsupported in
	// CUDA.
	#define __CUDACC__

	// Include some standard headers to avoid CUDA headers including them
	// while some required macros (like __THROW) are in a weird state.
	#include <cmath>
	#include <cstdlib>
	#include <stdlib.h>
	#include <string.h>
	#undef __CUDACC__

	// Preserve common macros that will be changed below by us or by CUDA
	// headers.
	#pragma push_macro("__THROW")
	#pragma push_macro("__CUDA_ARCH__")

	// WARNING: Preprocessor hacks below are based on specific details of
	// CUDA-7.x headers and are not expected to work with any other
	// version of CUDA headers.
	#include "cuda.h"
	#if !defined(CUDA_VERSION)
	#error "cuda.h did not define CUDA_VERSION"
	#elif CUDA_VERSION < 7000
	#error "Unsupported CUDA version!"
	#endif

	#pragma push_macro("__CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__")
	#if CUDA_VERSION >= 10000
	#define __CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__
	#endif

	// Make largest subset of device functions available during host
	// compilation.
	#ifndef __CUDA_ARCH__
	#define __CUDA_ARCH__ 9999
	#endif

	#include "__clang_cuda_builtin_vars.h"

	// No need for device_launch_parameters.h as __clang_cuda_builtin_vars.h above
	// has taken care of builtin variables declared in the file.
	#define __DEVICE_LAUNCH_PARAMETERS_H__

	// {math,device}_functions.h only have declarations of the
	// functions. We don't need them as we're going to pull in their
	// definitions from .hpp files.
	#define __DEVICE_FUNCTIONS_H__
	#define __MATH_FUNCTIONS_H__
	#define __COMMON_FUNCTIONS_H__
	// device_functions_decls is replaced by __clang_cuda_device_functions.h
	// included below.
	#define __DEVICE_FUNCTIONS_DECLS_H__

	#undef __CUDACC__
	#if CUDA_VERSION < 9000
	#define __CUDABE__
	#else
	#define __CUDACC__
	#define __CUDA_LIBDEVICE__
	#endif
	// Disables definitions of device-side runtime support stubs in
	// cuda_device_runtime_api.h
	#include "host_defines.h"
	#undef __CUDACC__
	#include "driver_types.h"
	#include "host_config.h"

	// Temporarily replace "nv_weak" with weak, so __attribute__((nv_weak)) in
	// cuda_device_runtime_api.h ends up being __attribute__((weak)) which is the
	// functional equivalent of what we need.
	#pragma push_macro("nv_weak")
	#define nv_weak weak
	#undef __CUDABE__
	#undef __CUDA_LIBDEVICE__
	#define __CUDACC__
	#include "cuda_runtime.h"

	#pragma pop_macro("nv_weak")
	#undef __CUDACC__
	#define __CUDABE__

	// CUDA headers use __nvvm_memcpy and __nvvm_memset which Clang does
	// not have at the moment. Emulate them with a builtin memcpy/memset.
	#define __nvvm_memcpy(s, d, n, a) __builtin_memcpy(s, d, n)
	#define __nvvm_memset(d, c, n, a) __builtin_memset(d, c, n)

	#if CUDA_VERSION < 9000
	#include "crt/device_runtime.h"
	#endif
	#include "crt/host_runtime.h"
	// device_runtime.h defines __cxa_* macros that will conflict with
	// cxxabi.h.
	// FIXME: redefine these as __device__ functions.
	#undef __cxa_vec_ctor
	#undef __cxa_vec_cctor
	#undef __cxa_vec_dtor
	#undef __cxa_vec_new
	#undef __cxa_vec_new2
	#undef __cxa_vec_new3
	#undef __cxa_vec_delete2
	#undef __cxa_vec_delete
	#undef __cxa_vec_delete3
	#undef __cxa_pure_virtual

	// math_functions.hpp expects this host function be defined on MacOS, but it
	// ends up not being there because of the games we play here. Just define it
	// ourselves; it's simple enough.
	#ifdef __APPLE__
	inline __host__ double __signbitd(double x) {
	return std::signbit(x);
	}
	#endif

	// CUDA 9.1 no longer provides declarations for libdevice functions, so we need
	// to provide our own.
	#include <__clang_cuda_libdevice_declares.h>

	// Wrappers for many device-side standard library functions, incl. math
	// functions, became compiler builtins in CUDA-9 and have been removed from the
	// CUDA headers. Clang now provides its own implementation of the wrappers.
	#if CUDA_VERSION >= 9000
	#include <__clang_cuda_device_functions.h>
	#include <__clang_cuda_math.h>
	#endif

	// __THROW is redefined to be empty by device_functions_decls.h in CUDA. Clang's
	// counterpart does not do it, so we need to make it empty here to keep
	// following CUDA includes happy.
	#undef __THROW
	#define __THROW

	// CUDA 8.0.41 relies on __USE_FAST_MATH__ and __CUDA_PREC_DIV's values.
	// Previous versions used to check whether they are defined or not.
	// CU_DEVICE_INVALID macro is only defined in 8.0.41, so we use it
	// here to detect the switch.

	#if defined(CU_DEVICE_INVALID)
	#if !defined(__USE_FAST_MATH__)
	#define __USE_FAST_MATH__ 0
	#endif

	#if !defined(__CUDA_PREC_DIV)
	#define __CUDA_PREC_DIV 0
	#endif
	#endif

	// Temporarily poison __host__ macro to ensure it's not used by any of
	// the headers we're about to include.
	#pragma push_macro("__host__")
	#define __host__ UNEXPECTED_HOST_ATTRIBUTE

	// device_functions.hpp and math_functions*.hpp use 'static
	// __forceinline__' (with no __device__) for definitions of device
	// functions. Temporarily redefine __forceinline__ to include
	// __device__.
	#pragma push_macro("__forceinline__")
	#define __forceinline__ __device__ __inline__ __attribute__((always_inline))
	#if CUDA_VERSION < 9000
	#include "device_functions.hpp"
	#endif

	// math_function.hpp uses the __USE_FAST_MATH__ macro to determine whether we
	// get the slow-but-accurate or fast-but-inaccurate versions of functions like
	// sin and exp. This is controlled in clang by -fcuda-approx-transcendentals.
	//
	// device_functions.hpp uses __USE_FAST_MATH__ for a different purpose (fast vs.
	// slow divides), so we need to scope our define carefully here.
	#pragma push_macro("__USE_FAST_MATH__")
	#if defined(__CLANG_CUDA_APPROX_TRANSCENDENTALS__)
	#define __USE_FAST_MATH__ 1
	#endif

	#if CUDA_VERSION >= 9000
	#include "crt/math_functions.hpp"
	#else
	#include "math_functions.hpp"
	#endif

	#pragma pop_macro("__USE_FAST_MATH__")

	#if CUDA_VERSION < 9000
	#include "math_functions_dbl_ptx3.hpp"
	#endif
	#pragma pop_macro("__forceinline__")

	// Pull in host-only functions that are only available when neither
	// __CUDACC__ nor __CUDABE__ are defined.
	#undef __MATH_FUNCTIONS_HPP__
	#undef __CUDABE__
	#if CUDA_VERSION < 9000
	#include "math_functions.hpp"
	#endif
	// Alas, additional overloads for these functions are hard to get to.
	// Considering that we only need these overloads for a few functions,
	// we can provide them here.
	static inline float rsqrt(float __a) { return rsqrtf(__a); }
	static inline float rcbrt(float __a) { return rcbrtf(__a); }
	static inline float sinpi(float __a) { return sinpif(__a); }
	static inline float cospi(float __a) { return cospif(__a); }
	static inline void sincospi(float __a, float __b, float __c) {
	return sincospif(__a, __b, __c);
	}
	static inline float erfcinv(float __a) { return erfcinvf(__a); }
	static inline float normcdfinv(float __a) { return normcdfinvf(__a); }
	static inline float normcdf(float __a) { return normcdff(__a); }
	static inline float erfcx(float __a) { return erfcxf(__a); }

	#if CUDA_VERSION < 9000
	// For some reason single-argument variant is not always declared by
	// CUDA headers. Alas, device_functions.hpp included below needs it.
	static inline __device__ void __brkpt(int __c) { __brkpt(); }
	#endif

	// Now include *.hpp with definitions of various GPU functions. Alas,
	// a lot of thins get declared/defined with __host__ attribute which
	// we don't want and we have to define it out. We also have to include
	// {device,math}_functions.hpp again in order to extract the other
	// branch of #if/else inside.
	#define __host__
	#undef __CUDABE__
	#define __CUDACC__
	#if CUDA_VERSION >= 9000
	// Some atomic functions became compiler builtins in CUDA-9 , so we need their
	// declarations.
	#include "device_atomic_functions.h"
	#endif
	#undef __DEVICE_FUNCTIONS_HPP__
	#include "device_atomic_functions.hpp"
	#if CUDA_VERSION >= 9000
	#include "crt/device_functions.hpp"
	#include "crt/device_double_functions.hpp"
	#else
	#include "device_functions.hpp"
	#define __CUDABE__
	#include "device_double_functions.h"
	#undef __CUDABE__
	#endif
	#include "sm_20_atomic_functions.hpp"
	// Predicate functions used in `__builtin_assume` need to have no side effect.
	// However, sm_20_intrinsics.hpp doesn't define them with neither pure nor
	// const attribute. Rename definitions from sm_20_intrinsics.hpp and re-define
	// them as pure ones.
	#pragma push_macro("__isGlobal")
	#pragma push_macro("__isShared")
	#pragma push_macro("__isConstant")
	#pragma push_macro("__isLocal")
	#define __isGlobal __ignored_cuda___isGlobal
	#define __isShared __ignored_cuda___isShared
	#define __isConstant __ignored_cuda___isConstant
	#define __isLocal __ignored_cuda___isLocal
	#include "sm_20_intrinsics.hpp"
	#pragma pop_macro("__isGlobal")
	#pragma pop_macro("__isShared")
	#pragma pop_macro("__isConstant")
	#pragma pop_macro("__isLocal")
	#pragma push_macro("__DEVICE__")
	#define __DEVICE__ static __device__ __forceinline__ __attribute__((const))
	__DEVICE__ unsigned int __isGlobal(const void *p) {
	return __nvvm_isspacep_global(p);
	}
	__DEVICE__ unsigned int __isShared(const void *p) {
	return __nvvm_isspacep_shared(p);
	}
	__DEVICE__ unsigned int __isConstant(const void *p) {
	return __nvvm_isspacep_const(p);
	}
	__DEVICE__ unsigned int __isLocal(const void *p) {
	return __nvvm_isspacep_local(p);
	}
	#pragma pop_macro("__DEVICE__")
	#include "sm_32_atomic_functions.hpp"

	// Don't include sm_30_intrinsics.h and sm_32_intrinsics.h. These define the
	// __shfl and __ldg intrinsics using inline (volatile) asm, but we want to
	// define them using builtins so that the optimizer can reason about and across
	// these instructions. In particular, using intrinsics for ldg gets us the
	// [addr+imm] addressing mode, which, although it doesn't actually exist in the
	// hardware, seems to generate faster machine code because ptxas can more easily
	// reason about our code.

	#if CUDA_VERSION >= 8000
	#pragma push_macro("__CUDA_ARCH__")
	#undef __CUDA_ARCH__
	#include "sm_60_atomic_functions.hpp"
	#include "sm_61_intrinsics.hpp"
	#pragma pop_macro("__CUDA_ARCH__")
	#endif

	#undef __MATH_FUNCTIONS_HPP__

	// math_functions.hpp defines ::signbit as a __host__ __device__ function. This
	// conflicts with libstdc++'s constexpr ::signbit, so we have to rename
	// math_function.hpp's ::signbit. It's guarded by #undef signbit, but that's
	// conditional on __GNUC__. :)
	#pragma push_macro("signbit")
	#pragma push_macro("__GNUC__")
	#undef __GNUC__
	#define signbit __ignored_cuda_signbit

	// CUDA-9 omits device-side definitions of some math functions if it sees
	// include guard from math.h wrapper from libstdc++. We have to undo the header
	// guard temporarily to get the definitions we need.
	#pragma push_macro("_GLIBCXX_MATH_H")
	#pragma push_macro("_LIBCPP_VERSION")
	#if CUDA_VERSION >= 9000
	#undef _GLIBCXX_MATH_H
	// We also need to undo another guard that checks for libc++ 3.8+
	#ifdef _LIBCPP_VERSION
	#define _LIBCPP_VERSION 3700
	#endif
	#endif

	#if CUDA_VERSION >= 9000
	#include "crt/math_functions.hpp"
	#else
	#include "math_functions.hpp"
	#endif
	#pragma pop_macro("_GLIBCXX_MATH_H")
	#pragma pop_macro("_LIBCPP_VERSION")
	#pragma pop_macro("__GNUC__")
	#pragma pop_macro("signbit")

	#pragma pop_macro("__host__")

	// __clang_cuda_texture_intrinsics.h must be included first in order to provide
	// implementation for __nv_tex_surf_handler that CUDA's headers depend on.
	// The implementation requires c++11 and only works with CUDA-9 or newer.
	#if __cplusplus >= 201103L && CUDA_VERSION >= 9000
	// clang-format off
	#include <__clang_cuda_texture_intrinsics.h>
	// clang-format on
	#else
	#if CUDA_VERSION >= 9000
	// Provide a hint that texture support needs C++11.
	template <typename T> struct __nv_tex_needs_cxx11 {
	const static bool value = false;
	};
	template <class T>
	__host__ __device__ void __nv_tex_surf_handler(const char name, T ptr,
	cudaTextureObject_t obj,
	float x) {
	_Static_assert(__nv_tex_needs_cxx11<T>::value,
	"Texture support requires C++11");
	}
	#else
	// Textures in CUDA-8 and older are not supported by clang.There's no
	// convenient way to intercept texture use in these versions, so we can't
	// produce a meaningful error. The source code that attempts to use textures
	// will continue to fail as it does now.
	#endif // CUDA_VERSION
	#endif // __cplusplus >= 201103L && CUDA_VERSION >= 9000
	#include "texture_fetch_functions.h"
	#include "texture_indirect_functions.h"

	// Restore state of __CUDA_ARCH__ and __THROW we had on entry.
	#pragma pop_macro("__CUDA_ARCH__")
	#pragma pop_macro("__THROW")

	// Set up compiler macros expected to be seen during compilation.
	#undef __CUDABE__
	#define __CUDACC__

	extern "C" {
	// Device-side CUDA system calls.
	// http://docs.nvidia.com/cuda/ptx-writers-guide-to-interoperability/index.html#system-calls
	// We need these declarations and wrappers for device-side
	// malloc/free/printf calls to work without relying on
	// -fcuda-disable-target-call-checks option.
	__device__ int vprintf(const char , const char );
	__device__ void free(void *) __attribute((nothrow));
	__device__ void *malloc(size_t) __attribute((nothrow)) __attribute__((malloc));

	// __assertfail() used to have a `noreturn` attribute. Unfortunately that
	// contributed to triggering the longstanding bug in ptxas when assert was used
	// in sufficiently convoluted code. See
	// https://bugs.llvm.org/show_bug.cgi?id=27738 for the details.
	__device__ void __assertfail(const char __message, const char __file,
	unsigned __line, const char *__function,
	size_t __charSize);

	// In order for standard assert() macro on linux to work we need to
	// provide device-side __assert_fail()
	__device__ static inline void __assert_fail(const char *__message,
	const char *__file, unsigned __line,
	const char *__function) {
	__assertfail(__message, __file, __line, __function, sizeof(char));
	}

	// Clang will convert printf into vprintf, but we still need
	// device-side declaration for it.
	__device__ int printf(const char *, ...);
	} // extern "C"

	// We also need device-side std::malloc and std::free.
	namespace std {
	__device__ static inline void free(void *__ptr) { ::free(__ptr); }
	__device__ static inline void *malloc(size_t __size) {
	return ::malloc(__size);
	}
	} // namespace std

	// Out-of-line implementations from __clang_cuda_builtin_vars.h. These need to
	// come after we've pulled in the definition of uint3 and dim3.

	__device__ inline __cuda_builtin_threadIdx_t::operator dim3() const {
	return dim3(x, y, z);
	}

	__device__ inline __cuda_builtin_threadIdx_t::operator uint3() const {
	return {x, y, z};
	}

	__device__ inline __cuda_builtin_blockIdx_t::operator dim3() const {
	return dim3(x, y, z);
	}

	__device__ inline __cuda_builtin_blockIdx_t::operator uint3() const {
	return {x, y, z};
	}

	__device__ inline __cuda_builtin_blockDim_t::operator dim3() const {
	return dim3(x, y, z);
	}

	__device__ inline __cuda_builtin_blockDim_t::operator uint3() const {
	return {x, y, z};
	}

	__device__ inline __cuda_builtin_gridDim_t::operator dim3() const {
	return dim3(x, y, z);
	}

	__device__ inline __cuda_builtin_gridDim_t::operator uint3() const {
	return {x, y, z};
	}

	#include <__clang_cuda_cmath.h>
	#include <__clang_cuda_intrinsics.h>
	#include <__clang_cuda_complex_builtins.h>

	// curand_mtgp32_kernel helpfully redeclares blockDim and threadIdx in host
	// mode, giving them their "proper" types of dim3 and uint3. This is
	// incompatible with the types we give in __clang_cuda_builtin_vars.h. As as
	// hack, force-include the header (nvcc doesn't include it by default) but
	// redefine dim3 and uint3 to our builtin types. (Thankfully dim3 and uint3 are
	// only used here for the redeclarations of blockDim and threadIdx.)
	#pragma push_macro("dim3")
	#pragma push_macro("uint3")
	#define dim3 __cuda_builtin_blockDim_t
	#define uint3 __cuda_builtin_threadIdx_t
	#include "curand_mtgp32_kernel.h"
	#pragma pop_macro("dim3")
	#pragma pop_macro("uint3")
	#pragma pop_macro("__USE_FAST_MATH__")
	#pragma pop_macro("__CUDA_INCLUDE_COMPILER_INTERNAL_HEADERS__")

	// CUDA runtime uses this undocumented function to access kernel launch
	// configuration. The declaration is in crt/device_functions.h but that file
	// includes a lot of other stuff we don't want. Instead, we'll provide our own
	// declaration for it here.
	#if CUDA_VERSION >= 9020
	extern "C" unsigned __cudaPushCallConfiguration(dim3 gridDim, dim3 blockDim,
	size_t sharedMem = 0,
	void *stream = 0);
	#endif

	#endif // __CUDA__
	#endif // __CLANG_CUDA_RUNTIME_WRAPPER_H__