boost/compute/kernel.hpp
//---------------------------------------------------------------------------// // Copyright (c) 2013 Kyle Lutz <kyle.r.lutz@gmail.com> // // Distributed under the Boost Software License, Version 1.0 // See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt // // See http://boostorg.github.com/compute for more information. //---------------------------------------------------------------------------// #ifndef BOOST_COMPUTE_KERNEL_HPP #define BOOST_COMPUTE_KERNEL_HPP #include <string> #include <boost/assert.hpp> #include <boost/utility/enable_if.hpp> #include <boost/compute/config.hpp> #include <boost/compute/program.hpp> #include <boost/compute/exception.hpp> #include <boost/compute/type_traits/is_fundamental.hpp> #include <boost/compute/detail/get_object_info.hpp> #include <boost/compute/detail/assert_cl_success.hpp> namespace boost { namespace compute { namespace detail { template<class T> struct set_kernel_arg; } // end detail namespace /// \class kernel /// \brief A compute kernel. /// /// \see command_queue, program class kernel { public: /// Creates a null kernel object. kernel() : m_kernel(0) { } /// Creates a new kernel object for \p kernel. If \p retain is /// \c true, the reference count for \p kernel will be incremented. explicit kernel(cl_kernel kernel, bool retain = true) : m_kernel(kernel) { if(m_kernel && retain){ clRetainKernel(m_kernel); } } /// Creates a new kernel object with \p name from \p program. kernel(const program &program, const std::string &name) { cl_int error = 0; m_kernel = clCreateKernel(program.get(), name.c_str(), &error); if(!m_kernel){ BOOST_THROW_EXCEPTION(opencl_error(error)); } } /// Creates a new kernel object as a copy of \p other. kernel(const kernel &other) : m_kernel(other.m_kernel) { if(m_kernel){ clRetainKernel(m_kernel); } } /// Copies the kernel object from \p other to \c *this. kernel& operator=(const kernel &other) { if(this != &other){ if(m_kernel){ clReleaseKernel(m_kernel); } m_kernel = other.m_kernel; if(m_kernel){ clRetainKernel(m_kernel); } } return *this; } #ifndef BOOST_COMPUTE_NO_RVALUE_REFERENCES /// Move-constructs a new kernel object from \p other. kernel(kernel&& other) BOOST_NOEXCEPT : m_kernel(other.m_kernel) { other.m_kernel = 0; } /// Move-assigns the kernel from \p other to \c *this. kernel& operator=(kernel&& other) BOOST_NOEXCEPT { if(m_kernel){ clReleaseKernel(m_kernel); } m_kernel = other.m_kernel; other.m_kernel = 0; return *this; } #endif // BOOST_COMPUTE_NO_RVALUE_REFERENCES /// Destroys the kernel object. ~kernel() { if(m_kernel){ BOOST_COMPUTE_ASSERT_CL_SUCCESS( clReleaseKernel(m_kernel) ); } } /// Returns a reference to the underlying OpenCL kernel object. cl_kernel& get() const { return const_cast<cl_kernel &>(m_kernel); } /// Returns the function name for the kernel. std::string name() const { return get_info<std::string>(CL_KERNEL_FUNCTION_NAME); } /// Returns the number of arguments for the kernel. size_t arity() const { return get_info<cl_uint>(CL_KERNEL_NUM_ARGS); } /// Returns the program for the kernel. program get_program() const { return program(get_info<cl_program>(CL_KERNEL_PROGRAM)); } /// Returns the context for the kernel. context get_context() const { return context(get_info<cl_context>(CL_KERNEL_CONTEXT)); } /// Returns information about the kernel. /// /// \see_opencl_ref{clGetKernelInfo} template<class T> T get_info(cl_kernel_info info) const { return detail::get_object_info<T>(clGetKernelInfo, m_kernel, info); } /// \overload template<int Enum> typename detail::get_object_info_type<kernel, Enum>::type get_info() const; #if defined(CL_VERSION_1_2) || defined(BOOST_COMPUTE_DOXYGEN_INVOKED) /// Returns information about the argument at \p index. /// /// For example, to get the name of the first argument: /// \code /// std::string arg = kernel.get_arg_info<std::string>(0, CL_KERNEL_ARG_NAME); /// \endcode /// /// Note, this function requires that the program be compiled with the /// \c "-cl-kernel-arg-info" flag. For example: /// \code /// program.build("-cl-kernel-arg-info"); /// \endcode /// /// \opencl_version_warning{1,2} /// /// \see_opencl_ref{clGetKernelArgInfo} template<class T> T get_arg_info(size_t index, cl_kernel_arg_info info) const { return detail::get_object_info<T>( clGetKernelArgInfo, m_kernel, info, static_cast<cl_uint>(index) ); } /// \overload template<int Enum> typename detail::get_object_info_type<kernel, Enum>::type get_arg_info(size_t index) const; #endif // CL_VERSION_1_2 /// Returns work-group information for the kernel with \p device. /// /// \see_opencl_ref{clGetKernelWorkGroupInfo} template<class T> T get_work_group_info(const device &device, cl_kernel_work_group_info info) const { return detail::get_object_info<T>(clGetKernelWorkGroupInfo, m_kernel, info, device.id()); } /// Sets the argument at \p index to \p value with \p size. /// /// \see_opencl_ref{clSetKernelArg} void set_arg(size_t index, size_t size, const void *value) { BOOST_ASSERT(index < arity()); cl_int ret = clSetKernelArg(m_kernel, static_cast<cl_uint>(index), size, value); if(ret != CL_SUCCESS){ BOOST_THROW_EXCEPTION(opencl_error(ret)); } } /// Sets the argument at \p index to \p value. /// /// For built-in types (e.g. \c float, \c int4_), this is equivalent to /// calling set_arg(index, sizeof(type), &value). /// /// Additionally, this method is specialized for device memory objects /// such as buffer and image2d. This allows for them to be passed directly /// without having to extract their underlying cl_mem object. /// /// This method is also specialized for device container types such as /// vector<T> and array<T, N>. This allows for them to be passed directly /// as kernel arguments without having to extract their underlying buffer. /// /// For setting local memory arguments (e.g. "__local float *buf"), the /// local_buffer<T> class may be used: /// \code /// // set argument to a local buffer with storage for 32 float's /// kernel.set_arg(0, local_buffer<float>(32)); /// \endcode template<class T> void set_arg(size_t index, const T &value) { // if you get a compilation error pointing here it means you // attempted to set a kernel argument from an invalid type. detail::set_kernel_arg<T>()(*this, index, value); } /// \internal_ void set_arg(size_t index, const cl_mem mem) { set_arg(index, sizeof(cl_mem), static_cast<const void *>(&mem)); } /// \internal_ void set_arg(size_t index, const cl_sampler sampler) { set_arg(index, sizeof(cl_sampler), static_cast<const void *>(&sampler)); } /// \internal_ void set_arg_svm_ptr(size_t index, void* ptr) { #ifdef CL_VERSION_2_0 cl_int ret = clSetKernelArgSVMPointer(m_kernel, static_cast<cl_uint>(index), ptr); if(ret != CL_SUCCESS){ BOOST_THROW_EXCEPTION(opencl_error(ret)); } #else (void) index; (void) ptr; BOOST_THROW_EXCEPTION(opencl_error(CL_INVALID_ARG_VALUE)); #endif } #ifndef BOOST_COMPUTE_NO_VARIADIC_TEMPLATES /// Sets the arguments for the kernel to \p args. template<class... T> void set_args(T&&... args) { BOOST_ASSERT(sizeof...(T) <= arity()); _set_args<0>(args...); } #endif // BOOST_COMPUTE_NO_VARIADIC_TEMPLATES #if defined(CL_VERSION_2_0) || defined(BOOST_COMPUTE_DOXYGEN_INVOKED) /// Sets additional execution information for the kernel. /// /// \opencl_version_warning{2,0} /// /// \see_opencl2_ref{clSetKernelExecInfo} void set_exec_info(cl_kernel_exec_info info, size_t size, const void *value) { cl_int ret = clSetKernelExecInfo(m_kernel, info, size, value); if(ret != CL_SUCCESS){ BOOST_THROW_EXCEPTION(opencl_error(ret)); } } #endif // CL_VERSION_2_0 /// Returns \c true if the kernel is the same at \p other. bool operator==(const kernel &other) const { return m_kernel == other.m_kernel; } /// Returns \c true if the kernel is different from \p other. bool operator!=(const kernel &other) const { return m_kernel != other.m_kernel; } /// \internal_ operator cl_kernel() const { return m_kernel; } /// \internal_ static kernel create_with_source(const std::string &source, const std::string &name, const context &context) { return program::build_with_source(source, context).create_kernel(name); } private: #ifndef BOOST_COMPUTE_NO_VARIADIC_TEMPLATES /// \internal_ template<size_t N> void _set_args() { } /// \internal_ template<size_t N, class T, class... Args> void _set_args(T&& arg, Args&&... rest) { set_arg(N, arg); _set_args<N+1>(rest...); } #endif // BOOST_COMPUTE_NO_VARIADIC_TEMPLATES private: cl_kernel m_kernel; }; inline kernel program::create_kernel(const std::string &name) const { return kernel(*this, name); } /// \internal_ define get_info() specializations for kernel BOOST_COMPUTE_DETAIL_DEFINE_GET_INFO_SPECIALIZATIONS(kernel, ((std::string, CL_KERNEL_FUNCTION_NAME)) ((cl_uint, CL_KERNEL_NUM_ARGS)) ((cl_uint, CL_KERNEL_REFERENCE_COUNT)) ((cl_context, CL_KERNEL_CONTEXT)) ((cl_program, CL_KERNEL_PROGRAM)) ) #ifdef CL_VERSION_1_2 BOOST_COMPUTE_DETAIL_DEFINE_GET_INFO_SPECIALIZATIONS(kernel, ((std::string, CL_KERNEL_ATTRIBUTES)) ) #endif // CL_VERSION_1_2 /// \internal_ define get_arg_info() specializations for kernel #ifdef CL_VERSION_1_2 #define BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(result_type, value) \ namespace detail { \ template<> struct get_object_info_type<kernel, value> { typedef result_type type; }; \ } \ template<> inline result_type kernel::get_arg_info<value>(size_t index) const { \ return get_arg_info<result_type>(index, value); \ } BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(cl_kernel_arg_address_qualifier, CL_KERNEL_ARG_ADDRESS_QUALIFIER) BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(cl_kernel_arg_access_qualifier, CL_KERNEL_ARG_ACCESS_QUALIFIER) BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(std::string, CL_KERNEL_ARG_TYPE_NAME) BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(cl_kernel_arg_type_qualifier, CL_KERNEL_ARG_TYPE_QUALIFIER) BOOST_COMPUTE_DETAIL_DEFINE_KERNEL_GET_ARG_INFO_SPECIALIZATION(std::string, CL_KERNEL_ARG_NAME) #endif // CL_VERSION_1_2 namespace detail { // set_kernel_arg implementation for built-in types template<class T> struct set_kernel_arg { typename boost::enable_if<is_fundamental<T> >::type operator()(kernel &kernel_, size_t index, const T &value) { kernel_.set_arg(index, sizeof(T), &value); } }; // set_kernel_arg specialization for char (different from built-in cl_char) template<> struct set_kernel_arg<char> { void operator()(kernel &kernel_, size_t index, const char c) { kernel_.set_arg(index, sizeof(char), &c); } }; } // end detail namespace } // end namespace compute } // end namespace boost #endif // BOOST_COMPUTE_KERNEL_HPP