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WSJT-X/boost/boost/compute/buffer.hpp

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//---------------------------------------------------------------------------//
// 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_BUFFER_HPP
#define BOOST_COMPUTE_BUFFER_HPP
#include <boost/compute/config.hpp>
#include <boost/compute/context.hpp>
#include <boost/compute/exception.hpp>
#include <boost/compute/memory_object.hpp>
#include <boost/compute/detail/get_object_info.hpp>
namespace boost {
namespace compute {
// forward declarations
class command_queue;
/// \class buffer
/// \brief A memory buffer on a compute device.
///
/// The buffer class represents a memory buffer on a compute device.
///
/// Buffers are allocated within a compute context. For example, to allocate
/// a memory buffer for 32 float's:
///
/// \snippet test/test_buffer.cpp constructor
///
/// Once created, data can be copied to and from the buffer using the
/// \c enqueue_*_buffer() methods in the command_queue class. For example, to
/// copy a set of \c int values from the host to the device:
/// \code
/// int data[] = { 1, 2, 3, 4 };
///
/// queue.enqueue_write_buffer(buf, 0, 4 * sizeof(int), data);
/// \endcode
///
/// Also see the copy() algorithm for a higher-level interface to copying data
/// between the host and the device. For a higher-level, dynamically-resizable,
/// type-safe container for data on a compute device, use the vector<T> class.
///
/// Buffer objects have reference semantics. Creating a copy of a buffer
/// object simply creates another reference to the underlying OpenCL memory
/// object. To create an actual copy use the buffer::clone() method.
///
/// \see context, command_queue
class buffer : public memory_object
{
public:
/// Creates a null buffer object.
buffer()
: memory_object()
{
}
/// Creates a buffer object for \p mem. If \p retain is \c true, the
/// reference count for \p mem will be incremented.
explicit buffer(cl_mem mem, bool retain = true)
: memory_object(mem, retain)
{
}
/// Create a new memory buffer in of \p size with \p flags in
/// \p context.
///
/// \see_opencl_ref{clCreateBuffer}
buffer(const context &context,
size_t size,
cl_mem_flags flags = read_write,
void *host_ptr = 0)
{
cl_int error = 0;
m_mem = clCreateBuffer(context,
flags,
(std::max)(size, size_t(1)),
host_ptr,
&error);
if(!m_mem){
BOOST_THROW_EXCEPTION(opencl_error(error));
}
}
/// Creates a new buffer object as a copy of \p other.
buffer(const buffer &other)
: memory_object(other)
{
}
/// Copies the buffer object from \p other to \c *this.
buffer& operator=(const buffer &other)
{
if(this != &other){
memory_object::operator=(other);
}
return *this;
}
#ifndef BOOST_COMPUTE_NO_RVALUE_REFERENCES
/// Move-constructs a new buffer object from \p other.
buffer(buffer&& other) BOOST_NOEXCEPT
: memory_object(std::move(other))
{
}
/// Move-assigns the buffer from \p other to \c *this.
buffer& operator=(buffer&& other) BOOST_NOEXCEPT
{
memory_object::operator=(std::move(other));
return *this;
}
#endif // BOOST_COMPUTE_NO_RVALUE_REFERENCES
/// Destroys the buffer object.
~buffer()
{
}
/// Returns the size of the buffer in bytes.
size_t size() const
{
return get_memory_size();
}
/// \internal_
size_t max_size() const
{
return get_context().get_device().max_memory_alloc_size();
}
/// Returns information about the buffer.
///
/// \see_opencl_ref{clGetMemObjectInfo}
template<class T>
T get_info(cl_mem_info info) const
{
return get_memory_info<T>(info);
}
/// \overload
template<int Enum>
typename detail::get_object_info_type<buffer, Enum>::type
get_info() const;
/// Creates a new buffer with a copy of the data in \c *this. Uses
/// \p queue to perform the copy.
buffer clone(command_queue &queue) const;
#if defined(BOOST_COMPUTE_CL_VERSION_1_1) || defined(BOOST_COMPUTE_DOXYGEN_INVOKED)
/// Creates a new buffer out of this buffer.
/// The new buffer is a sub region of this buffer.
/// \p flags The mem_flags which should be used to create the new buffer
/// \p origin The start index in this buffer
/// \p size The size of the new sub buffer
///
/// \see_opencl_ref{clCreateSubBuffer}
///
/// \opencl_version_warning{1,1}
buffer create_subbuffer(cl_mem_flags flags, size_t origin,
size_t size)
{
BOOST_ASSERT(origin + size <= this->size());
BOOST_ASSERT(origin % (get_context().
get_device().
get_info<CL_DEVICE_MEM_BASE_ADDR_ALIGN>() / 8) == 0);
cl_int error = 0;
cl_buffer_region region = { origin, size };
cl_mem mem = clCreateSubBuffer(m_mem,
flags,
CL_BUFFER_CREATE_TYPE_REGION,
&region,
&error);
if(!mem){
BOOST_THROW_EXCEPTION(opencl_error(error));
}
return buffer(mem, false);
}
#endif // BOOST_COMPUTE_CL_VERSION_1_1
};
/// \internal_ define get_info() specializations for buffer
BOOST_COMPUTE_DETAIL_DEFINE_GET_INFO_SPECIALIZATIONS(buffer,
((cl_mem_object_type, CL_MEM_TYPE))
((cl_mem_flags, CL_MEM_FLAGS))
((size_t, CL_MEM_SIZE))
((void *, CL_MEM_HOST_PTR))
((cl_uint, CL_MEM_MAP_COUNT))
((cl_uint, CL_MEM_REFERENCE_COUNT))
((cl_context, CL_MEM_CONTEXT))
)
#ifdef BOOST_COMPUTE_CL_VERSION_1_1
BOOST_COMPUTE_DETAIL_DEFINE_GET_INFO_SPECIALIZATIONS(buffer,
((cl_mem, CL_MEM_ASSOCIATED_MEMOBJECT))
((size_t, CL_MEM_OFFSET))
)
#endif // BOOST_COMPUTE_CL_VERSION_1_1
namespace detail {
// set_kernel_arg specialization for buffer
template<>
struct set_kernel_arg<buffer>
{
void operator()(kernel &kernel_, size_t index, const buffer &buffer_)
{
kernel_.set_arg(index, buffer_.get());
}
};
} // end detail namespace
} // end compute namespace
} // end boost namespace
#endif // BOOST_COMPUTE_BUFFER_HPP
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