opencv / include /opencv2 /core /cuda /scan.hpp

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	#ifndef OPENCV_CUDA_SCAN_HPP
	#define OPENCV_CUDA_SCAN_HPP

	#include "opencv2/core/cuda/common.hpp"
	#include "opencv2/core/cuda/utility.hpp"
	#include "opencv2/core/cuda/warp.hpp"
	#include "opencv2/core/cuda/warp_shuffle.hpp"

	/** @file
	* @deprecated Use @ref cudev instead.
	*/

	//! @cond IGNORED

	namespace cv { namespace cuda { namespace device
	{
	enum ScanKind { EXCLUSIVE = 0, INCLUSIVE = 1 };

	template <ScanKind Kind, typename T, typename F> struct WarpScan
	{
	__device__ __forceinline__ WarpScan() {}
	__device__ __forceinline__ WarpScan(const WarpScan& other) { CV_UNUSED(other); }

	__device__ __forceinline__ T operator()( volatile T *ptr , const unsigned int idx)
	{
	const unsigned int lane = idx & 31;
	F op;

	if ( lane >= 1) ptr [idx ] = op(ptr [idx - 1], ptr [idx]);
	if ( lane >= 2) ptr [idx ] = op(ptr [idx - 2], ptr [idx]);
	if ( lane >= 4) ptr [idx ] = op(ptr [idx - 4], ptr [idx]);
	if ( lane >= 8) ptr [idx ] = op(ptr [idx - 8], ptr [idx]);
	if ( lane >= 16) ptr [idx ] = op(ptr [idx - 16], ptr [idx]);

	if( Kind == INCLUSIVE )
	return ptr [idx];
	else
	return (lane > 0) ? ptr [idx - 1] : 0;
	}

	__device__ __forceinline__ unsigned int index(const unsigned int tid)
	{
	return tid;
	}

	__device__ __forceinline__ void init(volatile T *ptr){}

	static const int warp_offset = 0;

	typedef WarpScan<INCLUSIVE, T, F> merge;
	};

	template <ScanKind Kind , typename T, typename F> struct WarpScanNoComp
	{
	__device__ __forceinline__ WarpScanNoComp() {}
	__device__ __forceinline__ WarpScanNoComp(const WarpScanNoComp& other) { CV_UNUSED(other); }

	__device__ __forceinline__ T operator()( volatile T *ptr , const unsigned int idx)
	{
	const unsigned int lane = threadIdx.x & 31;
	F op;

	ptr [idx ] = op(ptr [idx - 1], ptr [idx]);
	ptr [idx ] = op(ptr [idx - 2], ptr [idx]);
	ptr [idx ] = op(ptr [idx - 4], ptr [idx]);
	ptr [idx ] = op(ptr [idx - 8], ptr [idx]);
	ptr [idx ] = op(ptr [idx - 16], ptr [idx]);

	if( Kind == INCLUSIVE )
	return ptr [idx];
	else
	return (lane > 0) ? ptr [idx - 1] : 0;
	}

	__device__ __forceinline__ unsigned int index(const unsigned int tid)
	{
	return (tid >> warp_log) * warp_smem_stride + 16 + (tid & warp_mask);
	}

	__device__ __forceinline__ void init(volatile T *ptr)
	{
	ptr[threadIdx.x] = 0;
	}

	static const int warp_smem_stride = 32 + 16 + 1;
	static const int warp_offset = 16;
	static const int warp_log = 5;
	static const int warp_mask = 31;

	typedef WarpScanNoComp<INCLUSIVE, T, F> merge;
	};

	template <ScanKind Kind , typename T, typename Sc, typename F> struct BlockScan
	{
	__device__ __forceinline__ BlockScan() {}
	__device__ __forceinline__ BlockScan(const BlockScan& other) { CV_UNUSED(other); }

	__device__ __forceinline__ T operator()(volatile T *ptr)
	{
	const unsigned int tid = threadIdx.x;
	const unsigned int lane = tid & warp_mask;
	const unsigned int warp = tid >> warp_log;

	Sc scan;
	typename Sc::merge merge_scan;
	const unsigned int idx = scan.index(tid);

	T val = scan(ptr, idx);
	__syncthreads ();

	if( warp == 0)
	scan.init(ptr);
	__syncthreads ();

	if( lane == 31 )
	ptr [scan.warp_offset + warp ] = (Kind == INCLUSIVE) ? val : ptr [idx];
	__syncthreads ();

	if( warp == 0 )
	merge_scan(ptr, idx);
	__syncthreads();

	if ( warp > 0)
	val = ptr [scan.warp_offset + warp - 1] + val;
	__syncthreads ();

	ptr[idx] = val;
	__syncthreads ();

	return val ;
	}

	static const int warp_log = 5;
	static const int warp_mask = 31;
	};

	template <typename T>
	__device__ T warpScanInclusive(T idata, volatile T* s_Data, unsigned int tid)
	{
	#if __CUDA_ARCH__ >= 300
	const unsigned int laneId = cv::cuda::device::Warp::laneId();

	// scan on shuffl functions
	#pragma unroll
	for (int i = 1; i <= (OPENCV_CUDA_WARP_SIZE / 2); i *= 2)
	{
	const T n = cv::cuda::device::shfl_up(idata, i);
	if (laneId >= i)
	idata += n;
	}

	return idata;
	#else
	unsigned int pos = 2 * tid - (tid & (OPENCV_CUDA_WARP_SIZE - 1));
	s_Data[pos] = 0;
	pos += OPENCV_CUDA_WARP_SIZE;
	s_Data[pos] = idata;

	s_Data[pos] += s_Data[pos - 1];
	s_Data[pos] += s_Data[pos - 2];
	s_Data[pos] += s_Data[pos - 4];
	s_Data[pos] += s_Data[pos - 8];
	s_Data[pos] += s_Data[pos - 16];

	return s_Data[pos];
	#endif
	}

	template <typename T>
	__device__ __forceinline__ T warpScanExclusive(T idata, volatile T* s_Data, unsigned int tid)
	{
	return warpScanInclusive(idata, s_Data, tid) - idata;
	}

	template <int tiNumScanThreads, typename T>
	__device__ T blockScanInclusive(T idata, volatile T* s_Data, unsigned int tid)
	{
	if (tiNumScanThreads > OPENCV_CUDA_WARP_SIZE)
	{
	//Bottom-level inclusive warp scan
	T warpResult = warpScanInclusive(idata, s_Data, tid);

	//Save top elements of each warp for exclusive warp scan
	//sync to wait for warp scans to complete (because s_Data is being overwritten)
	__syncthreads();
	if ((tid & (OPENCV_CUDA_WARP_SIZE - 1)) == (OPENCV_CUDA_WARP_SIZE - 1))
	{
	s_Data[tid >> OPENCV_CUDA_LOG_WARP_SIZE] = warpResult;
	}

	//wait for warp scans to complete
	__syncthreads();

	if (tid < (tiNumScanThreads / OPENCV_CUDA_WARP_SIZE) )
	{
	//grab top warp elements
	T val = s_Data[tid];
	//calculate exclusive scan and write back to shared memory
	s_Data[tid] = warpScanExclusive(val, s_Data, tid);
	}

	//return updated warp scans with exclusive scan results
	__syncthreads();

	return warpResult + s_Data[tid >> OPENCV_CUDA_LOG_WARP_SIZE];
	}
	else
	{
	return warpScanInclusive(idata, s_Data, tid);
	}
	}
	}}}

	//! @endcond

	#endif // OPENCV_CUDA_SCAN_HPP