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#include "precomp.hpp"
using namespace cv;
using namespace cv::gpu;
#if !defined (HAVE_CUDA)
void cv::gpu::cvtColor(const GpuMat&, GpuMat&, int, int) { throw_nogpu(); }
void cv::gpu::cvtColor(const GpuMat&, GpuMat&, int, int, const Stream&) { throw_nogpu(); }
#else /* !defined (HAVE_CUDA) */
namespace cv { namespace gpu { namespace color
{
void RGB2RGB_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream);
void RGB2RGB_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream);
void RGB2RGB_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream);
void RGB5x52RGB_gpu(const DevMem2D& src, int green_bits, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream);
void RGB2RGB5x5_gpu(const DevMem2D& src, int srccn, const DevMem2D& dst, int green_bits, int bidx, cudaStream_t stream);
void Gray2RGB_gpu_8u(const DevMem2D& src, const DevMem2D& dst, int dstcn, cudaStream_t stream);
void Gray2RGB_gpu_16u(const DevMem2D& src, const DevMem2D& dst, int dstcn, cudaStream_t stream);
void Gray2RGB_gpu_32f(const DevMem2D& src, const DevMem2D& dst, int dstcn, cudaStream_t stream);
void Gray2RGB5x5_gpu(const DevMem2D& src, const DevMem2D& dst, int green_bits, cudaStream_t stream);
void RGB2Gray_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int bidx, cudaStream_t stream);
void RGB2Gray_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int bidx, cudaStream_t stream);
void RGB2Gray_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int bidx, cudaStream_t stream);
void RGB5x52Gray_gpu(const DevMem2D& src, int green_bits, const DevMem2D& dst, cudaStream_t stream);
void RGB2YCrCb_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void RGB2YCrCb_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void RGB2YCrCb_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void YCrCb2RGB_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void YCrCb2RGB_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void YCrCb2RGB_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, const void* coeffs, cudaStream_t stream);
void RGB2XYZ_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void RGB2XYZ_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void RGB2XYZ_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void XYZ2RGB_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void XYZ2RGB_gpu_16u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void XYZ2RGB_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
void RGB2HSV_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void RGB2HSV_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void HSV2RGB_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void HSV2RGB_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void RGB2HLS_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void RGB2HLS_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void HLS2RGB_gpu_8u(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
void HLS2RGB_gpu_32f(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, int hrange, cudaStream_t stream);
}}}
namespace
{
#undef R2Y
#undef G2Y
#undef B2Y
enum
{
yuv_shift = 14,
xyz_shift = 12,
R2Y = 4899,
G2Y = 9617,
B2Y = 1868,
BLOCK_SIZE = 256
};
}
namespace
{
void cvtColor_caller(const GpuMat& src, GpuMat& dst, int code, int dcn, const cudaStream_t& stream)
{
Size sz = src.size();
int scn = src.channels(), depth = src.depth(), bidx;
CV_Assert(depth == CV_8U || depth == CV_16U || depth == CV_32F);
switch (code)
{
case CV_BGR2BGRA: case CV_RGB2BGRA: case CV_BGRA2BGR:
case CV_RGBA2BGR: case CV_RGB2BGR: case CV_BGRA2RGBA:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx, cudaStream_t stream);
static const func_t funcs[] = {color::RGB2RGB_gpu_8u, 0, color::RGB2RGB_gpu_16u, 0, 0, color::RGB2RGB_gpu_32f};
CV_Assert(scn == 3 || scn == 4);
dcn = code == CV_BGR2BGRA || code == CV_RGB2BGRA || code == CV_BGRA2RGBA ? 4 : 3;
bidx = code == CV_BGR2BGRA || code == CV_BGRA2BGR ? 0 : 2;
dst.create(sz, CV_MAKETYPE(depth, dcn));
funcs[depth](src, scn, dst, dcn, bidx, stream);
break;
}
case CV_BGR2BGR565: case CV_BGR2BGR555: case CV_RGB2BGR565: case CV_RGB2BGR555:
case CV_BGRA2BGR565: case CV_BGRA2BGR555: case CV_RGBA2BGR565: case CV_RGBA2BGR555:
{
CV_Assert((scn == 3 || scn == 4) && depth == CV_8U);
int green_bits = code == CV_BGR2BGR565 || code == CV_RGB2BGR565
|| code == CV_BGRA2BGR565 || code == CV_RGBA2BGR565 ? 6 : 5;
bidx = code == CV_BGR2BGR565 || code == CV_BGR2BGR555
|| code == CV_BGRA2BGR565 || code == CV_BGRA2BGR555 ? 0 : 2;
dst.create(sz, CV_8UC2);
color::RGB2RGB5x5_gpu(src, scn, dst, green_bits, bidx, stream);
break;
}
case CV_BGR5652BGR: case CV_BGR5552BGR: case CV_BGR5652RGB: case CV_BGR5552RGB:
case CV_BGR5652BGRA: case CV_BGR5552BGRA: case CV_BGR5652RGBA: case CV_BGR5552RGBA:
{
if (dcn <= 0) dcn = 3;
CV_Assert((dcn == 3 || dcn == 4) && scn == 2 && depth == CV_8U);
int green_bits = code == CV_BGR5652BGR || code == CV_BGR5652RGB
|| code == CV_BGR5652BGRA || code == CV_BGR5652RGBA ? 6 : 5;
bidx = code == CV_BGR5652BGR || code == CV_BGR5552BGR
|| code == CV_BGR5652BGRA || code == CV_BGR5552BGRA ? 0 : 2;
dst.create(sz, CV_MAKETYPE(depth, dcn));
color::RGB5x52RGB_gpu(src, green_bits, dst, dcn, bidx, stream);
break;
}
case CV_BGR2GRAY: case CV_BGRA2GRAY: case CV_RGB2GRAY: case CV_RGBA2GRAY:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int bidx, cudaStream_t stream);
static const func_t funcs[] = {color::RGB2Gray_gpu_8u, 0, color::RGB2Gray_gpu_16u, 0, 0, color::RGB2Gray_gpu_32f};
CV_Assert(scn == 3 || scn == 4);
bidx = code == CV_BGR2GRAY || code == CV_BGRA2GRAY ? 0 : 2;
dst.create(sz, CV_MAKETYPE(depth, 1));
funcs[depth](src, scn, dst, bidx, stream);
break;
}
case CV_BGR5652GRAY: case CV_BGR5552GRAY:
{
CV_Assert(scn == 2 && depth == CV_8U);
int green_bits = code == CV_BGR5652GRAY ? 6 : 5;
dst.create(sz, CV_8UC1);
color::RGB5x52Gray_gpu(src, green_bits, dst, stream);
break;
}
case CV_GRAY2BGR: case CV_GRAY2BGRA:
{
typedef void (*func_t)(const DevMem2D& src, const DevMem2D& dst, int dstcn, cudaStream_t stream);
static const func_t funcs[] = {color::Gray2RGB_gpu_8u, 0, color::Gray2RGB_gpu_16u, 0, 0, color::Gray2RGB_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert(scn == 1 && (dcn == 3 || dcn == 4));
dst.create(sz, CV_MAKETYPE(depth, dcn));
funcs[depth](src, dst, dcn, stream);
break;
}
case CV_GRAY2BGR565: case CV_GRAY2BGR555:
{
CV_Assert(scn == 1 && depth == CV_8U);
int green_bits = code == CV_GRAY2BGR565 ? 6 : 5;
dst.create(sz, CV_8UC2);
color::Gray2RGB5x5_gpu(src, dst, green_bits, stream);
break;
}
case CV_BGR2YCrCb: case CV_RGB2YCrCb:
case CV_BGR2YUV: case CV_RGB2YUV:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx,
const void* coeffs, cudaStream_t stream);
static const func_t funcs[] = {color::RGB2YCrCb_gpu_8u, 0, color::RGB2YCrCb_gpu_16u, 0, 0, color::RGB2YCrCb_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4));
bidx = code == CV_BGR2YCrCb || code == CV_RGB2YUV ? 0 : 2;
static const float yuv_f[] = { 0.114f, 0.587f, 0.299f, 0.492f, 0.877f };
static const int yuv_i[] = { B2Y, G2Y, R2Y, 8061, 14369 };
static const float YCrCb_f[] = {0.299f, 0.587f, 0.114f, 0.713f, 0.564f};
static const int YCrCb_i[] = {R2Y, G2Y, B2Y, 11682, 9241};
float coeffs_f[5];
int coeffs_i[5];
::memcpy(coeffs_f, code == CV_BGR2YCrCb || code == CV_RGB2YCrCb ? YCrCb_f : yuv_f, sizeof(yuv_f));
::memcpy(coeffs_i, code == CV_BGR2YCrCb || code == CV_RGB2YCrCb ? YCrCb_i : yuv_i, sizeof(yuv_i));
if (bidx == 0)
{
std::swap(coeffs_f[0], coeffs_f[2]);
std::swap(coeffs_i[0], coeffs_i[2]);
}
dst.create(sz, CV_MAKETYPE(depth, dcn));
const void* coeffs = depth == CV_32F ? (void*)coeffs_f : (void*)coeffs_i;
funcs[depth](src, scn, dst, dcn, bidx, coeffs, stream);
break;
}
case CV_YCrCb2BGR: case CV_YCrCb2RGB:
case CV_YUV2BGR: case CV_YUV2RGB:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx,
const void* coeffs, cudaStream_t stream);
static const func_t funcs[] = {color::YCrCb2RGB_gpu_8u, 0, color::YCrCb2RGB_gpu_16u, 0, 0, color::YCrCb2RGB_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4));
bidx = code == CV_YCrCb2BGR || code == CV_YUV2RGB ? 0 : 2;
static const float yuv_f[] = { 2.032f, -0.395f, -0.581f, 1.140f };
static const int yuv_i[] = { 33292, -6472, -9519, 18678 };
static const float YCrCb_f[] = {1.403f, -0.714f, -0.344f, 1.773f};
static const int YCrCb_i[] = {22987, -11698, -5636, 29049};
const float* coeffs_f = code == CV_YCrCb2BGR || code == CV_YCrCb2RGB ? YCrCb_f : yuv_f;
const int* coeffs_i = code == CV_YCrCb2BGR || code == CV_YCrCb2RGB ? YCrCb_i : yuv_i;
dst.create(sz, CV_MAKETYPE(depth, dcn));
const void* coeffs = depth == CV_32F ? (void*)coeffs_f : (void*)coeffs_i;
funcs[depth](src, scn, dst, dcn, bidx, coeffs, stream);
break;
}
case CV_BGR2XYZ: case CV_RGB2XYZ:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn,
const void* coeffs, cudaStream_t stream);
static const func_t funcs[] = {color::RGB2XYZ_gpu_8u, 0, color::RGB2XYZ_gpu_16u, 0, 0, color::RGB2XYZ_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4));
bidx = code == CV_BGR2XYZ ? 0 : 2;
static const float RGB2XYZ_D65f[] =
{
0.412453f, 0.357580f, 0.180423f,
0.212671f, 0.715160f, 0.072169f,
0.019334f, 0.119193f, 0.950227f
};
static const int RGB2XYZ_D65i[] =
{
1689, 1465, 739,
871, 2929, 296,
79, 488, 3892
};
float coeffs_f[9];
int coeffs_i[9];
::memcpy(coeffs_f, RGB2XYZ_D65f, sizeof(RGB2XYZ_D65f));
::memcpy(coeffs_i, RGB2XYZ_D65i, sizeof(RGB2XYZ_D65i));
if (bidx == 0)
{
std::swap(coeffs_f[0], coeffs_f[2]);
std::swap(coeffs_f[3], coeffs_f[5]);
std::swap(coeffs_f[6], coeffs_f[8]);
std::swap(coeffs_i[0], coeffs_i[2]);
std::swap(coeffs_i[3], coeffs_i[5]);
std::swap(coeffs_i[6], coeffs_i[8]);
}
dst.create(sz, CV_MAKETYPE(depth, dcn));
const void* coeffs = depth == CV_32F ? (void*)coeffs_f : (void*)coeffs_i;
funcs[depth](src, scn, dst, dcn, coeffs, stream);
break;
}
case CV_XYZ2BGR: case CV_XYZ2RGB:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, const void* coeffs, cudaStream_t stream);
static const func_t funcs[] = {color::XYZ2RGB_gpu_8u, 0, color::XYZ2RGB_gpu_16u, 0, 0, color::XYZ2RGB_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4));
bidx = code == CV_XYZ2BGR ? 0 : 2;
static const float XYZ2sRGB_D65f[] =
{
3.240479f, -1.53715f, -0.498535f,
-0.969256f, 1.875991f, 0.041556f,
0.055648f, -0.204043f, 1.057311f
};
static const int XYZ2sRGB_D65i[] =
{
13273, -6296, -2042,
-3970, 7684, 170,
228, -836, 4331
};
float coeffs_f[9];
int coeffs_i[9];
::memcpy(coeffs_f, XYZ2sRGB_D65f, sizeof(XYZ2sRGB_D65f));
::memcpy(coeffs_i, XYZ2sRGB_D65i, sizeof(XYZ2sRGB_D65i));
if (bidx == 0)
{
std::swap(coeffs_f[0], coeffs_f[6]);
std::swap(coeffs_f[1], coeffs_f[7]);
std::swap(coeffs_f[2], coeffs_f[8]);
std::swap(coeffs_i[0], coeffs_i[6]);
std::swap(coeffs_i[1], coeffs_i[7]);
std::swap(coeffs_i[2], coeffs_i[8]);
}
dst.create(sz, CV_MAKETYPE(depth, dcn));
//const void* coeffs = depth == CV_32F ? (void*)coeffs_f : (void*)coeffs_i;
funcs[depth](src, scn, dst, dcn, coeffs_i, stream);
break;
}
case CV_BGR2HSV: case CV_RGB2HSV: case CV_BGR2HSV_FULL: case CV_RGB2HSV_FULL:
case CV_BGR2HLS: case CV_RGB2HLS: case CV_BGR2HLS_FULL: case CV_RGB2HLS_FULL:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx,
int hrange, cudaStream_t stream);
static const func_t funcs_hsv[] = {color::RGB2HSV_gpu_8u, 0, 0, 0, 0, color::RGB2HSV_gpu_32f};
static const func_t funcs_hls[] = {color::RGB2HLS_gpu_8u, 0, 0, 0, 0, color::RGB2HLS_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4) && (depth == CV_8U || depth == CV_32F));
bidx = code == CV_BGR2HSV || code == CV_BGR2HLS ||
code == CV_BGR2HSV_FULL || code == CV_BGR2HLS_FULL ? 0 : 2;
int hrange = depth == CV_32F ? 360 : code == CV_BGR2HSV || code == CV_RGB2HSV ||
code == CV_BGR2HLS || code == CV_RGB2HLS ? 180 : 255;
dst.create(sz, CV_MAKETYPE(depth, dcn));
if (code == CV_BGR2HSV || code == CV_RGB2HSV || code == CV_BGR2HSV_FULL || code == CV_RGB2HSV_FULL)
funcs_hsv[depth](src, scn, dst, dcn, bidx, hrange, stream);
else
funcs_hls[depth](src, scn, dst, dcn, bidx, hrange, stream);
break;
}
case CV_HSV2BGR: case CV_HSV2RGB: case CV_HSV2BGR_FULL: case CV_HSV2RGB_FULL:
case CV_HLS2BGR: case CV_HLS2RGB: case CV_HLS2BGR_FULL: case CV_HLS2RGB_FULL:
{
typedef void (*func_t)(const DevMem2D& src, int srccn, const DevMem2D& dst, int dstcn, int bidx,
int hrange, cudaStream_t stream);
static const func_t funcs_hsv[] = {color::HSV2RGB_gpu_8u, 0, 0, 0, 0, color::HSV2RGB_gpu_32f};
static const func_t funcs_hls[] = {color::HLS2RGB_gpu_8u, 0, 0, 0, 0, color::HLS2RGB_gpu_32f};
if (dcn <= 0) dcn = 3;
CV_Assert((scn == 3 || scn == 4) && (dcn == 3 || dcn == 4) && (depth == CV_8U || depth == CV_32F));
bidx = code == CV_HSV2BGR || code == CV_HLS2BGR ||
code == CV_HSV2BGR_FULL || code == CV_HLS2BGR_FULL ? 0 : 2;
int hrange = depth == CV_32F ? 360 : code == CV_HSV2BGR || code == CV_HSV2RGB ||
code == CV_HLS2BGR || code == CV_HLS2RGB ? 180 : 255;
dst.create(sz, CV_MAKETYPE(depth, dcn));
if (code == CV_HSV2BGR || code == CV_HSV2RGB || code == CV_HSV2BGR_FULL || code == CV_HSV2RGB_FULL)
funcs_hsv[depth](src, scn, dst, dcn, bidx, hrange, stream);
else
funcs_hls[depth](src, scn, dst, dcn, bidx, hrange, stream);
break;
}
default:
CV_Error( CV_StsBadFlag, "Unknown/unsupported color conversion code" );
}
}
}
void cv::gpu::cvtColor(const GpuMat& src, GpuMat& dst, int code, int dcn)
{
cvtColor_caller(src, dst, code, dcn, 0);
}
void cv::gpu::cvtColor(const GpuMat& src, GpuMat& dst, int code, int dcn, const Stream& stream)
{
cvtColor_caller(src, dst, code, dcn, StreamAccessor::getStream(stream));
}
#endif /* !defined (HAVE_CUDA) */