Resize, Warp and Filter HAL API functions are implemented as immediate mode OpenVX calls

2025-08-06 14:36:36 +08:00 · 2016-08-31 17:10:45 +03:00 · 2016-08-31 17:10:45 +03:00 · c9229f7543
commit c9229f7543
parent 4170c97984
1 changed files with 301 additions and 5 deletions
--- a/3rdparty/openvx/include/openvx_hal.hpp
+++ b/3rdparty/openvx/include/openvx_hal.hpp
@ -7,6 +7,7 @@
 #include "VX/vxu.h"
 #include <string>
 #include <vector>
 //==================================================================================================
 // utility
@ -52,7 +53,8 @@ template <typename T>
 struct VX_Traits
 {
    enum {
-        Type = 0
+        ImgType = 0,
        DataType = 0
    };
 };
@ -60,7 +62,8 @@ template <>
 struct VX_Traits<uchar>
 {
    enum {
-        Type = VX_DF_IMAGE_U8
+        ImgType = VX_DF_IMAGE_U8,
        DataType = VX_TYPE_UINT8
    };
 };
@ -68,7 +71,8 @@ template <>
 struct VX_Traits<ushort>
 {
    enum {
-        Type = VX_DF_IMAGE_U16
+        ImgType = VX_DF_IMAGE_U16,
        DataType = VX_TYPE_UINT16
    };
 };
@ -76,7 +80,17 @@ template <>
 struct VX_Traits<short>
 {
    enum {
-        Type = VX_DF_IMAGE_S16
+        ImgType = VX_DF_IMAGE_S16,
        DataType = VX_TYPE_INT16
    };
 };
 template <>
 struct VX_Traits<float>
 {
    enum {
        ImgType = 0,
        DataType = VX_TYPE_FLOAT32
    };
 };
@ -108,6 +122,14 @@ struct vxErr
    {
        vxErr(vxGetStatus((vx_reference)img), "image check").check();
    }
    static void check(vx_matrix mtx)
    {
        vxErr(vxGetStatus((vx_reference)mtx), "matrix check").check();
    }
    static void check(vx_convolution cnv)
    {
        vxErr(vxGetStatus((vx_reference)cnv), "convolution check").check();
    }
    static void check(vx_status s)
    {
        vxErr(s, "status check").check();
@ -151,7 +173,7 @@ struct vxImage
        addr.step_x = 1;
        addr.step_y = 1;
        void *ptrs[] = { (void*)data };
-        img = vxCreateImageFromHandle(ctx.ctx, VX_Traits<T>::Type, &addr, ptrs, VX_MEMORY_TYPE_HOST);
+        img = vxCreateImageFromHandle(ctx.ctx, VX_Traits<T>::ImgType, &addr, ptrs, VX_MEMORY_TYPE_HOST);
        vxErr::check(img);
    }
    ~vxImage()
@ -161,6 +183,39 @@ struct vxImage
    }
 };
 struct vxMatrix
 {
    vx_matrix mtx;
    template <typename T>
    vxMatrix(vxContext &ctx, const T *data, int w, int h)
    {
        mtx = vxCreateMatrix(ctx.ctx, VX_Traits<T>::DataType, w, h);
        vxErr::check(mtx);
        vxErr::check(vxCopyMatrix(mtx, data, VX_WRITE_ONLY, VX_MEMORY_TYPE_HOST);
    }
    ~vxMatrix()
    {
        vxReleaseMatrix(&mtx);
    }
 };
 struct vxConvolution
 {
    vx_convolution cnv;
    vxConvolution(vxContext &ctx, const short *data, int w, int h)
    {
        cnv = vxCreateConvolution(ctx.ctx, w, h);
        vxErr::check(cnv);
        vxErr::check(vxCopyConvolutionCoefficients(cnv, (void*)data, VX_WRITE_ONLY, VX_MEMORY_TYPE_HOST);
    }
    ~vxConvolution()
    {
        vxReleaseConvolution(&cnv);
    }
 };
 //==================================================================================================
 // real code starts here
 // ...
@ -213,6 +268,229 @@ inline int ovx_hal_not(const uchar *a, size_t astep, uchar *c, size_t cstep, int
    return CV_HAL_ERROR_OK;
 }
 #if defined OPENCV_IMGPROC_HAL_INTERFACE_H
 #define CV_HAL_INTER_NEAREST 0
 #define CV_HAL_INTER_LINEAR 1
 #define CV_HAL_INTER_CUBIC 2
 #define CV_HAL_INTER_AREA 3
 #define CV_HAL_INTER_LANCZOS4 4
 #define MORPH_ERODE 0
 #define MORPH_DILATE 1
 inline int ovx_hal_resize(int atype, const uchar *a, size_t astep, int aw, int ah, uchar *b, size_t bstep, int bw, int bh, double inv_scale_x, double inv_scale_y, int interpolation)
 {
    try
    {
        vxContext * ctx = vxContext::getContext();
        vxImage ia(*ctx, a, astep, aw, ah);
        vxImage ib(*ctx, b, bstep, bw, bh);
        if(!((atype == CV_8UC1 || atype == CV_8SC1) &&
             inv_scale_x > 0 && inv_scale_y > 0 &&
             (bw - 0.5) / inv_scale_x - 0.5 < aw && (bh - 0.5) / inv_scale_y - 0.5 < ah &&
             (bw + 0.5) / inv_scale_x + 0.5 >= aw && (bh + 0.5) / inv_scale_y + 0.5 >= ah &&
             std::abs(bw / inv_scale_x - aw) < 0.1 && std::abs(bh / inv_scale_y - ah) < 0.1 ))
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad scale").check();
        int mode;
        if (interpolation == CV_HAL_INTER_LINEAR)
            mode = VX_INTERPOLATION_BILINEAR;
        else if (interpolation == CV_HAL_INTER_AREA)
            mode = VX_INTERPOLATION_AREA;
        else if (interpolation == CV_HAL_INTER_NEAREST)
            mode = VX_INTERPOLATION_NEAREST_NEIGHBOR;
        else
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad interpolation mode").check();
        vxErr::check( vxuScaleImage(ctx->ctx, ia.img, ib.img, mode));
    }
    catch (vxErr & e)
    {
        e.print();
        return CV_HAL_ERROR_UNKNOWN;
    }
    return CV_HAL_ERROR_OK;
 }
 inline int ovx_hal_warpAffine(int atype, const uchar *a, size_t astep, int aw, int ah, uchar *b, size_t bstep, int bw, int bh, const double M[6], int interpolation, int, const double*)
 {
    try
    {
        vxContext * ctx = vxContext::getContext();
        vxImage ia(*ctx, a, astep, aw, ah);
        vxImage ib(*ctx, b, bstep, bw, bh);
        if (!(atype == CV_8UC1 || atype == CV_8SC1))
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad input type").check();
        // It make sense to check border mode as well, but it's impossible to set border mode for immediate OpenVX calls
        // So the only supported modes should be UNDEFINED(there is no such for HAL) and probably ISOLATED
        int mode;
        if (interpolation == CV_HAL_INTER_LINEAR)
            mode = VX_INTERPOLATION_BILINEAR;
        else if (interpolation == CV_HAL_INTER_AREA)
            mode = VX_INTERPOLATION_AREA;
        else if (interpolation == CV_HAL_INTER_NEAREST)
            mode = VX_INTERPOLATION_NEAREST_NEIGHBOR;
        else
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad interpolation mode").check();
        vxMatrix mtx(*ctx, std::vector<float>(M, M + 6).data(), 2, 3);
        vxErr::check(vxuWarpAffine(ctx->ctx, ia.img, mtx.mtx, mode, ib.img));
    }
    catch (vxErr & e)
    {
        e.print();
        return CV_HAL_ERROR_UNKNOWN;
    }
    return CV_HAL_ERROR_OK;
 }
 inline int ovx_hal_warpPerspectve(int atype, const uchar *a, size_t astep, int aw, int ah, uchar *b, size_t bstep, int bw, int bh, const double M[9], int interpolation, int, const double*)
 {
    try
    {
        vxContext * ctx = vxContext::getContext();
        vxImage ia(*ctx, a, astep, aw, ah);
        vxImage ib(*ctx, b, bstep, bw, bh);
        if (!(atype == CV_8UC1 || atype == CV_8SC1))
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad input type").check();
        // It make sense to check border mode as well, but it's impossible to set border mode for immediate OpenVX calls
        // So the only supported modes should be UNDEFINED(there is no such for HAL) and probably ISOLATED
        int mode;
        if (interpolation == CV_HAL_INTER_LINEAR)
            mode = VX_INTERPOLATION_BILINEAR;
        else if (interpolation == CV_HAL_INTER_AREA)
            mode = VX_INTERPOLATION_AREA;
        else if (interpolation == CV_HAL_INTER_NEAREST)
            mode = VX_INTERPOLATION_NEAREST_NEIGHBOR;
        else
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad interpolation mode").check();
        vxMatrix mtx(*ctx, std::vector<float>(M, M + 9).data(), 3, 3);
        vxErr::check(vxuWarpAffine(ctx->ctx, ia.img, mtx.mtx, mode, ib.img));
    }
    catch (vxErr & e)
    {
        e.print();
        return CV_HAL_ERROR_UNKNOWN;
    }
    return CV_HAL_ERROR_OK;
 }
 struct cvhalFilter2D;
 struct FilterCtx
 {
    vxConvolution cnv;
    int dst_type;
    FilterCtx(vxContext &ctx, const short *data, int w, int h, int _dst_type) :
        cnv(ctx, data, w, h), dst_type(_dst_type) {}
 };
 inline int ovx_hal_filterInit(cvhalFilter2D **filter_context, uchar *kernel_data, size_t kernel_step, int kernel_type, int kernel_width, int kernel_height,
    int max_width, int max_height, int src_type, int dst_type, int borderType, double delta, int anchor_x, int anchor_y, bool allowSubmatrix, bool allowInplace)
 {
    if (!filter_context || !kernel_data || allowSubmatrix || allowInplace || delta != 0 ||
        src_type != CV_8UC1 || (dst_type != CV_8UC1 && dst_type != CV_16SC1) ||
        kernel_width % 2 == 0 || kernel_height % 2 == 0 || anchor_x != kernel_width / 2 || anchor_y != kernel_height / 2)
        return CV_HAL_ERROR_NOT_IMPLEMENTED;
    // It make sense to check border mode as well, but it's impossible to set border mode for immediate OpenVX calls
    // So the only supported modes should be UNDEFINED(there is no such for HAL) and probably ISOLATED
    vxContext * ctx = vxContext::getContext();
    std::vector<short> data;
    data.reserve(kernel_width*kernel_height);
    switch (kernel_type)
    {
    case CV_8UC1:
        for (int j = 0; j < kernel_height; ++j)
        {
            uchar * row = (uchar*)(kernel_data + kernel_step*j);
            for (int i = 0; i < kernel_width; ++i)
                data.push_back(row[i]);
        }
        break;
    case CV_8SC1:
        for (int j = 0; j < kernel_height; ++j)
        {
            schar * row = (schar*)(kernel_data + kernel_step*j);
            for (int i = 0; i < kernel_width; ++i)
                data.push_back(row[i]);
        }
        break;
    case CV_16SC1:
        for (int j = 0; j < kernel_height; ++j)
        {
            short * row = (short*)(kernel_data + kernel_step*j);
            for (int i = 0; i < kernel_width; ++i)
                data.push_back(row[i]);
        }
    default:
        return CV_HAL_ERROR_NOT_IMPLEMENTED;
    }
    FilterCtx* cnv = new FilterCtx(*ctx, data.data(), kernel_width, kernel_height, dst_type);
    if (!cnv)
        return CV_HAL_ERROR_UNKNOWN;
    *filter_context = (cvhalFilter2D*)(cnv);
    return CV_HAL_ERROR_OK;
 }
 inline int ovx_hal_filterFree(cvhalFilter2D *filter_context)
 {
    if (filter_context)
    {
        delete (FilterCtx*)filter_context;
        return CV_HAL_ERROR_OK;
    }
    else
    {
        return CV_HAL_ERROR_UNKNOWN;
    }
 }
 inline int ovx_hal_filter(cvhalFilter2D *filter_context, uchar *a, size_t astep, uchar *b, size_t bstep, int w, int h, int full_w, int full_h, int offset_x, int offset_y)
 {
    try
    {
        FilterCtx* cnv = (FilterCtx*)filter_context;
        if(cnv)
            vxErr::check(cnv->cnv.cnv);
        else
            vxErr(VX_ERROR_INVALID_PARAMETERS, "Bad HAL context").check();
        vxContext * ctx = vxContext::getContext();
        vxImage ia(*ctx, a, astep, w, h);
        if (cnv->dst_type == CV_16SC1)
        {
            vxImage ib(*ctx, (short*)b, bstep, w, h);
            vxErr::check(vxuConvolve(ctx->ctx, ia.img, cnv->cnv.cnv, ib.img));
        }
        else
        {
            vxImage ib(*ctx, b, bstep, w, h);
            vxErr::check(vxuConvolve(ctx->ctx, ia.img, cnv->cnv.cnv, ib.img));
        }
    }
    catch (vxErr & e)
    {
        e.print();
        return CV_HAL_ERROR_UNKNOWN;
    }
    return CV_HAL_ERROR_OK;
 }
 #endif
 //==================================================================================================
 // functions redefinition
 // ...
@ -245,4 +523,22 @@ inline int ovx_hal_not(const uchar *a, size_t astep, uchar *c, size_t cstep, int
 #undef cv_hal_mul16s
 #define cv_hal_mul16s ovx_hal_mul<short>
 #if defined OPENCV_IMGPROC_HAL_INTERFACE_H
 #undef cv_hal_resize
 #define cv_hal_resize ovx_hal_resize
 #undef cv_hal_warpAffine
 #define cv_hal_warpAffine ovx_hal_warpAffine
 #undef cv_hal_warpPerspective
 #define cv_hal_warpPerspective ovx_hal_warpPerspectve
 #undef cv_hal_filterInit
 #define cv_hal_filterInit ovx_hal_filterInit
 #undef cv_hal_filter
 #define cv_hal_filter ovx_hal_filter
 #undef cv_hal_filterFree
 #define cv_hal_filterFree ovx_hal_filterFree
 #endif
 #endif