Exemple #1
0
//  Split a MxNx3 image into 3 separate channel matrices.
//  Produce 3 channels if needed
static af_err channel_split(const af_array rgb, const af::dim4 &dims,
                            af_array *outr, af_array *outg, af_array *outb, af_array *outa)
{
    try {
        af_seq idx[4][3] = {{af_span, af_span, {0, 0, 1}},
                            {af_span, af_span, {1, 1, 1}},
                            {af_span, af_span, {2, 2, 1}},
                            {af_span, af_span, {3, 3, 1}}
                           };

        if (dims[2] == 4) {
            AF_CHECK(af_index(outr, rgb, dims.ndims(), idx[0]));
            AF_CHECK(af_index(outg, rgb, dims.ndims(), idx[1]));
            AF_CHECK(af_index(outb, rgb, dims.ndims(), idx[2]));
            AF_CHECK(af_index(outa, rgb, dims.ndims(), idx[3]));
        } else if (dims[2] == 3) {
            AF_CHECK(af_index(outr, rgb, dims.ndims(), idx[0]));
            AF_CHECK(af_index(outg, rgb, dims.ndims(), idx[1]));
            AF_CHECK(af_index(outb, rgb, dims.ndims(), idx[2]));
        } else {
            AF_CHECK(af_index(outr, rgb, dims.ndims(), idx[0]));
        }
    } CATCHALL;
    return AF_SUCCESS;
}
Exemple #2
0
void randnTest<unsigned char>(af::dim4 &dims)
{
    if (noDoubleTests<unsigned char>()) return;

    af_array outArray = 0;
    ASSERT_EQ(AF_ERR_NOT_SUPPORTED, af_randn(&outArray, dims.ndims(), dims.get(), (af_dtype) af::dtype_traits<unsigned char>::af_type));
    if(outArray != 0) af_destroy_array(outArray);
}
Exemple #3
0
void randnTest(af::dim4 &dims)
{
    if (noDoubleTests<T>()) return;

    af_array outArray = 0;
    ASSERT_EQ(AF_SUCCESS, af_randn(&outArray, dims.ndims(), dims.get(), (af_dtype) af::dtype_traits<T>::af_type));
    if(outArray != 0) af_destroy_array(outArray);
}
Exemple #4
0
af_err af_scale(af_array *out, const af_array in, const float scale0, const float scale1,
                const dim_t odim0, const dim_t odim1, const af_interp_type method)
{
    try {
        ArrayInfo i_info = getInfo(in);
        af::dim4 idims = i_info.dims();

        dim_t _odim0 = odim0, _odim1 = odim1;
        float sx, sy;

        if(_odim0 == 0 || _odim1 == 0) {

            DIM_ASSERT(2, scale0 != 0);
            DIM_ASSERT(3, scale1 != 0);

            sx = 1.f / scale0, sy = 1.f / scale1;
            _odim0 = idims[0] / sx;
            _odim1 = idims[1] / sy;

        } else if (scale0 == 0 || scale1 == 0) {

            DIM_ASSERT(4, odim0 != 0);
            DIM_ASSERT(5, odim1 != 0);

            sx = idims[0] / (float)_odim0;
            sy = idims[1] / (float)_odim1;

        } else {

            sx = 1.f / scale0, sy = 1.f / scale1;
        }

        static float trans_mat[6] = {1, 0, 0,
                                     0, 1, 0};
        trans_mat[0] = sx;
        trans_mat[4] = sy;

        static af::dim4 tdims(3, 2, 1, 1);
        af_array t = 0;
        AF_CHECK(af_create_array(&t, trans_mat, tdims.ndims(), tdims.get(), f32));
        AF_CHECK(af_transform(out, in, t, _odim0, _odim1, method, true));
        AF_CHECK(af_release_array(t));
    }
    CATCHALL;
    return AF_SUCCESS;
}
Exemple #5
0
af_err af_translate(af_array *out, const af_array in, const float trans0, const float trans1,
                    const dim_t odim0, const dim_t odim1, const af_interp_type method)
{

    try {
        static float trans_mat[6] = {1, 0, 0,
                                     0, 1, 0};
        trans_mat[2] = trans0;
        trans_mat[5] = trans1;

        static af::dim4 tdims(3, 2, 1, 1);
        af_array t = 0;

        AF_CHECK(af_create_array(&t, trans_mat, tdims.ndims(), tdims.get(), f32));
        AF_CHECK(af_transform(out, in, t, odim0, odim1, method, true));
        AF_CHECK(af_release_array(t));
    }
    CATCHALL;

    return AF_SUCCESS;
}
Exemple #6
0
af_err af_skew(af_array *out, const af_array in, const float skew0, const float skew1,
               const dim_t odim0, const dim_t odim1, const af_interp_type method,
               const bool inverse)
{
    try {
        float tx = std::tan(skew0);
        float ty = std::tan(skew1);

        static float trans_mat[6] = {1, 0, 0,
                                     0, 1, 0};
        trans_mat[1] = ty;
        trans_mat[3] = tx;

        if(inverse) {
            if(tx == 0 || ty == 0) {
                trans_mat[1] = tx;
                trans_mat[3] = ty;
            } else {
                //calc_tranform_inverse(trans_mat);
                //short cut of calc_transform_inverse
                float d = 1.0f / (1.0f - tx * ty);
                trans_mat[0] = d;
                trans_mat[1] = ty * d;
                trans_mat[3] = tx * d;
                trans_mat[4] = d;
            }
        }
        static af::dim4 tdims(3, 2, 1, 1);
        af_array t = 0;
        AF_CHECK(af_create_array(&t, trans_mat, tdims.ndims(), tdims.get(), f32));
        AF_CHECK(af_transform(out, in, t, odim0, odim1, method, true));
        AF_CHECK(af_release_array(t));
    }
    CATCHALL;

    return AF_SUCCESS;
}
 size_t ndims() const                { return dim_size.ndims();      }