Add a temporary variable to reduce the amount of tedious typing.

[movit] / deconvolution_sharpen_effect.frag

uniform vec4 PREFIX(samples)[(R + 1) * (R + 1)];

vec4 FUNCNAME(vec2 tc) {
        // The full matrix has five different symmetry cases, that look like this:
        //
        // D D D C D D D
        // D D D C D D D
        // D D D C D D D
        // B B B A B B B
        // D D D C D D D
        // D D D C D D D
        // D D D C D D D
        //
        // We only store the lower-right part of the matrix:
        //
        // A B B B 
        // C D D D
        // C D D D
        // C D D D

        // Case A: Top-left sample has no symmetry.
        vec4 sum = PREFIX(samples)[0].z * INPUT(tc);

        // Case B: Uppermost samples have left/right symmetry.
        for (int x = 1; x <= R; ++x) {
                vec4 sample = PREFIX(samples)[x];
                sum += sample.z * (INPUT(tc - sample.xy) + INPUT(tc + sample.xy));
        }

        // Case C: Leftmost samples have top/bottom symmetry.
        for (int y = 1; y <= R; ++y) {
                vec4 sample = PREFIX(samples)[y * (R + 1)];
                sum += sample.z * (INPUT(tc - sample.xy) + INPUT(tc + sample.xy));
        }

        // Case D: All other samples have four-way symmetry.
        // (Actually we have eight-way, but since we are using normalized
        // coordinates, we can't just flip x and y.)
        for (int y = 1; y <= R; ++y) {
                for (int x = 1; x <= R; ++x) {
                        vec4 sample = PREFIX(samples)[y * (R + 1) + x];
                        vec2 mirror_sample = vec2(sample.x, -sample.y);

                        vec4 local_sum = INPUT(tc - sample.xy) + INPUT(tc + sample.xy);
                        local_sum += INPUT(tc - mirror_sample.xy) + INPUT(tc + mirror_sample.xy);
                        sum += sample.z * local_sum;
                }
        }

        return sum;
}