Esempio n. 1
0
void NamedWindow::showImage3D(Halide::Image<uint8_t> im)
{
	static Halide::Func convert("convertToMat3D");
	static Halide::ImageParam ip(Halide::UInt(8), 3);
	static Halide::Var x, y, c;

	if (!convert.defined())
	{
		convert(c, x, y) = ip(x, y, 2 - c);
		convert.vectorize(x, 4).parallel(y, 4);
	}

	ip.set(im);
	cv::Mat mat(im.height(), im.width(), CV_8UC3, cv::Scalar(0));
	convert.realize(Halide::Buffer(Halide::UInt(8), im.channels(), im.width(), im.height(), 0, mat.data));
	cv::imshow(name, mat);
}
int main(int argc, char **argv) {

    // This program defines a single-stage imaging pipeline that
    // brightens an image.

    // First we'll load the input image we wish to brighten.
    Halide::Image<uint8_t> input = load<uint8_t>("../apps/images/rgb.png");

    // Next we define our Func object that represents our one pipeline
    // stage.
    Halide::Func brighter;

    // Our Func will have three arguments, representing the position
    // in the image and the color channel. Halide treats color
    // channels as an extra dimension of the image.
    Halide::Var x, y, c;

    // Normally we'd probably write the whole function definition on
    // one line. Here we'll break it apart so we can explain what
    // we're doing at every step.

    // For each pixel of the input image.
    Halide::Expr value = input(x, y, c);

    // Cast it to a floating point value.
    value = Halide::cast<float>(value);

    // Multiply it by 1.5 to brighten it. Halide represents real
    // numbers as floats, not doubles, so we stick an 'f' on the end
    // of our constant.
    value = value * 1.5f;

    // Clamp it to be less than 255, so we don't get overflow when we
    // cast it back to an 8-bit unsigned int.
    value = Halide::min(value, 255.0f);

    // Cast it back to an 8-bit unsigned integer.
    value = Halide::cast<uint8_t>(value);

    // Define the function.
    brighter(x, y, c) = value;

    // The equivalent one-liner to all of the above is:
    //
    // brighter(x, y, c) = Halide::cast<uint8_t>(min(input(x, y, c) * 1.5f, 255));
    //
    // In the shorter version:
    // - I skipped the cast to float, because multiplying by 1.5f does
    //   that automatically.
    // - I also used integer constants in clamp, because they get cast
    //   to match the type of the first argument.
    // - I left the Halide:: off clamp. It's unnecessary due to Koenig
    //   lookup.

    // Remember. All we've done so far is build a representation of a
    // Halide program in memory. We haven't actually processed any
    // pixels yet. We haven't even compiled that Halide program yet.

    // So now we'll realize the Func. The size of the output image
    // should match the size of the input image. If we just wanted to
    // brighten a portion of the input image we could request a
    // smaller size. If we request a larger size Halide will throw an
    // error at runtime telling us we're trying to read out of bounds
    // on the input image.
    Halide::Image<uint8_t> output = brighter.realize(input.width(), input.height(), input.channels());

    // Save the output for inspection. It should look like a bright parrot.
    save(output, "brighter.png");

    printf("Success!\n");
    return 0;
}