Exemple #1
0
func main() {
	var i, j cl.CL_size_t
	// Rows and columns in the input image
	inputFile := "test.png"
	outputFile := "output.png"
	refFile := "ref.png"

	// Homegrown function to read a BMP from file
	inputpixels, imageWidth, imageHeight, err1 := utils.Read_image_data(inputFile)
	if err1 != nil {
		log.Fatal(err1)
		return
	} else {
		fmt.Printf("width=%d, height=%d (%d)\n", imageWidth, imageHeight, inputpixels[0])
	}

	// Output image on the host
	outputpixels := make([]uint16, imageHeight*imageWidth)
	inputImage := make([]float32, imageHeight*imageWidth)
	outputImage := make([]float32, imageHeight*imageWidth)
	refImage := make([]float32, imageHeight*imageWidth)

	for i = 0; i < imageHeight*imageWidth; i++ {
		inputImage[i] = float32(inputpixels[i])
	}

	// 45 degree motion blur
	var filter = [49]float32{0, 0, 0, 0, 0, 0, 0,
		0, 0, 0, 0, 0, 0, 0,
		0, 0, -1, 0, 1, 0, 0,
		0, 0, -2, 0, 2, 0, 0,
		0, 0, -1, 0, 1, 0, 0,
		0, 0, 0, 0, 0, 0, 0,
		0, 0, 0, 0, 0, 0, 0}

	// The convolution filter is 7x7
	filterWidth := cl.CL_size_t(7)
	filterSize := cl.CL_size_t(filterWidth * filterWidth) // Assume a square kernel

	// Set up the OpenCL environment
	var status cl.CL_int

	// Discovery platform
	var platform [1]cl.CL_platform_id
	status = cl.CLGetPlatformIDs(1, platform[:], nil)
	chk(status, "clGetPlatformIDs")

	// Discover device
	var device [1]cl.CL_device_id
	cl.CLGetDeviceIDs(platform[0], cl.CL_DEVICE_TYPE_ALL, 1, device[:], nil)
	chk(status, "clGetDeviceIDs")

	// Create context
	//var props =[3]cl.CL_context_properties{cl.CL_CONTEXT_PLATFORM,
	//    (cl.CL_context_properties)(unsafe.Pointer(&platform[0])), 0};

	var context cl.CL_context
	context = cl.CLCreateContext(nil, 1, device[:], nil, nil, &status)
	chk(status, "clCreateContext")

	// Create command queue
	var queue cl.CL_command_queue
	queue = cl.CLCreateCommandQueue(context, device[0], 0, &status)
	chk(status, "clCreateCommandQueue")

	// The image format describes how the data will be stored in memory
	var format cl.CL_image_format
	format.Image_channel_order = cl.CL_R         // single channel
	format.Image_channel_data_type = cl.CL_FLOAT // float data type

	var desc cl.CL_image_desc
	desc.Image_type = cl.CL_MEM_OBJECT_IMAGE2D
	desc.Image_width = imageWidth
	desc.Image_height = imageHeight
	desc.Image_depth = 0
	desc.Image_array_size = 0
	desc.Image_row_pitch = 0
	desc.Image_slice_pitch = 0
	desc.Num_mip_levels = 0
	desc.Num_samples = 0
	desc.Buffer = cl.CL_mem{}

	// Create space for the source image on the device
	d_inputImage := cl.CLCreateImage(context, cl.CL_MEM_READ_ONLY, &format, &desc,
		nil, &status)
	chk(status, "clCreateImage")

	// Create space for the output image on the device
	d_outputImage := cl.CLCreateImage(context, cl.CL_MEM_WRITE_ONLY, &format, &desc,
		nil, &status)
	chk(status, "clCreateImage")

	// Create space for the 7x7 filter on the device
	d_filter := cl.CLCreateBuffer(context, 0, filterSize*cl.CL_size_t(unsafe.Sizeof(filter[0])),
		nil, &status)
	chk(status, "clCreateBuffer")

	// Copy the source image to the device
	var origin = [3]cl.CL_size_t{0, 0, 0}                                                // Offset within the image to copy from
	var region = [3]cl.CL_size_t{cl.CL_size_t(imageWidth), cl.CL_size_t(imageHeight), 1} // Elements to per dimension
	status = cl.CLEnqueueWriteImage(queue, d_inputImage, cl.CL_FALSE, origin, region,
		0, 0, unsafe.Pointer(&inputImage[0]), 0, nil, nil)
	chk(status, "clEnqueueWriteImage")

	// Copy the 7x7 filter to the device
	status = cl.CLEnqueueWriteBuffer(queue, d_filter, cl.CL_FALSE, 0,
		filterSize*cl.CL_size_t(unsafe.Sizeof(filter[0])), unsafe.Pointer(&filter[0]), 0, nil, nil)
	chk(status, "clEnqueueWriteBuffer")

	// Create the image sampler
	sampler := cl.CLCreateSampler(context, cl.CL_FALSE,
		cl.CL_ADDRESS_CLAMP_TO_EDGE, cl.CL_FILTER_NEAREST, &status)
	chk(status, "clCreateSampler")

	// Create a program object with source and build it
	program := utils.Build_program(context, device[:], "convolution.cl", nil)
	kernel := cl.CLCreateKernel(*program, []byte("convolution"), &status)
	chk(status, "clCreateKernel")

	// Set the kernel arguments
	var w, h, f cl.CL_int
	w = cl.CL_int(imageWidth)
	h = cl.CL_int(imageHeight)
	f = cl.CL_int(filterWidth)
	status = cl.CLSetKernelArg(kernel, 0, cl.CL_size_t(unsafe.Sizeof(d_inputImage)), unsafe.Pointer(&d_inputImage))
	status |= cl.CLSetKernelArg(kernel, 1, cl.CL_size_t(unsafe.Sizeof(d_outputImage)), unsafe.Pointer(&d_outputImage))
	status |= cl.CLSetKernelArg(kernel, 2, cl.CL_size_t(unsafe.Sizeof(h)), unsafe.Pointer(&h))
	status |= cl.CLSetKernelArg(kernel, 3, cl.CL_size_t(unsafe.Sizeof(w)), unsafe.Pointer(&w))
	status |= cl.CLSetKernelArg(kernel, 4, cl.CL_size_t(unsafe.Sizeof(d_filter)), unsafe.Pointer(&d_filter))
	status |= cl.CLSetKernelArg(kernel, 5, cl.CL_size_t(unsafe.Sizeof(f)), unsafe.Pointer(&f))
	status |= cl.CLSetKernelArg(kernel, 6, cl.CL_size_t(unsafe.Sizeof(sampler)), unsafe.Pointer(&sampler))
	chk(status, "clSetKernelArg")

	// Set the work item dimensions
	var globalSize = [2]cl.CL_size_t{imageWidth, imageHeight}
	status = cl.CLEnqueueNDRangeKernel(queue, kernel, 2, nil, globalSize[:], nil, 0,
		nil, nil)
	chk(status, "clEnqueueNDRange")

	// Read the image back to the host
	status = cl.CLEnqueueReadImage(queue, d_outputImage, cl.CL_TRUE, origin,
		region, 0, 0, unsafe.Pointer(&outputImage[0]), 0, nil, nil)
	chk(status, "clEnqueueReadImage")

	// Write the output image to file
	for i = 0; i < imageHeight*imageWidth; i++ {
		outputpixels[i] = uint16(outputImage[i])
	}
	utils.Write_image_data(outputFile, outputpixels, imageWidth, imageHeight)

	// Compute the reference image
	for i = 0; i < imageHeight; i++ {
		for j = 0; j < imageWidth; j++ {
			refImage[i*imageWidth+j] = 0
		}
	}

	// Iterate over the rows of the source image
	halfFilterWidth := filterWidth / 2
	var sum float32
	for i = 0; i < imageHeight; i++ {
		// Iterate over the columns of the source image
		for j = 0; j < imageWidth; j++ {
			sum = 0 // Reset sum for new source pixel
			// Apply the filter to the neighborhood
			for k := -halfFilterWidth; k <= halfFilterWidth; k++ {
				for l := -halfFilterWidth; l <= halfFilterWidth; l++ {
					if i+k >= 0 && i+k < imageHeight &&
						j+l >= 0 && j+l < imageWidth {
						sum += inputImage[(i+k)*imageWidth+j+l] *
							filter[(k+halfFilterWidth)*filterWidth+
								l+halfFilterWidth]
					} else {
						i_k := i + k
						j_l := j + l
						if i+k < 0 {
							i_k = 0
						} else if i+k >= imageHeight {
							i_k = imageHeight - 1
						}
						if j+l < 0 {
							j_l = 0
						} else if j+l >= imageWidth {
							j_l = imageWidth - 1
						}
						sum += inputImage[(i_k)*imageWidth+j_l] *
							filter[(k+halfFilterWidth)*filterWidth+
								l+halfFilterWidth]
					}
				}
			}
			refImage[i*imageWidth+j] = sum
		}
	}
	// Write the ref image to file
	for i = 0; i < imageHeight*imageWidth; i++ {
		outputpixels[i] = uint16(refImage[i])
	}
	utils.Write_image_data(refFile, outputpixels, imageWidth, imageHeight)

	failed := 0
	for i = 0; i < imageHeight; i++ {
		for j = 0; j < imageWidth; j++ {
			if math.Abs(float64(outputImage[i*imageWidth+j]-refImage[i*imageWidth+j])) > 0.01 {
				//fmt.Printf("Results are INCORRECT\n");
				//fmt.Printf("Pixel mismatch at <%d,%d> (%f vs. %f) %f\n", i, j,
				//   outputImage[i*imageWidth+j], refImage[i*imageWidth+j], inputImage[i*imageWidth+j]);
				failed++
			}
		}
	}
	fmt.Printf("Mismatch Pixel number/Total pixel number = %d/%d\n", failed, imageWidth*imageHeight)

	// Free OpenCL resources
	cl.CLReleaseKernel(kernel)
	cl.CLReleaseProgram(*program)
	cl.CLReleaseCommandQueue(queue)
	cl.CLReleaseMemObject(d_inputImage)
	cl.CLReleaseMemObject(d_outputImage)
	cl.CLReleaseMemObject(d_filter)
	cl.CLReleaseSampler(sampler)
	cl.CLReleaseContext(context)
}
Exemple #2
0
func main() {

	/* OpenCL data structures */
	var device []cl.CL_device_id
	var context cl.CL_context
	var queue cl.CL_command_queue
	var program *cl.CL_program
	var kernel cl.CL_kernel
	var err cl.CL_int

	var err1 error
	var global_size [2]cl.CL_size_t

	/* Image data */
	var pixels []uint16
	var png_format cl.CL_image_format
	var input_image, output_image cl.CL_mem
	var origin, region [3]cl.CL_size_t
	var width, height cl.CL_size_t

	/* Open input file and read image data */
	pixels, width, height, err1 = utils.Read_image_data(INPUT_FILE)
	if err1 != nil {
		return
	} else {
		fmt.Printf("width=%d, height=%d", width, height)
	}

	/* Create a device and context */
	device = utils.Create_device()
	context = cl.CLCreateContext(nil, 1, device[:], nil, nil, &err)
	if err < 0 {
		println("Couldn't create a context")
		return
	}

	/* Build the program and create a kernel */
	program = utils.Build_program(context, device[:], PROGRAM_FILE, nil)
	kernel = cl.CLCreateKernel(*program, KERNEL_FUNC, &err)
	if err < 0 {
		fmt.Printf("Couldn't create a kernel: %d", err)
		return
	}

	/* Create image object */
	png_format.Image_channel_order = cl.CL_LUMINANCE
	png_format.Image_channel_data_type = cl.CL_UNORM_INT16
	input_image = cl.CLCreateImage2D(context,
		cl.CL_MEM_READ_ONLY|cl.CL_MEM_COPY_HOST_PTR,
		&png_format, width, height, 0, unsafe.Pointer(&pixels[0]), &err)
	output_image = cl.CLCreateImage2D(context,
		cl.CL_MEM_WRITE_ONLY, &png_format, width, height, 0, nil, &err)
	if err < 0 {
		println("Couldn't create the image object")
		return
	}

	/* Create kernel arguments */
	err = cl.CLSetKernelArg(kernel, 0, cl.CL_size_t(unsafe.Sizeof(input_image)), unsafe.Pointer(&input_image))
	err |= cl.CLSetKernelArg(kernel, 1, cl.CL_size_t(unsafe.Sizeof(output_image)), unsafe.Pointer(&output_image))
	if err < 0 {
		println("Couldn't set a kernel argument")
		return
	}

	/* Create a command queue */
	queue = cl.CLCreateCommandQueue(context, device[0], 0, &err)
	if err < 0 {
		println("Couldn't create a command queue")
		return
	}

	/* Enqueue kernel */
	global_size[0] = width
	global_size[1] = height
	err = cl.CLEnqueueNDRangeKernel(queue, kernel, 2, nil, global_size[:],
		nil, 0, nil, nil)
	if err < 0 {
		println("Couldn't enqueue the kernel")
		return
	}

	/* Read the image object */
	origin[0] = 0
	origin[1] = 0
	origin[2] = 0
	region[0] = width
	region[1] = height
	region[2] = 1
	err = cl.CLEnqueueReadImage(queue, output_image, cl.CL_TRUE, origin,
		region, 0, 0, unsafe.Pointer(&pixels[0]), 0, nil, nil)
	if err < 0 {
		println("Couldn't read from the image object")
		return
	}

	/* Create output PNG file and write data */
	utils.Write_image_data(OUTPUT_FILE, pixels, width, height)

	/* Deallocate resources */
	cl.CLReleaseMemObject(input_image)
	cl.CLReleaseMemObject(output_image)
	cl.CLReleaseKernel(kernel)
	cl.CLReleaseCommandQueue(queue)
	cl.CLReleaseProgram(*program)
	cl.CLReleaseContext(context)

}