func main() {
var err error
if *help {
fmt.Fprintf(os.Stderr, "Usage of %s:\n", os.Args[0])
flag.PrintDefaults()
return
}
var input io.Reader
if len(*inFilename) == 0 {
input = os.Stdin
} else {
if input, err = os.Open(*inFilename); err != nil {
fatalError(err)
}
}
var output io.Writer
if len(*outFilename) == 0 {
output = os.Stdout
} else {
if output, err = os.Create(*outFilename); err != nil {
fatalError(err)
}
}
var inImage image.Image
var inFormat string
if inImage, inFormat, err = image.Decode(input); err != nil {
fatalError(err)
}
size := inImage.Bounds().Size()
var pixels []uint32
if pixels, err = imagePixels(inImage); err != nil {
fatalError(err)
}
_ = pixels
for _, platform := range cl.Platforms {
for _, dev := range platform.Devices {
var context *cl.Context
var queue *cl.CommandQueue
var sourceImage, destImage *cl.Image
var sampler *cl.Sampler
var program *cl.Program
var kernel *cl.Kernel
var outPixels []byte
if context, err = cl.NewContextOfDevices(map[cl.ContextParameter]interface{}{cl.CONTEXT_PLATFORM: platform}, []cl.Device{dev}); err != nil {
fatalError(err)
}
format := cl.ImageFormat{ChannelOrder: cl.RGBA, ChannelDataType: cl.UNSIGNED_INT32}
if sourceImage, err = context.NewImage2D(cl.MEM_READ_ONLY, format, uint32(size.X), uint32(size.Y), 0, nil); err != nil {
fatalError(err)
}
if destImage, err = context.NewImage2D(cl.MEM_WRITE_ONLY, format, uint32(size.X), uint32(size.Y), 0, nil); err != nil {
fatalError(err)
}
if sampler, err = context.NewSampler(false, cl.ADDRESS_CLAMP, cl.FILTER_NEAREST); err != nil {
fatalError(err)
}
if queue, err = context.NewCommandQueue(dev, cl.QUEUE_NIL); err != nil {
fatalError(err)
}
if program, err = context.NewProgramFromFile("rotate.cl"); err != nil {
fatalError(err)
}
if err = program.Build(nil, ""); err != nil {
if status := program.BuildStatus(dev); status != cl.BUILD_SUCCESS {
fatalError(&customError{fmt.Sprintf("Build Error:\n%s\n", program.Property(dev, cl.BUILD_LOG))})
}
fatalError(err)
}
if kernel, err = program.NewKernelNamed("imageRotate"); err != nil {
fatalError(err)
}
if err = queue.EnqueueWriteImage(sourceImage, true, [3]cl.Size{0, 0, 0}, [3]cl.Size{cl.Size(size.X), cl.Size(size.Y), 1}, 0, 0, raw.ByteSlice(pixels)); err != nil {
fatalError(err)
}
if err = kernel.SetArgs(0, []interface{}{
sourceImage, destImage,
float32(math.Sin(*angle * math.Pi / 180)),
float32(math.Cos(*angle * math.Pi / 180)),
sampler}); err != nil {
fatalError(err)
}
if err = queue.EnqueueKernel(kernel, []cl.Size{0, 0, 0}, []cl.Size{cl.Size(size.X), cl.Size(size.Y), 1}, []cl.Size{1, 1, 1}); err != nil {
fatalError(err)
}
if outPixels, err = queue.EnqueueReadImage(destImage, true, [3]cl.Size{0, 0, 0}, [3]cl.Size{cl.Size(size.X), cl.Size(size.Y), 1}, 0, 0); err != nil {
fatalError(err)
}
outImage := image.NewNRGBA(inImage.Bounds())
for i := 0; i < len(outImage.Pix); i++ {
outImage.Pix[i] = uint8(outPixels[4*i])
}
switch inFormat {
case "jpeg":
if err = jpeg.Encode(output, outImage, nil); err != nil {
fatalError(err)
}
case "png":
if err = png.Encode(output, outImage); err != nil {
fatalError(err)
}
default:
fatalError(&customError{fmt.Sprintf("Unknown Format: %s", inFormat)})
}
return
}
}
}
func Test_VectAdd(t *testing.T) {
const elements = 100000
A := make([]int, elements)
B := make([]int, elements)
for i := 0; i < elements; i++ {
A[i], B[i] = i, i
}
bytes := uint32(len(raw.ByteSlice(A)))
for _, platform := range Platforms {
for _, dev := range platform.Devices {
var err error
var context *Context
var queue *CommandQueue
var bufA, bufB, bufC *Buffer
var program *Program
var kernel *Kernel
if context, err = NewContextOfDevices(nil, []Device{dev}); err != nil {
t.Fatal(err)
}
if queue, err = context.NewCommandQueue(dev, QUEUE_NIL); err != nil {
t.Fatal(err)
}
if bufA, err = context.NewBuffer(MEM_READ_ONLY, bytes); err != nil {
t.Fatal(err)
}
if bufB, err = context.NewBuffer(MEM_READ_ONLY, bytes); err != nil {
t.Fatal(err)
}
if bufC, err = context.NewBuffer(MEM_WRITE_ONLY, bytes); err != nil {
t.Fatal(err)
}
if err = queue.EnqueueWriteBuffer(bufA, raw.ByteSlice(A), 0); err != nil {
t.Fatal(err)
}
if err = queue.EnqueueWriteBuffer(bufB, raw.ByteSlice(B), 0); err != nil {
t.Fatal(err)
}
if program, err = context.NewProgramFromFile("vector.cl"); err != nil {
t.Fatal(err)
}
if err = program.Build([]Device{dev}, ""); err != nil {
t.Fatal(err)
}
if kernel, err = program.NewKernelNamed("vectAddInt"); err != nil {
t.Fatal(err)
}
if err = kernel.SetArgs(0, []interface{}{bufA, bufB, bufC}); err != nil {
t.Fatal(err)
}
if err = queue.EnqueueKernel(kernel, []Size{0}, []Size{elements}, []Size{1}); err != nil {
t.Fatal(err)
}
if outBuf, err := queue.EnqueueReadBuffer(bufC, 0, bytes); err != nil {
t.Fatal(err)
} else {
C := raw.IntSlice(outBuf)
for i := 0; i < elements; i++ {
if C[i] != i<<1 {
t.Fatal("Output is incorrect")
}
}
}
}
}
}
