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11

Buffers are CL's version of malloc, while pyopencl.array.Array is a workalike of numpy arrays on the compute device. So for the second version of the first part of your question, you may write a_gpu + 2 to get a new arrays that has 2 added to each number in your array, whereas in the case of the Buffer, PyOpenCL only sees a bag of bytes and cannot perform ...


10

This can be achieved by adding __local array as a kernel parameter: __kernel void test(__global int **values, __global int *result, const int array_size, __local int * cache) and providing desired size of the kernel parameter: clSetKernelArg(kernel, 3, array_size*sizeof(int), NULL); The local memory will be allocated upon the kernel invocation. ...


6

You are setting your global size argument incorrectly. Since you are using two dimensions of global size in your kernel, you need to set your global size to (ORDER,ORDER). When you change it to that, you get: [3942 7236 4756 8611]


6

This is definitely a memory access problem. Neighbouring work items' pixels can overlap by as much as 15x16, and worse yet, each work item will overlap at least 225 others. I would use local memory and get work groups to cooperatively process many 16x16 blocks. I like to use a large, square block for each work group. Rectangular blocks are a bit more ...


5

It is similar to C. You pass it a fixed size array as a local. Here is an example from Enja's radix sort. Notice the last argument is a local memory array. def naive_scan(self, num): nhist = num/2/self.cta_size*16 global_size = (nhist,) local_size = (nhist,) extra_space = nhist / 16 #NUM_BANKS defined as 16 in RadixSort.cpp ...


5

It seems you are looking for the fastest and most effective path to learn PyOpenCL. You do not need to know OpenCL (the hard part) at the start, but it will be helpful to know Python when you begin. For learning Python syntax quickly, I recommend Codecademy's Python track: http://www.codecademy.com/tracks/python Then, the Udacity parallel programming ...


5

NVIDIA have a whitepaper for the NVIDIA GeForce GTX 750 Ti, which is worth a read. An OpenCL compute unit translates to a streaming multiprocessor in NVIDIA GPU terms. Each Maxwell SMM in your GPU contains 128 processing elements ("CUDA cores") - and 128*5 = 640. The SIMD width of the device is still 32, but each compute unit (SMM) can issue instructions to ...


5

Optimization #1: make vector __local. My first pass at this got a decent improvement in performance. I noticed that each vector[k] is read a total of D times, so I copied it to a __local. This is only possible because D is small enough to allow this. The kernel as you have it above suffers from a terrible ALU:fetch ratio of 0.08 on both the 5870 and the ...


5

In OpenCL 1.2 you link different object files together.


4

My opinion is that trying to shoehorn a dynamic language into OpenCL is not worth the effort. You will lose most of what you like about Python, and probably not save much time for your effort in the end. But I am speaking only of writing OpenCL kernels in Python. There is also the host application, which prepares and submits the kernels. If you like Python, ...


4

Making this an answer since it seems to fully answer the question. You normally create the buffer in device memory, and you can reuse these buffers by redefining the kernel arguments via clSetKernelArg() (unless, of course, you want to use them at the same time which is trickier, and I'm not sure it's even allowed by the OpenCL standard in fact).


4

I found what was causing this error. In pyopencl __init__ there is a function called _find_pyopencl_include_path, it is quite self explanatory what it does. To make a long story short: the imp module fails to find the pyopencl module. To fix this I commented out that line and set pathname to the path to pyopencls include directory. Probably not a good fix. ...


4

PyOpenCL (for Python) and OpenCL (for C/C++) are just frameworks. You choose the framework based on the language you're using for your application. Neither of these has Image Processing algorithms pre-built. If you want image processing algorithms, then try libraries that are built on top of OpenCL. I work on ArrayFire for OpenCL that has image ...


4

If you're using nvidia instead of ATI/AMD GPU, the OpenCL support in nvidia SDK is...less than desired. Intel provides a CPU-based OpenCL SDK for their recent processors, see http://software.intel.com/en-us/vcsource/tools/opencl-sdk-2013 -- (to use the RPM packages they provide on Ubuntu, you need to run "fakeroot alien --to-deb" on each package, then "dpkg ...


4

Irrespective of the language of adoption for GPGPU computing such as Java,C/C++, Python, I would recommend you first get started with the basics of GPGPU computing and OpenCL. You can use the following resources all are C/C++ oriented but this should you give enough knowledge about OpenCL, GPGPU hardware to get you started. AMD OpenCL University Tool kit ...


4

According to the PyOpenCL documentation, Context takes a list of devices, not a specific device. If you change your context creation code to this: platform = cl.get_platforms() my_gpu_devices = platform[0].get_devices(device_type=cl.device_type.GPU) ctx = cl.Context(devices=my_gpu_devices) It should work. If you really want to limit the choice to only ...


3

Kernel debugging is an implementation-dependent affair. On Linux, the best I've found is to use AMD's CL implementation on the CPU, compile the kernel with -g, and use gdb. They've got instructions on this in their programming guide, here: AMD CL Documentation page


3

The local-work-size, aka work-group-size, is the number of work-items in each work-group. Each work-group is executed on a compute-unit which is able to handle a bunch of work-items, not only one. So when you are using too small groups you waste some computing power, and only got a coarse parallelization at the compute-unit level. But if you have too many ...


3

.wait() will wait for the operation to be completed. If your code can proceed without it being finished (or even started), you can leave it out. Note that this is not related to the order of operations in the queue: they will be executed (unless you use out-of-order queue) in the order you enqueued them, one after another.


3

I am no familiar with Python and its OpenCL implementation, but a local memory can also be created within the kernel with a fixed size (similar what you did): __kernel void matrixMul(...) { __local float A_templ[1024]; } Instead of 1024 a defined preprocessor symbol can be used and can be set during compilation to change the size: #define SIZE 1024 ...


3

The main(ish) point in GPU computing is trying to utilize hardware parallelism as much as possible. Instead of using the loop, launch a kernel with a different thread for every one of the coordinates. Then, either use atomic operations (the quick-to-code, but slow-performance option), or parallel reduction, for the various sums. AMD has A tutorial on this ...


3

There's two errors with your kernel invocation. The error that relates to your backtrace is that self.a is a Python int object, and the kernel expects an OpenCL unsigned int, which is specifically 32-bits. You need to explicitly pass in a 32-bit integer, by using (for example) numpy.int32(self.a). The second error is that the global work size argument needs ...


3

import os os.environ['PYOPENCL_COMPILER_OUTPUT'] = '1' Do this to see the compiler output, i've gotten the same message before. It was just the intel opencl compiler saying it had vectorized\optimized the opencl kernel.


3

You said it crashed on a line like this: s = zeros((A,B,C),complex128) With A=2400, B=256, C=25. That would require 235 MB of memory. And not just any 235 MB: it must be contiguous, because NumPy expects to use it as a single array. You also mentioned you're running this in a 32-bit process, and that it crashes when the process memory usage gets around ...


3

It is likely that PyOpenCL is your best choice. I would choose to use C only in very specific situations (a super-critical need for speed/low-latency on the host). For most casual parallel programs, it is fine for the host side to have plenty of slack, because all the real work gets done on the device. You can consider PyOpenCL and OpenCL to have ...


3

The function pyopencl.array.to_device does not take the context as a parameter according to the documentation. Use this instead: gpu_data0 = cl_array.to_device(self.queue, ref_input)


3

When you specify extern __shared__ float sdata[]; you are telling the compiler that the caller will provide the shared memory. In PyCUDA, that is done by specifying shared=nnnn on the line that calls the CUDA function. In your case, something like: reduce0(drv.In(a),drv.Out(dest),block=(400,1,1),shared=4*400) Alternately, you can drop the extern ...


3

If you're willing to use http://pythonhosted.org/pythran, you can leverage on the numpy implementation and get better performance than cython for that case: #pythran export np_cos_norm(float[], float[]) import numpy as np def np_cos_norm(a, b): val = np.sum(1. - np.cos(a-b)) return np.sqrt(val / 2. / a.shape[0]) And compile it with: pythran ...


3

Your second case is only capturing the time taken to enqueue the kernel, not to actually run it. These enqueue kernel calls return as soon as the kernel invocation has been placed in the queue - the kernel will be run asynchronously with your host code. To time the kernel execution as well, just add a call to wait until all enqueued commands have finished: ...



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