# example provided by Roger Pau Monn'e
from __future__ import print_function
import pyopencl as cl
import numpy
import numpy.linalg as la
import datetime
from time import time
data_points = 2**23 # ~8 million data points, ~32 MB data
workers = 2**8 # 256 workers, play with this to see performance differences
# eg: 2**0 => 1 worker will be non-parallel execution on gpu
# data points must be a multiple of workers
a = numpy.random.rand(data_points).astype(numpy.float32)
b = numpy.random.rand(data_points).astype(numpy.float32)
c_result = numpy.empty_like(a)
# Speed in normal CPU usage
time1 = time()
c_temp = (a+b) # adds each element in a to its corresponding element in b
c_temp = c_temp * c_temp # element-wise multiplication
c_result = c_temp * (a/2.0) # element-wise half a and multiply
time2 = time()
print("Execution time of test without OpenCL: ", time2 - time1, "s")
for platform in cl.get_platforms():
for device in platform.get_devices():
print("===============================================================")
print("Platform name:", platform.name)
print("Platform profile:", platform.profile)
print("Platform vendor:", platform.vendor)
print("Platform version:", platform.version)
print("---------------------------------------------------------------")
print("Device name:", device.name)
print("Device type:", cl.device_type.to_string(device.type))
print("Device memory: ", device.global_mem_size//1024//1024, 'MB')
print("Device max clock speed:", device.max_clock_frequency, 'MHz')
print("Device compute units:", device.max_compute_units)
print("Device max work group size:", device.max_work_group_size)
print("Device max work item sizes:", device.max_work_item_sizes)
# Simnple speed test
ctx = cl.Context([device])
queue = cl.CommandQueue(ctx,
properties=cl.command_queue_properties.PROFILING_ENABLE)
mf = cl.mem_flags
a_buf = cl.Buffer(ctx, mf.READ_ONLY | mf.COPY_HOST_PTR, hostbuf=a)
b_buf = cl.Buffer(ctx, mf.READ_ONLY | mf.COPY_HOST_PTR, hostbuf=b)
dest_buf = cl.Buffer(ctx, mf.WRITE_ONLY, b.nbytes)
prg = cl.Program(ctx, """
__kernel void sum(__global const float *a,
__global const float *b, __global float *c)
{
int gid = get_global_id(0);
float a_temp;
float b_temp;
float c_temp;
a_temp = a[gid]; // my a element (by global ref)
b_temp = b[gid]; // my b element (by global ref)
c_temp = a_temp+b_temp; // sum of my elements
c_temp = c_temp * c_temp; // product of sums
c_temp = c_temp * (a_temp/2.0); // times 1/2 my a
c[gid] = c_temp; // store result in global memory
}
""").build()
global_size=(data_points,)
local_size=(workers,)
preferred_multiple = cl.Kernel(prg, 'sum').get_work_group_info( \
cl.kernel_work_group_info.PREFERRED_WORK_GROUP_SIZE_MULTIPLE, \
device)
print("Data points:", data_points)
print("Workers:", workers)
print("Preferred work group size multiple:", preferred_multiple)
if (workers % preferred_multiple):
print("Number of workers not a preferred multiple (%d*N)." \
% (preferred_multiple))
print("Performance may be reduced.")
exec_evt = prg.sum(queue, global_size, local_size, a_buf, b_buf, dest_buf)
exec_evt.wait()
elapsed = 1e-9*(exec_evt.profile.end - exec_evt.profile.start)
print("Execution time of test: %g s" % elapsed)
c = numpy.empty_like(a)
cl.enqueue_read_buffer(queue, dest_buf, c).wait()
equal = numpy.all( c == c_result)
if not equal:
print("Results doesn't match!!")
else:
print("Results OK")
