/// Before each run, build a vector of random integers.
virtual void setUp(int64_t experimentSize)
{
experimentSize = experimentSize <= 0 ? 1 : experimentSize;
try
{
deviceGC();
int depth = 100;
input_cube = constant(1.0, experimentSize, experimentSize, depth, this->data_type);
input_cube.eval();
output = array(depth, this->data_type);
output.eval();
af::sync();
}
catch (af::exception & e)
{
// print out the error, rethrow the error to cause the test to fail.
std::cout << e << std::endl;
throw e;
}
}
static array::array_proxy gen_indexing(const array &ref, const index &s0, const index &s1, const index &s2, const index &s3, bool linear = false)
{
ref.eval();
af_index_t inds[AF_MAX_DIMS];
inds[0] = s0.get();
inds[1] = s1.get();
inds[2] = s2.get();
inds[3] = s3.get();
return array::array_proxy(const_cast<array&>(ref), inds, linear);
}
void run(const int iter)
{
try {
for (int i = 0; i < iter; i++) {
y = a * x + y;
y.eval();
}
af::sync();
} catch(const af::exception &ex) {
std::cout << ex.what() << std::endl;
throw;
}
}
void Window::plot3(const array& P, const char* const title) {
af_cell temp{_r, _c, title, AF_COLORMAP_DEFAULT};
P.eval();
AF_THROW(af_draw_plot_nd(get(), P.get(), &temp));
}