Beispiel #1
0
/**
 * Create a new kernel wrapper object.
 *
 * @public @memberof ccl_kernel
 *
 * @param[in] prg A program wrapper object.
 * @param[in] kernel_name The kernel name.
 * @param[out] err Return location for a ::CCLErr object, or `NULL` if error
 * reporting is to be ignored.
 * @return A new kernel wrapper object.
 * */
CCL_EXPORT
CCLKernel* ccl_kernel_new(
	CCLProgram* prg, const char* kernel_name, CCLErr** err) {

	/* Make sure err is NULL or it is not set. */
	g_return_val_if_fail((err) == NULL || *(err) == NULL, NULL);

	/* Make sure prg is not NULL. */
	g_return_val_if_fail(prg != NULL, NULL);

	/* Make sure kernel_name is not NULL. */
	g_return_val_if_fail(kernel_name != NULL, NULL);

	/* Kernel wrapper object. */
	CCLKernel* krnl = NULL;

	/* OpenCL return status. */
	cl_int ocl_status;

	/* The OpenCL kernel object. */
	cl_kernel kernel = NULL;

	/* Create kernel. */
	kernel = clCreateKernel(ccl_program_unwrap(prg),
		kernel_name, &ocl_status);
	ccl_if_err_create_goto(*err, CCL_OCL_ERROR,
		CL_SUCCESS != ocl_status, ocl_status, error_handler,
		"%s: unable to create kernel (OpenCL error %d: %s).",
		CCL_STRD, ocl_status, ccl_err(ocl_status));

	/* Create kernel wrapper. */
	krnl = ccl_kernel_new_wrap(kernel);

	/* If we got here, everything is OK. */
	g_assert(err == NULL || *err == NULL);
	goto finish;

error_handler:

	/* If we got here there was an error, verify that it is so. */
	g_assert(err == NULL || *err != NULL);

	krnl = NULL;

finish:

	/* Return kernel wrapper. */
	return krnl;

}
Beispiel #2
0
/**
 * Tests creation, getting info from and destruction of
 * kernel wrapper objects.
 * */
static void create_info_destroy_test() {

	/* Test variables. */
	CCLContext* ctx = NULL;
	cl_context context = NULL;
	CCLProgram* prg = NULL;
	cl_program program = NULL;
	CCLKernel* krnl = NULL;
	cl_kernel kernel = NULL;
	CCLDevice* d = NULL;
	CCLQueue* cq = NULL;
	size_t gws;
	size_t lws;
	cl_uint host_buf[CCL_TEST_KERNEL_BUF_SIZE];
	cl_uint host_buf_aux[CCL_TEST_KERNEL_BUF_SIZE];
	CCLBuffer* buf;
	GError* err = NULL;
	CCLEvent* evt = NULL;
	CCLEventWaitList ewl = NULL;
	const char* krnl_name;
	void* args[] = { NULL, NULL };
	cl_bool release_krnl;
	cl_int ocl_status;

	/* Create a context with devices from first available platform. */
	ctx = ccl_test_context_new(&err);
	g_assert_no_error(err);

	/* Create a new program from source and build it. */
	prg = ccl_program_new_from_source(
		ctx, CCL_TEST_KERNEL_CONTENT, &err);
	g_assert_no_error(err);

	ccl_program_build(prg, NULL, &err);
	g_assert_no_error(err);

	/* Create a command queue. */
	cq = ccl_queue_new(ctx, d, CL_QUEUE_PROFILING_ENABLE, &err);
	g_assert_no_error(err);

	/* Test three ways to create a kernel wrapper. */
	for (cl_uint i = 0; i < 3; ++i) {

		/* Create kernel wrapper. */
		switch (i) {
			case 0:
				/* Instantiate kernel directly. */
				krnl = ccl_kernel_new(prg, CCL_TEST_KERNEL_NAME, &err);
				g_assert_no_error(err);
				release_krnl = CL_TRUE;
				break;
			case 1:
				/* Using the program utility function. No need to free
				 * kernel in this case, because it will be freed when
				 * program is destroyed. */
				krnl = ccl_program_get_kernel(
					prg, CCL_TEST_KERNEL_NAME, &err);
				g_assert_no_error(err);
				release_krnl = CL_FALSE;
				break;
			case 2:
				/* Using the "wrap" constructor. */
				kernel = clCreateKernel(ccl_program_unwrap(prg),
					CCL_TEST_KERNEL_NAME, &ocl_status);
				g_assert_cmpint(ocl_status, ==, CL_SUCCESS);
				krnl = ccl_kernel_new_wrap(kernel);
				g_assert_cmphex(GPOINTER_TO_UINT(kernel), ==,
					GPOINTER_TO_UINT(ccl_kernel_unwrap(krnl)));
				release_krnl = CL_TRUE;
				break;
		}

		/* Get some kernel info, compare it with expected info. */

		/* Get kernel function name from kernel info, compare it with the
		 * expected value. */
		krnl_name = ccl_kernel_get_info_array(
			krnl, CL_KERNEL_FUNCTION_NAME, char*, &err);
		g_assert_no_error(err);
		g_assert_cmpstr(krnl_name, ==, CCL_TEST_KERNEL_NAME);

		/* Check if the kernel context is the same as the initial context
		 * and the program context. */
		context = ccl_kernel_get_info_scalar(
			krnl, CL_KERNEL_CONTEXT, cl_context, &err);
		g_assert_no_error(err);
		g_assert(context == ccl_context_unwrap(ctx));

		program = ccl_kernel_get_info_scalar(
			krnl, CL_KERNEL_PROGRAM, cl_program, &err);
		g_assert_no_error(err);
		g_assert(program == ccl_program_unwrap(prg));

#ifndef OPENCL_STUB

		cl_uint ocl_ver;

		/* Get OpenCL version of kernel's underlying platform. */
		ocl_ver = ccl_kernel_get_opencl_version(krnl, &err);
		g_assert_no_error(err);

		(void)ocl_ver;

#ifdef CL_VERSION_1_1

		size_t kwgz;
		size_t* kcwgs;
		CCLDevice* dev = NULL;

		/* If platform supports kernel work group queries, get kernel
		 * work group information and compare it with expected info. */
		if (ocl_ver >= 110) {

			dev = ccl_context_get_device(ctx, 0, &err);
			g_assert_no_error(err);

			kwgz = ccl_kernel_get_workgroup_info_scalar(
				krnl, dev, CL_KERNEL_WORK_GROUP_SIZE, size_t, &err);
			g_assert_no_error(err);
			(void)kwgz;

			kcwgs = ccl_kernel_get_workgroup_info_array(krnl, dev,
				CL_KERNEL_COMPILE_WORK_GROUP_SIZE, size_t*, &err);
			g_assert_no_error(err);
			(void)kcwgs;

		}

#endif /* ifdef CL_VERSION_1_1 */

#ifdef CL_VERSION_1_2

		cl_kernel_arg_address_qualifier kaaq;
		char* kernel_arg_type_name;
		char* kernel_arg_name;

		/* If platform supports kernel argument queries, get kernel argument
		 * information and compare it with expected info. */
		if (ocl_ver >= 120) {

			kaaq = ccl_kernel_get_arg_info_scalar(krnl, 0,
					CL_KERNEL_ARG_ADDRESS_QUALIFIER,
					cl_kernel_arg_address_qualifier, &err);
			g_assert((err == NULL) || (err->code == CCL_ERROR_INFO_UNAVAILABLE_OCL));
			if (err == NULL) {
				g_assert_cmphex(kaaq, ==, CL_KERNEL_ARG_ADDRESS_GLOBAL);
			} else {