DEF_TEST(SkSLIfTypeMismatch, r) {
test_failure(r,
"void main() { if (3) { } }",
"error: 1: expected 'bool', but found 'int'\n1 error\n");
}
DEF_TEST(SkSLInterfaceBlockStorageModifiers, r) {
test_failure(r,
"uniform foo { out int x; };",
"error: 1: interface block fields may not have storage qualifiers\n1 error\n");
}
DEF_TEST(SkSLBreakOutsideLoop, r) {
test_failure(r,
"void foo() { while(true) {} if (true) break; }",
"error: 1: break statement must be inside a loop or switch\n1 error\n");
}
DEF_TEST(SkSLReturnTypeMismatch, r) {
test_failure(r,
"int foo() { return 1.0; } void main() { }",
"error: 1: expected 'int', but found 'float'\n1 error\n");
}
DEF_TEST(SkSLDifferentModifiers, r) {
test_failure(r,
"void test(int x); void test(out int x) { }",
"error: 1: modifiers on parameter 1 differ between declaration and definition\n1 "
"error\n");
}
DEF_TEST(SkSLSwizzleTooManyComponents, r) {
test_failure(r,
"void main() { vec4 test = vec2(1).xxxxx; }",
"error: 1: too many components in swizzle mask 'xxxxx'\n1 error\n");
}
DEF_TEST(SkSLReturnFromVoid, r) {
test_failure(r,
"void main() { return true; }",
"error: 1: may not return a value from a void function\n1 error\n");
}
static int
run_test (int, char**)
{
test_get_temporary_buffer ((char*)0, "char");
test_get_temporary_buffer ((int*)0, "int");
#ifdef _RWSTD_LONG_LONG
test_get_temporary_buffer ((_RWSTD_LONG_LONG*)0, "long long");
#else // if !defined (_RWSTD_LONG_LONG)
test_get_temporary_buffer ((long*)0, "long");
#endif // _RWSTD_LONG_LONG
#ifndef _RWSTD_NO_LONG_DOUBLE
test_get_temporary_buffer ((long double*)0, "long double");
#else // if defined (_RWSTD_NO_LONG_DOUBLE)
test_get_temporary_buffer ((double*)0, "double");
#endif // _RWSTD_NO_LONG_DOUBLE
// exercise ordinary pointers
test_get_temporary_buffer ((void**)0, "void*");
// exercise function pointers
test_get_temporary_buffer ((FunctionPointer*)0, "void (*)()");
// exercise pointers to members
test_get_temporary_buffer ((MemberPointer*)0, "void (struct::*)()");
#if (!defined (__IBMCPP__) || __IBMCPP__ > 700) \
&& !defined (__HP_aCC)
# ifndef _MSC_VER
const std::size_t MAX_SIZE = _RWSTD_PTRDIFF_MAX;
# else
// the MSVC and ICC/Windows has maximum size of
// the array equal to 0x7fffffff bytes
const std::size_t MAX_SIZE = INT_MAX;
# endif
// avoid instantiating test on very large structs
// to prevent failures (at compile or run-time) due
// to compiler bugs
test_failure ((BigStruct<MAX_SIZE / 2>*)0, 0);
test_failure ((BigStruct<MAX_SIZE - 1>*)0, 0);
test_failure ((BigStruct<MAX_SIZE>*)0, 0);
#else
// work around VAC++ 7.0 (and prior) bug #549
// work around HP aCC 3,5,6 bug #565
rw_warn (0, 0, __LINE__, "get_temp_buffer<large-struct>() "
"not tested due to a compiler bug");
#endif // VAC++ > 7.0
return 0;
}
void test_handle_invalid_nucleotide(void)
{
TEST_IGNORE();
test_failure("U");
}
void test_fail_stop(const char *msg, int status)
{
test_failure(msg);
test_finalize();
exit(status);
}
int
main(int argc, char *argv[])
{
char hostname[OPAL_MAXHOSTNAMELEN];
opal_init(&argc, &argv);
test_init("opal_if");
/* 127.0.0.1 */
if (test_ifaddrtoname("127.0.0.1")) {
test_success();
} else {
test_failure("ifaddrtoname test failed for 127.0.0.1");
}
if (opal_ifislocal("127.0.0.1")) {
test_success();
} else {
test_failure("ifislocal test failed for 127.0.0.1");
}
/* localhost */
if (test_ifaddrtoname("localhost")) {
test_success();
} else {
test_failure("ifaddrtoname test failed for localhost");
}
if (opal_ifislocal("localhost")) {
test_success();
} else {
test_failure("ifislocal test failed for localhost");
}
/* 0.0.0.0 */
if (test_ifaddrtoname("0.0.0.0")) {
test_failure("ifaddrtoname test failed for 0.0.0.0");
} else {
test_success();
}
if (opal_ifislocal("0.0.0.0")) {
test_failure("opal_ifislocal test failed for 0.0.0.0");
} else {
test_success();
}
/* foo.example.com */
printf("This should generate a warning:\n");
fflush(stdout);
if (test_ifaddrtoname("foo.example.com")) {
test_failure("ifaddrtoname test failed for foo.example.com");
} else {
test_success();
}
printf("This should generate a warning:\n");
fflush(stdout);
if (opal_ifislocal("foo.example.com")) {
test_failure("ifislocal test failed for foo.example.com");
} else {
test_success();
}
/* local host name */
gethostname(hostname, sizeof(hostname));
if (test_ifaddrtoname(hostname)) {
test_success();
} else {
test_failure("ifaddrtoname test failed for local host name");
}
if (opal_ifislocal(hostname)) {
test_success();
} else {
test_failure("ifislocal test failed for local host name");
}
test_finalize();
opal_finalize();
return 0;
}
DEF_TEST(SkSLForTypeMismatch, r) {
test_failure(r,
"void main() { for (int x = 0; x; x++) { } }",
"error: 1: expected 'bool', but found 'int'\n1 error\n");
}
DEF_TEST(SkSLWhileTypeMismatch, r) {
test_failure(r,
"void main() { while (float3(1)) { } }",
"error: 1: expected 'bool', but found 'float3'\n1 error\n");
}
DEF_TEST(SkSLDoTypeMismatch, r) {
test_failure(r,
"void main() { do { } while (float2(1)); }",
"error: 1: expected 'bool', but found 'float2'\n1 error\n");
}
DEF_TEST(SkSLSwizzleMatrix, r) {
test_failure(r,
"void main() { mat2 x = mat2(1); float y = x.y; }",
"error: 1: cannot swizzle value of type 'mat2'\n1 error\n");
}
void test_handle_completely_invalid_input(void)
{
TEST_IGNORE();
test_failure("XXX");
}
DEF_TEST(SkSLSwizzleOutOfBounds, r) {
test_failure(r,
"void main() { vec3 test = vec2(1).xyz; }",
"error: 1: invalid swizzle component 'z'\n1 error\n");
}
void test_handle_partially_invalid_input(void)
{
TEST_IGNORE();
test_failure("ACGTXXXCTTAA");
}
DEF_TEST(SkSLSwizzleDuplicateOutput, r) {
test_failure(r,
"void main() { vec4 test = vec4(1); test.xyyz = vec4(1); }",
"error: 1: cannot write to the same swizzle field more than once\n1 error\n");
}
int main(int argc, char* argv[])
{
orte_proc_info(); /* initialize proc info structure */
orte_process_info.my_name = (orte_process_name_t*)malloc(sizeof(orte_process_name_t));
orte_process_info.my_name->cellid = 0;
orte_process_info.my_name->jobid = 0;
orte_process_info.my_name->vpid = 0;
test_init("orte_session_dir_t");
test_out = fopen( "test_session_dir_out", "w+" );
if( test_out == NULL ) {
test_failure("test_session_dir couldn't open test file failed");
test_finalize();
exit(1);
}
fprintf(test_out, "running test1\n");
if (test1()) {
test_success();
}
else {
test_failure("orte_session_dir_t test1 failed");
}
fprintf(test_out, "running test2\n");
if (test2()) {
test_success();
}
else {
test_failure("orte_session_dir_t test2 failed");
}
fprintf(test_out, "running test3\n");
if (test3()) {
test_success();
}
else {
test_failure("orte_session_dir_t test3 failed");
}
fprintf(test_out, "running test4\n");
if (test4()) {
test_success();
}
else {
test_failure("orte_session_dir_t test4 failed");
}
fprintf(test_out, "running test5\n");
if (test5()) {
test_success();
}
else {
test_failure("orte_session_dir_t test5 failed");
}
fprintf(test_out, "running test6\n");
if (test6()) {
test_success();
}
else {
test_failure("orte_session_dir_t test6 failed");
}
fprintf(test_out, "running test7\n");
if (test7()) {
test_success();
}
else {
test_failure("orte_session_dir_t test7 failed");
}
fprintf(test_out, "running test8\n");
if (test8()) {
test_success();
}
else {
test_failure("orte_session_dir_t test8 failed");
}
fprintf(test_out, "completed all tests\n");
fclose(test_out);
/* clean up */
orte_proc_info_finalize();
test_finalize();
return 0;
}
DEF_TEST(SkSLReturnMissingValue, r) {
test_failure(r,
"int foo() { return; } void main() { }",
"error: 1: expected function to return 'int'\n1 error\n");
}
void test1(void)
{
ompi_rb_tree_t tree;
int rc;
void * result;
OBJ_CONSTRUCT(&tree, ompi_rb_tree_t);
rc = ompi_rb_tree_init(&tree, comp_fn);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly initialize the tree");
}
rc = ompi_rb_tree_insert(&tree, &keys[0], &values[0]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[0]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[0], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[1], &values[1]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[1]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[1], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[2], &values[2]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[2]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[2], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[3], &values[3]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[3]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[3], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[4], &values[4]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[4]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[4], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[5], &values[5]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[5]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[5], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[6], &values[6]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[6]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[6], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_insert(&tree, &keys[7], &values[7]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly insert a new node");
}
result = ompi_rb_tree_find(&tree, &keys[7]);
if(NULL == result) {
test_failure("lookup returned null!");
}
if(!test_verify_int(values[7], *((int *) result))) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_size(&tree);
if(!test_verify_int(8, rc)) {
test_failure("failed to properly insert a new node");
}
rc = ompi_rb_tree_delete(&tree, &keys[0]);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly delete a node");
}
result = ompi_rb_tree_find(&tree, &keys[0]);
if(NULL != result) {
test_failure("lookup returned a value instead of null!");
} else {
test_success();
}
OBJ_DESTRUCT(&tree);
}
DEF_TEST(SkSLDifferentReturnType, r) {
test_failure(r,
"int main() { return 1; } void main() { }",
"error: 1: functions 'void main()' and 'int main()' differ only in return type\n1 "
"error\n");
}
void test2(void)
{
ompi_free_list_t key_list;
ompi_free_list_item_t * new_value;
ompi_rb_tree_t tree;
int rc, i, size;
void * result, * lookup;
void * mem[NUM_ALLOCATIONS];
ompi_free_list_item_t * key_array[NUM_ALLOCATIONS];
struct timeval start, end;
OBJ_CONSTRUCT(&key_list, ompi_free_list_t);
ompi_free_list_init_new(&key_list, sizeof(ompi_test_rb_value_t),
CACHE_LINE_SIZE,
OBJ_CLASS(ompi_test_rb_value_t),
0,CACHE_LINE_SIZE,
0, -1 , 128, NULL);
OBJ_CONSTRUCT(&tree, ompi_rb_tree_t);
rc = ompi_rb_tree_init(&tree, mem_node_compare);
if(!test_verify_int(OMPI_SUCCESS, rc)) {
test_failure("failed to properly initialize the tree");
}
size = 1;
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
mem[i] = malloc(size);
if(NULL == mem[i])
{
test_failure("system out of memory");
return;
}
OMPI_FREE_LIST_GET(&key_list, new_value, rc);
if(OMPI_SUCCESS != rc)
{
test_failure("failed to get memory from free list");
}
key_array[i] = new_value;
((ompi_test_rb_value_t *) new_value)->key.bottom = mem[i];
((ompi_test_rb_value_t *) new_value)->key.top =
(void *) ((size_t) mem[i] + size - 1);
((ompi_test_rb_value_t *) new_value)->registered_mpools[0] = (void *) i;
rc = ompi_rb_tree_insert(&tree, &((ompi_test_rb_value_t *)new_value)->key,
new_value);
if(OMPI_SUCCESS != rc)
{
test_failure("failed to properly insert a new node");
}
size += 1;
}
gettimeofday(&start, NULL);
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
lookup = (void *) ((size_t) mem[i] + i);
result = ompi_rb_tree_find(&tree, &lookup);
if(NULL == result)
{
test_failure("lookup returned null!");
} else if(i != ((int) ((ompi_test_rb_value_t *) result)->registered_mpools[0]))
{
test_failure("lookup returned wrong node!");
}
result = ompi_rb_tree_find(&tree, &lookup);
if(NULL == result)
{
test_failure("lookup returned null!");
} else if(i != ((int) ((ompi_test_rb_value_t *) result)->registered_mpools[0]))
{
test_failure("lookup returned wrong node!");
}
}
gettimeofday(&end, NULL);
#if 0
i = (end.tv_sec - start.tv_sec) * 1000000 + (end.tv_usec - start.tv_usec);
printf("In a %d node tree, %d lookups took %f microseonds each\n",
NUM_ALLOCATIONS, NUM_ALLOCATIONS * 2,
(float) i / (float) (NUM_ALLOCATIONS * 2));
#endif
for(i = 0; i < NUM_ALLOCATIONS; i++)
{
if(NULL != mem[i])
{
free(mem[i]);
}
OMPI_FREE_LIST_RETURN(&(key_list), key_array[i]);
}
OBJ_DESTRUCT(&tree);
OBJ_DESTRUCT(&key_list);
}
DEF_TEST(SkSLCallNonFunction, r) {
test_failure(r,
"void main() { float x = 3; x(); }",
"error: 1: 'x' is not a function\n1 error\n");
}
int main(int argc, char **argv)
{
/* local variables */
opal_list_t list, x;
size_t indx,i,list_size, tmp_size_1, tmp_size_2,size_elements;
int error_cnt;
test_data_t *elements, *ele;
opal_list_item_t *item;
opal_init();
test_init("opal_list_t");
/* initialize list */
OBJ_CONSTRUCT(&list, opal_list_t);
OBJ_CONSTRUCT(&x, opal_list_t);
/* check length of list */
list_size=opal_list_get_size(&list);
if( 0 == list_size ) {
test_success();
} else {
test_failure(" opal_list_get_size");
}
/* check for empty */
if (opal_list_is_empty(&list)) {
test_success();
} else {
test_failure(" opal_list_is_empty(empty list)");
}
/* create test elements */
size_elements=4;
elements=(test_data_t *)malloc(sizeof(test_data_t)*size_elements);
assert(elements);
for(i=0 ; i < size_elements ; i++) {
OBJ_CONSTRUCT(elements + i, test_data_t);
(elements+i)->data=i;
}
/* populate list */
for(i=0 ; i < size_elements ; i++) {
opal_list_append(&list,(opal_list_item_t *)(elements+i));
}
list_size=opal_list_get_size(&list);
if( list_size == size_elements ) {
test_success();
} else {
test_failure(" populating list");
}
/* checking for empty on non-empty list */
if (!opal_list_is_empty(&list)) {
test_success();
} else {
test_failure(" opal_list_is_empty(non-empty list)");
}
/* check that list is ordered as expected */
i=0;
error_cnt=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
if( ele->data != i )
error_cnt++;
i++;
}
if( 0 == error_cnt ) {
test_success();
} else {
test_failure(" error in list order ");
}
/* check opal_list_get_first */
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_get_first(&list);
assert(ele);
if( 0 == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_get_first");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( size_elements == i ) {
test_success();
} else {
test_failure(" error in opal_list_get_first - list size changed ");
}
/* check opal_list_get_last */
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_get_last(&list);
assert(ele);
if( (size_elements-1) == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_get_last");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( size_elements == i ) {
test_success();
} else {
test_failure(" error in opal_list_get_first - list size changed ");
}
/* check opal_list_remove_first */
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_remove_first(&list);
assert(ele);
if( 0 == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_remove_first");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( (size_elements-1) == i ) {
test_success();
} else {
test_failure(" error in opal_list_remove_first - list size changed ");
}
/* test opal_list_prepend */
opal_list_prepend(&list,(opal_list_item_t *)elements);
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_get_first(&list);
assert(ele);
if( 0 == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_prepend");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( size_elements == i ) {
test_success();
} else {
test_failure(" error in opal_list_prepend - list size changed ");
}
/* check opal_list_remove_last */
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_remove_last(&list);
assert(ele);
if( (size_elements-1) == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_remove_last");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( (size_elements-1) == i ) {
test_success();
} else {
test_failure(" error in opal_list_remove_last - list size changed ");
}
/* test opal_list_append */
opal_list_append(&list,(opal_list_item_t *)(elements+size_elements-1));
ele = (test_data_t *)NULL;
ele = (test_data_t *) opal_list_get_last(&list);
assert(ele);
if( (size_elements-1) == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_append");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( size_elements == i ) {
test_success();
} else {
test_failure(" error in opal_list_append - list size changed ");
}
/* remove element from list */
indx=size_elements/2;
if( 0 == indx )
indx=1;
assert(2 <= size_elements);
ele = (test_data_t *)NULL;
ele = (test_data_t *)
opal_list_remove_item(&list,(opal_list_item_t *)(elements+indx));
assert(ele);
if( (indx-1) == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_remove - previous");
}
ele=(test_data_t *)(((opal_list_item_t *)ele)->opal_list_next);
if( (indx+1) == ele->data ) {
test_success();
} else {
test_failure(" error in opal_list_remove - next");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( (size_elements-1) == i ) {
test_success();
} else {
test_failure(" error in opal_list_remove - list size changed incorrectly");
}
/* test the insert function */
i=opal_list_insert(&list,(opal_list_item_t *)(elements+indx),indx);
if( 1 == i ) {
test_success();
} else {
test_failure(" error in opal_list_remove_item \n");
}
i=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
i++;
}
if( size_elements == i ) {
test_success();
} else {
test_failure(" error in opal_list_insert - incorrect list length");
}
i=0;
error_cnt=0;
for(ele = (test_data_t *) opal_list_get_first(&list);
ele != (test_data_t *) opal_list_get_end(&list);
ele = (test_data_t *) ((opal_list_item_t *)ele)->opal_list_next) {
if( ele->data != i )
error_cnt++;
i++;
}
if( 0 == error_cnt ) {
test_success();
} else {
test_failure(" error in list order - opal_list_remove_item ");
}
/* test the splice and join functions */
list_size = opal_list_get_size(&list);
for (i = 0, item = opal_list_get_first(&list) ;
i < list_size / 2 ; ++i, item = opal_list_get_next(item)) {
}
opal_list_splice(&x, opal_list_get_end(&x),
&list, item, opal_list_get_end(&list));
tmp_size_1 = opal_list_get_size(&list);
tmp_size_2 = opal_list_get_size(&x);
if (tmp_size_1 != i) {
test_failure(" error in splice (size of list)");
} else if (tmp_size_2 != list_size - tmp_size_1) {
test_failure(" error in splice (size of x)");
} else {
test_success();
}
opal_list_join(&list, opal_list_get_end(&list), &x);
tmp_size_1 = opal_list_get_size(&list);
tmp_size_2 = opal_list_get_size(&x);
if (tmp_size_1 != list_size) {
test_failure(" error in join (size of list)");
} else if (tmp_size_2 != 0) {
test_failure(" error in join (size of x)");
} else {
test_success();
}
if (NULL != elements) free(elements);
opal_finalize();
return test_finalize();
}
DEF_TEST(SkSLNoReturn, r) {
test_failure(r,
"int foo() { if (2 > 5) return 3; }",
"error: 1: function can exit without returning a value\n1 error\n");
}
DEF_TEST(SkSLSwizzleScalar, r) {
test_failure(r,
"void main() { float x = 1; float y = x.y; }",
"error: 1: cannot swizzle value of type 'float'\n1 error\n");
}
DEF_TEST(SkSLUndefinedSymbol, r) {
test_failure(r,
"void main() { x = vec2(1); }",
"error: 1: unknown identifier 'x'\n1 error\n");
}
DEF_TEST(SkSLArgumentMismatch, r) {
test_failure(r,
"float foo(float x) { return x * x; }"
"void main() { float x = foo(true); }",
"error: 1: expected 'float', but found 'bool'\n1 error\n");
}
