qemu/tests/test-qmp-commands.c

251 lines
7.6 KiB
C
Raw Normal View History

#include <glib.h>
#include "qemu-common.h"
#include "qapi/qmp/types.h"
#include "test-qmp-commands.h"
#include "qapi/qmp/dispatch.h"
#include "qemu/module.h"
#include "qapi/qmp-input-visitor.h"
#include "tests/test-qapi-types.h"
#include "tests/test-qapi-visit.h"
void qmp_user_def_cmd(Error **errp)
{
}
void qmp_user_def_cmd1(UserDefOne * ud1, Error **errp)
{
}
UserDefTwo *qmp_user_def_cmd2(UserDefOne *ud1a,
bool has_udb1, UserDefOne *ud1b,
Error **errp)
{
UserDefTwo *ret;
UserDefOne *ud1c = g_malloc0(sizeof(UserDefOne));
UserDefOne *ud1d = g_malloc0(sizeof(UserDefOne));
ud1c->string = strdup(ud1a->string);
ud1c->base = g_new0(UserDefZero, 1);
ud1c->base->integer = ud1a->base->integer;
ud1d->string = strdup(has_udb1 ? ud1b->string : "blah0");
ud1d->base = g_new0(UserDefZero, 1);
ud1d->base->integer = has_udb1 ? ud1b->base->integer : 0;
ret = g_new0(UserDefTwo, 1);
ret->string0 = strdup("blah1");
qapi: Drop tests for inline nested structs A future patch will be using a 'name':{dictionary} entry in the QAPI schema to specify a default value for an optional argument; but existing use of inline nested structs conflicts with that goal. More precisely, a definition in the QAPI schema associates a name with a set of properties: Example 1: { 'struct': 'Foo', 'data': { MEMBERS... } } associates the global name 'Foo' with properties (meta-type struct) and MEMBERS... Example 2: 'mumble': TYPE within MEMBERS... above associates 'mumble' with properties (type TYPE) and (optional false) within type Foo The syntax of example 1 is extensible; if we need another property, we add another name/value pair to the dictionary (such as 'base':TYPE). The syntax of example 2 is not extensible, because the right hand side can only be a type. We have used name encoding to add a property: "'*mumble': 'int'" associates 'mumble' with (type int) and (optional true). Nice, but doesn't scale. So the solution is to change our existing uses to be syntactic sugar to an extensible form: NAME: TYPE --> NAME: { 'type': TYPE, 'optional': false } *ONAME: TYPE --> ONAME: { 'type': TYPE, 'optional': true } This patch fixes the testsuite to avoid inline nested types, by breaking the nesting into explicit types; it means that the type is now boxed instead of unboxed in C code, but makes no difference on the wire (and if desired, a later patch could change the generator to not do so much boxing in C). When touching code to add new allocations, also convert existing allocations to consistently prefer typesafe g_new0 over g_malloc0 when a type name is involved. Signed-off-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-05-04 18:05:30 +03:00
ret->dict1 = g_new0(UserDefTwoDict, 1);
ret->dict1->string1 = strdup("blah2");
ret->dict1->dict2 = g_new0(UserDefTwoDictDict, 1);
ret->dict1->dict2->userdef = ud1c;
ret->dict1->dict2->string = strdup("blah3");
ret->dict1->dict3 = g_new0(UserDefTwoDictDict, 1);
ret->dict1->has_dict3 = true;
ret->dict1->dict3->userdef = ud1d;
ret->dict1->dict3->string = strdup("blah4");
return ret;
}
int64_t qmp_user_def_cmd3(int64_t a, bool has_b, int64_t b, Error **errp)
{
return a + (has_b ? b : 0);
}
__org_qemu_x_Union1 *qmp___org_qemu_x_command(__org_qemu_x_EnumList *a,
__org_qemu_x_StructList *b,
__org_qemu_x_Union2 *c,
__org_qemu_x_Alt *d,
Error **errp)
{
__org_qemu_x_Union1 *ret = g_new0(__org_qemu_x_Union1, 1);
ret->kind = ORG_QEMU_X_UNION1_KIND___ORG_QEMU_X_BRANCH;
ret->__org_qemu_x_branch = strdup("blah1");
return ret;
}
/* test commands with no input and no return value */
static void test_dispatch_cmd(void)
{
QDict *req = qdict_new();
QObject *resp;
qdict_put_obj(req, "execute", QOBJECT(qstring_from_str("user_def_cmd")));
resp = qmp_dispatch(QOBJECT(req));
assert(resp != NULL);
assert(!qdict_haskey(qobject_to_qdict(resp), "error"));
qobject_decref(resp);
QDECREF(req);
}
/* test commands that return an error due to invalid parameters */
static void test_dispatch_cmd_error(void)
{
QDict *req = qdict_new();
QObject *resp;
qdict_put_obj(req, "execute", QOBJECT(qstring_from_str("user_def_cmd2")));
resp = qmp_dispatch(QOBJECT(req));
assert(resp != NULL);
assert(qdict_haskey(qobject_to_qdict(resp), "error"));
qobject_decref(resp);
QDECREF(req);
}
static QObject *test_qmp_dispatch(QDict *req)
{
QObject *resp_obj;
QDict *resp;
QObject *ret;
resp_obj = qmp_dispatch(QOBJECT(req));
assert(resp_obj);
resp = qobject_to_qdict(resp_obj);
assert(resp && !qdict_haskey(resp, "error"));
ret = qdict_get(resp, "return");
assert(ret);
qobject_incref(ret);
qobject_decref(resp_obj);
return ret;
}
/* test commands that involve both input parameters and return values */
static void test_dispatch_cmd_io(void)
{
QDict *req = qdict_new();
QDict *args = qdict_new();
QDict *args3 = qdict_new();
QDict *ud1a = qdict_new();
QDict *ud1b = qdict_new();
QDict *ret, *ret_dict, *ret_dict_dict, *ret_dict_dict_userdef;
QDict *ret_dict_dict2, *ret_dict_dict2_userdef;
QInt *ret3;
qdict_put_obj(ud1a, "integer", QOBJECT(qint_from_int(42)));
qdict_put_obj(ud1a, "string", QOBJECT(qstring_from_str("hello")));
qdict_put_obj(ud1b, "integer", QOBJECT(qint_from_int(422)));
qdict_put_obj(ud1b, "string", QOBJECT(qstring_from_str("hello2")));
qdict_put_obj(args, "ud1a", QOBJECT(ud1a));
qdict_put_obj(args, "ud1b", QOBJECT(ud1b));
qdict_put_obj(req, "arguments", QOBJECT(args));
qdict_put_obj(req, "execute", QOBJECT(qstring_from_str("user_def_cmd2")));
ret = qobject_to_qdict(test_qmp_dispatch(req));
assert(!strcmp(qdict_get_str(ret, "string0"), "blah1"));
ret_dict = qdict_get_qdict(ret, "dict1");
assert(!strcmp(qdict_get_str(ret_dict, "string1"), "blah2"));
ret_dict_dict = qdict_get_qdict(ret_dict, "dict2");
ret_dict_dict_userdef = qdict_get_qdict(ret_dict_dict, "userdef");
assert(qdict_get_int(ret_dict_dict_userdef, "integer") == 42);
assert(!strcmp(qdict_get_str(ret_dict_dict_userdef, "string"), "hello"));
assert(!strcmp(qdict_get_str(ret_dict_dict, "string"), "blah3"));
ret_dict_dict2 = qdict_get_qdict(ret_dict, "dict3");
ret_dict_dict2_userdef = qdict_get_qdict(ret_dict_dict2, "userdef");
assert(qdict_get_int(ret_dict_dict2_userdef, "integer") == 422);
assert(!strcmp(qdict_get_str(ret_dict_dict2_userdef, "string"), "hello2"));
assert(!strcmp(qdict_get_str(ret_dict_dict2, "string"), "blah4"));
QDECREF(ret);
qdict_put(args3, "a", qint_from_int(66));
qdict_put(req, "arguments", args3);
qdict_put(req, "execute", qstring_from_str("user_def_cmd3"));
ret3 = qobject_to_qint(test_qmp_dispatch(req));
assert(qint_get_int(ret3) == 66);
QDECREF(ret3);
QDECREF(req);
}
/* test generated dealloc functions for generated types */
static void test_dealloc_types(void)
{
UserDefOne *ud1test, *ud1a, *ud1b;
UserDefOneList *ud1list;
ud1test = g_malloc0(sizeof(UserDefOne));
ud1test->base = g_new0(UserDefZero, 1);
ud1test->base->integer = 42;
ud1test->string = g_strdup("hi there 42");
qapi_free_UserDefOne(ud1test);
ud1a = g_malloc0(sizeof(UserDefOne));
ud1a->base = g_new0(UserDefZero, 1);
ud1a->base->integer = 43;
ud1a->string = g_strdup("hi there 43");
ud1b = g_malloc0(sizeof(UserDefOne));
ud1b->base = g_new0(UserDefZero, 1);
ud1b->base->integer = 44;
ud1b->string = g_strdup("hi there 44");
ud1list = g_malloc0(sizeof(UserDefOneList));
ud1list->value = ud1a;
ud1list->next = g_malloc0(sizeof(UserDefOneList));
ud1list->next->value = ud1b;
qapi_free_UserDefOneList(ud1list);
}
/* test generated deallocation on an object whose construction was prematurely
* terminated due to an error */
static void test_dealloc_partial(void)
{
static const char text[] = "don't leak me";
UserDefTwo *ud2 = NULL;
Error *err = NULL;
/* create partial object */
{
QDict *ud2_dict;
QmpInputVisitor *qiv;
ud2_dict = qdict_new();
qdict_put_obj(ud2_dict, "string0", QOBJECT(qstring_from_str(text)));
qiv = qmp_input_visitor_new(QOBJECT(ud2_dict));
visit_type_UserDefTwo(qmp_input_get_visitor(qiv), &ud2, NULL, &err);
qmp_input_visitor_cleanup(qiv);
QDECREF(ud2_dict);
}
/* verify partial success */
assert(ud2 != NULL);
assert(ud2->string0 != NULL);
assert(strcmp(ud2->string0, text) == 0);
qapi: Drop tests for inline nested structs A future patch will be using a 'name':{dictionary} entry in the QAPI schema to specify a default value for an optional argument; but existing use of inline nested structs conflicts with that goal. More precisely, a definition in the QAPI schema associates a name with a set of properties: Example 1: { 'struct': 'Foo', 'data': { MEMBERS... } } associates the global name 'Foo' with properties (meta-type struct) and MEMBERS... Example 2: 'mumble': TYPE within MEMBERS... above associates 'mumble' with properties (type TYPE) and (optional false) within type Foo The syntax of example 1 is extensible; if we need another property, we add another name/value pair to the dictionary (such as 'base':TYPE). The syntax of example 2 is not extensible, because the right hand side can only be a type. We have used name encoding to add a property: "'*mumble': 'int'" associates 'mumble' with (type int) and (optional true). Nice, but doesn't scale. So the solution is to change our existing uses to be syntactic sugar to an extensible form: NAME: TYPE --> NAME: { 'type': TYPE, 'optional': false } *ONAME: TYPE --> ONAME: { 'type': TYPE, 'optional': true } This patch fixes the testsuite to avoid inline nested types, by breaking the nesting into explicit types; it means that the type is now boxed instead of unboxed in C code, but makes no difference on the wire (and if desired, a later patch could change the generator to not do so much boxing in C). When touching code to add new allocations, also convert existing allocations to consistently prefer typesafe g_new0 over g_malloc0 when a type name is involved. Signed-off-by: Eric Blake <eblake@redhat.com> Reviewed-by: Markus Armbruster <armbru@redhat.com> Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-05-04 18:05:30 +03:00
assert(ud2->dict1 == NULL);
/* confirm & release construction error */
assert(err != NULL);
error_free(err);
/* tear down partial object */
qapi_free_UserDefTwo(ud2);
}
int main(int argc, char **argv)
{
g_test_init(&argc, &argv, NULL);
g_test_add_func("/0.15/dispatch_cmd", test_dispatch_cmd);
g_test_add_func("/0.15/dispatch_cmd_error", test_dispatch_cmd_error);
g_test_add_func("/0.15/dispatch_cmd_io", test_dispatch_cmd_io);
g_test_add_func("/0.15/dealloc_types", test_dealloc_types);
g_test_add_func("/0.15/dealloc_partial", test_dealloc_partial);
module_call_init(MODULE_INIT_QAPI);
g_test_run();
return 0;
}