qemu-e2k/tests/test-visitor-serialization.c

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/*
* Unit-tests for visitor-based serialization
*
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 17:05:30 +02:00
* Copyright (C) 2014-2015 Red Hat, Inc.
* Copyright IBM, Corp. 2012
*
* Authors:
* Michael Roth <mdroth@linux.vnet.ibm.com>
*
* This work is licensed under the terms of the GNU GPL, version 2 or later.
* See the COPYING file in the top-level directory.
*/
#include <glib.h>
#include <stdlib.h>
#include <stdint.h>
#include <float.h>
#include "qemu-common.h"
#include "test-qapi-types.h"
#include "test-qapi-visit.h"
#include "qapi/qmp/types.h"
#include "qapi/qmp-input-visitor.h"
#include "qapi/qmp-output-visitor.h"
#include "qapi/string-input-visitor.h"
#include "qapi/string-output-visitor.h"
#include "qapi-types.h"
#include "qapi-visit.h"
#include "qapi/dealloc-visitor.h"
enum PrimitiveTypeKind {
PTYPE_STRING = 0,
PTYPE_BOOLEAN,
PTYPE_NUMBER,
PTYPE_INTEGER,
PTYPE_U8,
PTYPE_U16,
PTYPE_U32,
PTYPE_U64,
PTYPE_S8,
PTYPE_S16,
PTYPE_S32,
PTYPE_S64,
PTYPE_EOL,
};
typedef struct PrimitiveType {
union {
const char *string;
bool boolean;
double number;
int64_t integer;
uint8_t u8;
uint16_t u16;
uint32_t u32;
uint64_t u64;
int8_t s8;
int16_t s16;
int32_t s32;
int64_t s64;
intmax_t max;
} value;
enum PrimitiveTypeKind type;
const char *description;
} PrimitiveType;
typedef struct PrimitiveList {
union {
strList *strings;
boolList *booleans;
numberList *numbers;
intList *integers;
int8List *s8_integers;
int16List *s16_integers;
int32List *s32_integers;
int64List *s64_integers;
uint8List *u8_integers;
uint16List *u16_integers;
uint32List *u32_integers;
uint64List *u64_integers;
} value;
enum PrimitiveTypeKind type;
const char *description;
} PrimitiveList;
/* test helpers */
typedef void (*VisitorFunc)(Visitor *v, void **native, Error **errp);
static void dealloc_helper(void *native_in, VisitorFunc visit, Error **errp)
{
QapiDeallocVisitor *qdv = qapi_dealloc_visitor_new();
visit(qapi_dealloc_get_visitor(qdv), &native_in, errp);
qapi_dealloc_visitor_cleanup(qdv);
}
static void visit_primitive_type(Visitor *v, void **native, Error **errp)
{
PrimitiveType *pt = *native;
switch(pt->type) {
case PTYPE_STRING:
visit_type_str(v, (char **)&pt->value.string, NULL, errp);
break;
case PTYPE_BOOLEAN:
visit_type_bool(v, &pt->value.boolean, NULL, errp);
break;
case PTYPE_NUMBER:
visit_type_number(v, &pt->value.number, NULL, errp);
break;
case PTYPE_INTEGER:
visit_type_int(v, &pt->value.integer, NULL, errp);
break;
case PTYPE_U8:
visit_type_uint8(v, &pt->value.u8, NULL, errp);
break;
case PTYPE_U16:
visit_type_uint16(v, &pt->value.u16, NULL, errp);
break;
case PTYPE_U32:
visit_type_uint32(v, &pt->value.u32, NULL, errp);
break;
case PTYPE_U64:
visit_type_uint64(v, &pt->value.u64, NULL, errp);
break;
case PTYPE_S8:
visit_type_int8(v, &pt->value.s8, NULL, errp);
break;
case PTYPE_S16:
visit_type_int16(v, &pt->value.s16, NULL, errp);
break;
case PTYPE_S32:
visit_type_int32(v, &pt->value.s32, NULL, errp);
break;
case PTYPE_S64:
visit_type_int64(v, &pt->value.s64, NULL, errp);
break;
case PTYPE_EOL:
g_assert_not_reached();
}
}
static void visit_primitive_list(Visitor *v, void **native, Error **errp)
{
PrimitiveList *pl = *native;
switch (pl->type) {
case PTYPE_STRING:
visit_type_strList(v, &pl->value.strings, NULL, errp);
break;
case PTYPE_BOOLEAN:
visit_type_boolList(v, &pl->value.booleans, NULL, errp);
break;
case PTYPE_NUMBER:
visit_type_numberList(v, &pl->value.numbers, NULL, errp);
break;
case PTYPE_INTEGER:
visit_type_intList(v, &pl->value.integers, NULL, errp);
break;
case PTYPE_S8:
visit_type_int8List(v, &pl->value.s8_integers, NULL, errp);
break;
case PTYPE_S16:
visit_type_int16List(v, &pl->value.s16_integers, NULL, errp);
break;
case PTYPE_S32:
visit_type_int32List(v, &pl->value.s32_integers, NULL, errp);
break;
case PTYPE_S64:
visit_type_int64List(v, &pl->value.s64_integers, NULL, errp);
break;
case PTYPE_U8:
visit_type_uint8List(v, &pl->value.u8_integers, NULL, errp);
break;
case PTYPE_U16:
visit_type_uint16List(v, &pl->value.u16_integers, NULL, errp);
break;
case PTYPE_U32:
visit_type_uint32List(v, &pl->value.u32_integers, NULL, errp);
break;
case PTYPE_U64:
visit_type_uint64List(v, &pl->value.u64_integers, NULL, errp);
break;
default:
g_assert_not_reached();
}
}
static TestStruct *struct_create(void)
{
TestStruct *ts = g_malloc0(sizeof(*ts));
ts->integer = -42;
ts->boolean = true;
ts->string = strdup("test string");
return ts;
}
static void struct_compare(TestStruct *ts1, TestStruct *ts2)
{
g_assert(ts1);
g_assert(ts2);
g_assert_cmpint(ts1->integer, ==, ts2->integer);
g_assert(ts1->boolean == ts2->boolean);
g_assert_cmpstr(ts1->string, ==, ts2->string);
}
static void struct_cleanup(TestStruct *ts)
{
g_free(ts->string);
g_free(ts);
}
static void visit_struct(Visitor *v, void **native, Error **errp)
{
visit_type_TestStruct(v, (TestStruct **)native, NULL, errp);
}
static UserDefTwo *nested_struct_create(void)
{
UserDefTwo *udnp = g_malloc0(sizeof(*udnp));
udnp->string0 = strdup("test_string0");
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 17:05:30 +02:00
udnp->dict1 = g_malloc0(sizeof(*udnp->dict1));
udnp->dict1->string1 = strdup("test_string1");
udnp->dict1->dict2 = g_malloc0(sizeof(*udnp->dict1->dict2));
udnp->dict1->dict2->userdef = g_new0(UserDefOne, 1);
qapi: Unbox base members Rather than storing a base class as a pointer to a box, just store the fields of that base class in the same order, so that a child struct can be directly cast to its parent. This gives less malloc overhead, less pointer dereferencing, and even less generated code. Compare to the earlier commit 1e6c1616a "qapi: Generate a nicer struct for flat unions" (although that patch had fewer places to change, as less of qemu was directly using qapi structs for flat unions). It also allows us to turn on automatic type-safe wrappers for upcasting to the base class of a struct. Changes to the generated code look like this in qapi-types.h: | struct SpiceChannel { |- SpiceBasicInfo *base; |+ /* Members inherited from SpiceBasicInfo: */ |+ char *host; |+ char *port; |+ NetworkAddressFamily family; |+ /* Own members: */ | int64_t connection_id; as well as additional upcast functions like qapi_SpiceChannel_base(). Meanwhile, changes to qapi-visit.c look like: | static void visit_type_SpiceChannel_fields(Visitor *v, SpiceChannel **obj, Error **errp) | { | Error *err = NULL; | |- visit_type_implicit_SpiceBasicInfo(v, &(*obj)->base, &err); |+ visit_type_SpiceBasicInfo_fields(v, (SpiceBasicInfo **)obj, &err); | if (err) { (the cast is necessary, since our upcast wrappers only deal with a single pointer, not pointer-to-pointer); plus the wholesale elimination of some now-unused visit_type_implicit_FOO() functions. Without boxing, the corner case of one empty struct having another empty struct as its base type now requires inserting a dummy member (previously, the 'Base *base' member sufficed). And now that we no longer consume a 'base' member in the generated C struct, we can delete the former negative struct-base-clash-base test. Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <1445898903-12082-11-git-send-email-eblake@redhat.com> [Commit message tweaked slightly] Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-10-26 23:34:49 +01:00
udnp->dict1->dict2->userdef->integer = 42;
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 17:05:30 +02:00
udnp->dict1->dict2->userdef->string = strdup("test_string");
udnp->dict1->dict2->string = strdup("test_string2");
udnp->dict1->dict3 = g_malloc0(sizeof(*udnp->dict1->dict3));
udnp->dict1->has_dict3 = true;
udnp->dict1->dict3->userdef = g_new0(UserDefOne, 1);
qapi: Unbox base members Rather than storing a base class as a pointer to a box, just store the fields of that base class in the same order, so that a child struct can be directly cast to its parent. This gives less malloc overhead, less pointer dereferencing, and even less generated code. Compare to the earlier commit 1e6c1616a "qapi: Generate a nicer struct for flat unions" (although that patch had fewer places to change, as less of qemu was directly using qapi structs for flat unions). It also allows us to turn on automatic type-safe wrappers for upcasting to the base class of a struct. Changes to the generated code look like this in qapi-types.h: | struct SpiceChannel { |- SpiceBasicInfo *base; |+ /* Members inherited from SpiceBasicInfo: */ |+ char *host; |+ char *port; |+ NetworkAddressFamily family; |+ /* Own members: */ | int64_t connection_id; as well as additional upcast functions like qapi_SpiceChannel_base(). Meanwhile, changes to qapi-visit.c look like: | static void visit_type_SpiceChannel_fields(Visitor *v, SpiceChannel **obj, Error **errp) | { | Error *err = NULL; | |- visit_type_implicit_SpiceBasicInfo(v, &(*obj)->base, &err); |+ visit_type_SpiceBasicInfo_fields(v, (SpiceBasicInfo **)obj, &err); | if (err) { (the cast is necessary, since our upcast wrappers only deal with a single pointer, not pointer-to-pointer); plus the wholesale elimination of some now-unused visit_type_implicit_FOO() functions. Without boxing, the corner case of one empty struct having another empty struct as its base type now requires inserting a dummy member (previously, the 'Base *base' member sufficed). And now that we no longer consume a 'base' member in the generated C struct, we can delete the former negative struct-base-clash-base test. Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <1445898903-12082-11-git-send-email-eblake@redhat.com> [Commit message tweaked slightly] Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-10-26 23:34:49 +01:00
udnp->dict1->dict3->userdef->integer = 43;
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 17:05:30 +02:00
udnp->dict1->dict3->userdef->string = strdup("test_string");
udnp->dict1->dict3->string = strdup("test_string3");
return udnp;
}
static void nested_struct_compare(UserDefTwo *udnp1, UserDefTwo *udnp2)
{
g_assert(udnp1);
g_assert(udnp2);
g_assert_cmpstr(udnp1->string0, ==, udnp2->string0);
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 17:05:30 +02:00
g_assert_cmpstr(udnp1->dict1->string1, ==, udnp2->dict1->string1);
qapi: Unbox base members Rather than storing a base class as a pointer to a box, just store the fields of that base class in the same order, so that a child struct can be directly cast to its parent. This gives less malloc overhead, less pointer dereferencing, and even less generated code. Compare to the earlier commit 1e6c1616a "qapi: Generate a nicer struct for flat unions" (although that patch had fewer places to change, as less of qemu was directly using qapi structs for flat unions). It also allows us to turn on automatic type-safe wrappers for upcasting to the base class of a struct. Changes to the generated code look like this in qapi-types.h: | struct SpiceChannel { |- SpiceBasicInfo *base; |+ /* Members inherited from SpiceBasicInfo: */ |+ char *host; |+ char *port; |+ NetworkAddressFamily family; |+ /* Own members: */ | int64_t connection_id; as well as additional upcast functions like qapi_SpiceChannel_base(). Meanwhile, changes to qapi-visit.c look like: | static void visit_type_SpiceChannel_fields(Visitor *v, SpiceChannel **obj, Error **errp) | { | Error *err = NULL; | |- visit_type_implicit_SpiceBasicInfo(v, &(*obj)->base, &err); |+ visit_type_SpiceBasicInfo_fields(v, (SpiceBasicInfo **)obj, &err); | if (err) { (the cast is necessary, since our upcast wrappers only deal with a single pointer, not pointer-to-pointer); plus the wholesale elimination of some now-unused visit_type_implicit_FOO() functions. Without boxing, the corner case of one empty struct having another empty struct as its base type now requires inserting a dummy member (previously, the 'Base *base' member sufficed). And now that we no longer consume a 'base' member in the generated C struct, we can delete the former negative struct-base-clash-base test. Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <1445898903-12082-11-git-send-email-eblake@redhat.com> [Commit message tweaked slightly] Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-10-26 23:34:49 +01:00
g_assert_cmpint(udnp1->dict1->dict2->userdef->integer, ==,
udnp2->dict1->dict2->userdef->integer);
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 17:05:30 +02:00
g_assert_cmpstr(udnp1->dict1->dict2->userdef->string, ==,
udnp2->dict1->dict2->userdef->string);
g_assert_cmpstr(udnp1->dict1->dict2->string, ==,
udnp2->dict1->dict2->string);
g_assert(udnp1->dict1->has_dict3 == udnp2->dict1->has_dict3);
qapi: Unbox base members Rather than storing a base class as a pointer to a box, just store the fields of that base class in the same order, so that a child struct can be directly cast to its parent. This gives less malloc overhead, less pointer dereferencing, and even less generated code. Compare to the earlier commit 1e6c1616a "qapi: Generate a nicer struct for flat unions" (although that patch had fewer places to change, as less of qemu was directly using qapi structs for flat unions). It also allows us to turn on automatic type-safe wrappers for upcasting to the base class of a struct. Changes to the generated code look like this in qapi-types.h: | struct SpiceChannel { |- SpiceBasicInfo *base; |+ /* Members inherited from SpiceBasicInfo: */ |+ char *host; |+ char *port; |+ NetworkAddressFamily family; |+ /* Own members: */ | int64_t connection_id; as well as additional upcast functions like qapi_SpiceChannel_base(). Meanwhile, changes to qapi-visit.c look like: | static void visit_type_SpiceChannel_fields(Visitor *v, SpiceChannel **obj, Error **errp) | { | Error *err = NULL; | |- visit_type_implicit_SpiceBasicInfo(v, &(*obj)->base, &err); |+ visit_type_SpiceBasicInfo_fields(v, (SpiceBasicInfo **)obj, &err); | if (err) { (the cast is necessary, since our upcast wrappers only deal with a single pointer, not pointer-to-pointer); plus the wholesale elimination of some now-unused visit_type_implicit_FOO() functions. Without boxing, the corner case of one empty struct having another empty struct as its base type now requires inserting a dummy member (previously, the 'Base *base' member sufficed). And now that we no longer consume a 'base' member in the generated C struct, we can delete the former negative struct-base-clash-base test. Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <1445898903-12082-11-git-send-email-eblake@redhat.com> [Commit message tweaked slightly] Signed-off-by: Markus Armbruster <armbru@redhat.com>
2015-10-26 23:34:49 +01:00
g_assert_cmpint(udnp1->dict1->dict3->userdef->integer, ==,
udnp2->dict1->dict3->userdef->integer);
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 17:05:30 +02:00
g_assert_cmpstr(udnp1->dict1->dict3->userdef->string, ==,
udnp2->dict1->dict3->userdef->string);
g_assert_cmpstr(udnp1->dict1->dict3->string, ==,
udnp2->dict1->dict3->string);
}
static void nested_struct_cleanup(UserDefTwo *udnp)
{
qapi_free_UserDefTwo(udnp);
}
static void visit_nested_struct(Visitor *v, void **native, Error **errp)
{
visit_type_UserDefTwo(v, (UserDefTwo **)native, NULL, errp);
}
static void visit_nested_struct_list(Visitor *v, void **native, Error **errp)
{
visit_type_UserDefTwoList(v, (UserDefTwoList **)native, NULL, errp);
}
/* test cases */
typedef enum VisitorCapabilities {
VCAP_PRIMITIVES = 1,
VCAP_STRUCTURES = 2,
VCAP_LISTS = 4,
VCAP_PRIMITIVE_LISTS = 8,
} VisitorCapabilities;
typedef struct SerializeOps {
void (*serialize)(void *native_in, void **datap,
VisitorFunc visit, Error **errp);
void (*deserialize)(void **native_out, void *datap,
VisitorFunc visit, Error **errp);
void (*cleanup)(void *datap);
const char *type;
VisitorCapabilities caps;
} SerializeOps;
typedef struct TestArgs {
const SerializeOps *ops;
void *test_data;
} TestArgs;
static void test_primitives(gconstpointer opaque)
{
TestArgs *args = (TestArgs *) opaque;
const SerializeOps *ops = args->ops;
PrimitiveType *pt = args->test_data;
PrimitiveType *pt_copy = g_malloc0(sizeof(*pt_copy));
void *serialize_data;
pt_copy->type = pt->type;
ops->serialize(pt, &serialize_data, visit_primitive_type, &error_abort);
ops->deserialize((void **)&pt_copy, serialize_data, visit_primitive_type,
&error_abort);
g_assert(pt_copy != NULL);
if (pt->type == PTYPE_STRING) {
g_assert_cmpstr(pt->value.string, ==, pt_copy->value.string);
g_free((char *)pt_copy->value.string);
} else if (pt->type == PTYPE_NUMBER) {
GString *double_expected = g_string_new("");
GString *double_actual = g_string_new("");
/* we serialize with %f for our reference visitors, so rather than fuzzy
* floating math to test "equality", just compare the formatted values
*/
g_string_printf(double_expected, "%.6f", pt->value.number);
g_string_printf(double_actual, "%.6f", pt_copy->value.number);
g_assert_cmpstr(double_actual->str, ==, double_expected->str);
g_string_free(double_expected, true);
g_string_free(double_actual, true);
} else if (pt->type == PTYPE_BOOLEAN) {
g_assert_cmpint(!!pt->value.max, ==, !!pt->value.max);
} else {
g_assert_cmpint(pt->value.max, ==, pt_copy->value.max);
}
ops->cleanup(serialize_data);
g_free(args);
g_free(pt_copy);
}
static void test_primitive_lists(gconstpointer opaque)
{
TestArgs *args = (TestArgs *) opaque;
const SerializeOps *ops = args->ops;
PrimitiveType *pt = args->test_data;
PrimitiveList pl = { .value = { NULL } };
PrimitiveList pl_copy = { .value = { NULL } };
PrimitiveList *pl_copy_ptr = &pl_copy;
void *serialize_data;
void *cur_head = NULL;
int i;
pl.type = pl_copy.type = pt->type;
/* build up our list of primitive types */
for (i = 0; i < 32; i++) {
switch (pl.type) {
case PTYPE_STRING: {
strList *tmp = g_new0(strList, 1);
tmp->value = g_strdup(pt->value.string);
if (pl.value.strings == NULL) {
pl.value.strings = tmp;
} else {
tmp->next = pl.value.strings;
pl.value.strings = tmp;
}
break;
}
case PTYPE_INTEGER: {
intList *tmp = g_new0(intList, 1);
tmp->value = pt->value.integer;
if (pl.value.integers == NULL) {
pl.value.integers = tmp;
} else {
tmp->next = pl.value.integers;
pl.value.integers = tmp;
}
break;
}
case PTYPE_S8: {
int8List *tmp = g_new0(int8List, 1);
tmp->value = pt->value.s8;
if (pl.value.s8_integers == NULL) {
pl.value.s8_integers = tmp;
} else {
tmp->next = pl.value.s8_integers;
pl.value.s8_integers = tmp;
}
break;
}
case PTYPE_S16: {
int16List *tmp = g_new0(int16List, 1);
tmp->value = pt->value.s16;
if (pl.value.s16_integers == NULL) {
pl.value.s16_integers = tmp;
} else {
tmp->next = pl.value.s16_integers;
pl.value.s16_integers = tmp;
}
break;
}
case PTYPE_S32: {
int32List *tmp = g_new0(int32List, 1);
tmp->value = pt->value.s32;
if (pl.value.s32_integers == NULL) {
pl.value.s32_integers = tmp;
} else {
tmp->next = pl.value.s32_integers;
pl.value.s32_integers = tmp;
}
break;
}
case PTYPE_S64: {
int64List *tmp = g_new0(int64List, 1);
tmp->value = pt->value.s64;
if (pl.value.s64_integers == NULL) {
pl.value.s64_integers = tmp;
} else {
tmp->next = pl.value.s64_integers;
pl.value.s64_integers = tmp;
}
break;
}
case PTYPE_U8: {
uint8List *tmp = g_new0(uint8List, 1);
tmp->value = pt->value.u8;
if (pl.value.u8_integers == NULL) {
pl.value.u8_integers = tmp;
} else {
tmp->next = pl.value.u8_integers;
pl.value.u8_integers = tmp;
}
break;
}
case PTYPE_U16: {
uint16List *tmp = g_new0(uint16List, 1);
tmp->value = pt->value.u16;
if (pl.value.u16_integers == NULL) {
pl.value.u16_integers = tmp;
} else {
tmp->next = pl.value.u16_integers;
pl.value.u16_integers = tmp;
}
break;
}
case PTYPE_U32: {
uint32List *tmp = g_new0(uint32List, 1);
tmp->value = pt->value.u32;
if (pl.value.u32_integers == NULL) {
pl.value.u32_integers = tmp;
} else {
tmp->next = pl.value.u32_integers;
pl.value.u32_integers = tmp;
}
break;
}
case PTYPE_U64: {
uint64List *tmp = g_new0(uint64List, 1);
tmp->value = pt->value.u64;
if (pl.value.u64_integers == NULL) {
pl.value.u64_integers = tmp;
} else {
tmp->next = pl.value.u64_integers;
pl.value.u64_integers = tmp;
}
break;
}
case PTYPE_NUMBER: {
numberList *tmp = g_new0(numberList, 1);
tmp->value = pt->value.number;
if (pl.value.numbers == NULL) {
pl.value.numbers = tmp;
} else {
tmp->next = pl.value.numbers;
pl.value.numbers = tmp;
}
break;
}
case PTYPE_BOOLEAN: {
boolList *tmp = g_new0(boolList, 1);
tmp->value = pt->value.boolean;
if (pl.value.booleans == NULL) {
pl.value.booleans = tmp;
} else {
tmp->next = pl.value.booleans;
pl.value.booleans = tmp;
}
break;
}
default:
g_assert_not_reached();
}
}
ops->serialize((void **)&pl, &serialize_data, visit_primitive_list,
&error_abort);
ops->deserialize((void **)&pl_copy_ptr, serialize_data,
visit_primitive_list, &error_abort);
i = 0;
/* compare our deserialized list of primitives to the original */
do {
switch (pl_copy.type) {
case PTYPE_STRING: {
strList *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.strings;
}
g_assert_cmpstr(pt->value.string, ==, ptr->value);
break;
}
case PTYPE_INTEGER: {
intList *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.integers;
}
g_assert_cmpint(pt->value.integer, ==, ptr->value);
break;
}
case PTYPE_S8: {
int8List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.s8_integers;
}
g_assert_cmpint(pt->value.s8, ==, ptr->value);
break;
}
case PTYPE_S16: {
int16List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.s16_integers;
}
g_assert_cmpint(pt->value.s16, ==, ptr->value);
break;
}
case PTYPE_S32: {
int32List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.s32_integers;
}
g_assert_cmpint(pt->value.s32, ==, ptr->value);
break;
}
case PTYPE_S64: {
int64List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.s64_integers;
}
g_assert_cmpint(pt->value.s64, ==, ptr->value);
break;
}
case PTYPE_U8: {
uint8List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.u8_integers;
}
g_assert_cmpint(pt->value.u8, ==, ptr->value);
break;
}
case PTYPE_U16: {
uint16List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.u16_integers;
}
g_assert_cmpint(pt->value.u16, ==, ptr->value);
break;
}
case PTYPE_U32: {
uint32List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.u32_integers;
}
g_assert_cmpint(pt->value.u32, ==, ptr->value);
break;
}
case PTYPE_U64: {
uint64List *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.u64_integers;
}
g_assert_cmpint(pt->value.u64, ==, ptr->value);
break;
}
case PTYPE_NUMBER: {
numberList *ptr;
GString *double_expected = g_string_new("");
GString *double_actual = g_string_new("");
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.numbers;
}
/* we serialize with %f for our reference visitors, so rather than
* fuzzy floating math to test "equality", just compare the
* formatted values
*/
g_string_printf(double_expected, "%.6f", pt->value.number);
g_string_printf(double_actual, "%.6f", ptr->value);
g_assert_cmpstr(double_actual->str, ==, double_expected->str);
g_string_free(double_expected, true);
g_string_free(double_actual, true);
break;
}
case PTYPE_BOOLEAN: {
boolList *ptr;
if (cur_head) {
ptr = cur_head;
cur_head = ptr->next;
} else {
cur_head = ptr = pl_copy.value.booleans;
}
g_assert_cmpint(!!pt->value.boolean, ==, !!ptr->value);
break;
}
default:
g_assert_not_reached();
}
i++;
} while (cur_head);
g_assert_cmpint(i, ==, 33);
ops->cleanup(serialize_data);
dealloc_helper(&pl, visit_primitive_list, &error_abort);
dealloc_helper(&pl_copy, visit_primitive_list, &error_abort);
g_free(args);
}
static void test_struct(gconstpointer opaque)
{
TestArgs *args = (TestArgs *) opaque;
const SerializeOps *ops = args->ops;
TestStruct *ts = struct_create();
TestStruct *ts_copy = NULL;
void *serialize_data;
ops->serialize(ts, &serialize_data, visit_struct, &error_abort);
ops->deserialize((void **)&ts_copy, serialize_data, visit_struct,
&error_abort);
struct_compare(ts, ts_copy);
struct_cleanup(ts);
struct_cleanup(ts_copy);
ops->cleanup(serialize_data);
g_free(args);
}
static void test_nested_struct(gconstpointer opaque)
{
TestArgs *args = (TestArgs *) opaque;
const SerializeOps *ops = args->ops;
UserDefTwo *udnp = nested_struct_create();
UserDefTwo *udnp_copy = NULL;
void *serialize_data;
ops->serialize(udnp, &serialize_data, visit_nested_struct, &error_abort);
ops->deserialize((void **)&udnp_copy, serialize_data, visit_nested_struct,
&error_abort);
nested_struct_compare(udnp, udnp_copy);
nested_struct_cleanup(udnp);
nested_struct_cleanup(udnp_copy);
ops->cleanup(serialize_data);
g_free(args);
}
static void test_nested_struct_list(gconstpointer opaque)
{
TestArgs *args = (TestArgs *) opaque;
const SerializeOps *ops = args->ops;
UserDefTwoList *listp = NULL, *tmp, *tmp_copy, *listp_copy = NULL;
void *serialize_data;
int i = 0;
for (i = 0; i < 8; i++) {
tmp = g_new0(UserDefTwoList, 1);
tmp->value = nested_struct_create();
tmp->next = listp;
listp = tmp;
}
ops->serialize(listp, &serialize_data, visit_nested_struct_list,
&error_abort);
ops->deserialize((void **)&listp_copy, serialize_data,
visit_nested_struct_list, &error_abort);
tmp = listp;
tmp_copy = listp_copy;
while (listp_copy) {
g_assert(listp);
nested_struct_compare(listp->value, listp_copy->value);
listp = listp->next;
listp_copy = listp_copy->next;
}
qapi_free_UserDefTwoList(tmp);
qapi_free_UserDefTwoList(tmp_copy);
ops->cleanup(serialize_data);
g_free(args);
}
static PrimitiveType pt_values[] = {
/* string tests */
{
.description = "string_empty",
.type = PTYPE_STRING,
.value.string = "",
},
{
.description = "string_whitespace",
.type = PTYPE_STRING,
.value.string = "a b c\td",
},
{
.description = "string_newlines",
.type = PTYPE_STRING,
.value.string = "a\nb\n",
},
{
.description = "string_commas",
.type = PTYPE_STRING,
.value.string = "a,b, c,d",
},
{
.description = "string_single_quoted",
.type = PTYPE_STRING,
.value.string = "'a b',cd",
},
{
.description = "string_double_quoted",
.type = PTYPE_STRING,
.value.string = "\"a b\",cd",
},
/* boolean tests */
{
.description = "boolean_true1",
.type = PTYPE_BOOLEAN,
.value.boolean = true,
},
{
.description = "boolean_true2",
.type = PTYPE_BOOLEAN,
.value.boolean = 8,
},
{
.description = "boolean_true3",
.type = PTYPE_BOOLEAN,
.value.boolean = -1,
},
{
.description = "boolean_false1",
.type = PTYPE_BOOLEAN,
.value.boolean = false,
},
{
.description = "boolean_false2",
.type = PTYPE_BOOLEAN,
.value.boolean = 0,
},
/* number tests (double) */
/* note: we format these to %.6f before comparing, since that's how
* we serialize them and it doesn't make sense to check precision
* beyond that.
*/
{
.description = "number_sanity1",
.type = PTYPE_NUMBER,
.value.number = -1,
},
{
.description = "number_sanity2",
.type = PTYPE_NUMBER,
.value.number = 3.14159265,
},
{
.description = "number_min",
.type = PTYPE_NUMBER,
.value.number = DBL_MIN,
},
{
.description = "number_max",
.type = PTYPE_NUMBER,
.value.number = DBL_MAX,
},
/* integer tests (int64) */
{
.description = "integer_sanity1",
.type = PTYPE_INTEGER,
.value.integer = -1,
},
{
.description = "integer_sanity2",
.type = PTYPE_INTEGER,
.value.integer = INT64_MAX / 2 + 1,
},
{
.description = "integer_min",
.type = PTYPE_INTEGER,
.value.integer = INT64_MIN,
},
{
.description = "integer_max",
.type = PTYPE_INTEGER,
.value.integer = INT64_MAX,
},
/* uint8 tests */
{
.description = "uint8_sanity1",
.type = PTYPE_U8,
.value.u8 = 1,
},
{
.description = "uint8_sanity2",
.type = PTYPE_U8,
.value.u8 = UINT8_MAX / 2 + 1,
},
{
.description = "uint8_min",
.type = PTYPE_U8,
.value.u8 = 0,
},
{
.description = "uint8_max",
.type = PTYPE_U8,
.value.u8 = UINT8_MAX,
},
/* uint16 tests */
{
.description = "uint16_sanity1",
.type = PTYPE_U16,
.value.u16 = 1,
},
{
.description = "uint16_sanity2",
.type = PTYPE_U16,
.value.u16 = UINT16_MAX / 2 + 1,
},
{
.description = "uint16_min",
.type = PTYPE_U16,
.value.u16 = 0,
},
{
.description = "uint16_max",
.type = PTYPE_U16,
.value.u16 = UINT16_MAX,
},
/* uint32 tests */
{
.description = "uint32_sanity1",
.type = PTYPE_U32,
.value.u32 = 1,
},
{
.description = "uint32_sanity2",
.type = PTYPE_U32,
.value.u32 = UINT32_MAX / 2 + 1,
},
{
.description = "uint32_min",
.type = PTYPE_U32,
.value.u32 = 0,
},
{
.description = "uint32_max",
.type = PTYPE_U32,
.value.u32 = UINT32_MAX,
},
/* uint64 tests */
{
.description = "uint64_sanity1",
.type = PTYPE_U64,
.value.u64 = 1,
},
{
.description = "uint64_sanity2",
.type = PTYPE_U64,
.value.u64 = UINT64_MAX / 2 + 1,
},
{
.description = "uint64_min",
.type = PTYPE_U64,
.value.u64 = 0,
},
{
.description = "uint64_max",
.type = PTYPE_U64,
.value.u64 = UINT64_MAX,
},
/* int8 tests */
{
.description = "int8_sanity1",
.type = PTYPE_S8,
.value.s8 = -1,
},
{
.description = "int8_sanity2",
.type = PTYPE_S8,
.value.s8 = INT8_MAX / 2 + 1,
},
{
.description = "int8_min",
.type = PTYPE_S8,
.value.s8 = INT8_MIN,
},
{
.description = "int8_max",
.type = PTYPE_S8,
.value.s8 = INT8_MAX,
},
/* int16 tests */
{
.description = "int16_sanity1",
.type = PTYPE_S16,
.value.s16 = -1,
},
{
.description = "int16_sanity2",
.type = PTYPE_S16,
.value.s16 = INT16_MAX / 2 + 1,
},
{
.description = "int16_min",
.type = PTYPE_S16,
.value.s16 = INT16_MIN,
},
{
.description = "int16_max",
.type = PTYPE_S16,
.value.s16 = INT16_MAX,
},
/* int32 tests */
{
.description = "int32_sanity1",
.type = PTYPE_S32,
.value.s32 = -1,
},
{
.description = "int32_sanity2",
.type = PTYPE_S32,
.value.s32 = INT32_MAX / 2 + 1,
},
{
.description = "int32_min",
.type = PTYPE_S32,
.value.s32 = INT32_MIN,
},
{
.description = "int32_max",
.type = PTYPE_S32,
.value.s32 = INT32_MAX,
},
/* int64 tests */
{
.description = "int64_sanity1",
.type = PTYPE_S64,
.value.s64 = -1,
},
{
.description = "int64_sanity2",
.type = PTYPE_S64,
.value.s64 = INT64_MAX / 2 + 1,
},
{
.description = "int64_min",
.type = PTYPE_S64,
.value.s64 = INT64_MIN,
},
{
.description = "int64_max",
.type = PTYPE_S64,
.value.s64 = INT64_MAX,
},
{ .type = PTYPE_EOL }
};
/* visitor-specific op implementations */
typedef struct QmpSerializeData {
QmpOutputVisitor *qov;
QmpInputVisitor *qiv;
} QmpSerializeData;
static void qmp_serialize(void *native_in, void **datap,
VisitorFunc visit, Error **errp)
{
QmpSerializeData *d = g_malloc0(sizeof(*d));
d->qov = qmp_output_visitor_new();
visit(qmp_output_get_visitor(d->qov), &native_in, errp);
*datap = d;
}
static void qmp_deserialize(void **native_out, void *datap,
VisitorFunc visit, Error **errp)
{
QmpSerializeData *d = datap;
QString *output_json;
QObject *obj_orig, *obj;
obj_orig = qmp_output_get_qobject(d->qov);
output_json = qobject_to_json(obj_orig);
obj = qobject_from_json(qstring_get_str(output_json));
QDECREF(output_json);
d->qiv = qmp_input_visitor_new(obj);
qobject_decref(obj_orig);
qobject_decref(obj);
visit(qmp_input_get_visitor(d->qiv), native_out, errp);
}
static void qmp_cleanup(void *datap)
{
QmpSerializeData *d = datap;
qmp_output_visitor_cleanup(d->qov);
qmp_input_visitor_cleanup(d->qiv);
g_free(d);
}
typedef struct StringSerializeData {
char *string;
StringOutputVisitor *sov;
StringInputVisitor *siv;
} StringSerializeData;
static void string_serialize(void *native_in, void **datap,
VisitorFunc visit, Error **errp)
{
StringSerializeData *d = g_malloc0(sizeof(*d));
d->sov = string_output_visitor_new(false);
visit(string_output_get_visitor(d->sov), &native_in, errp);
*datap = d;
}
static void string_deserialize(void **native_out, void *datap,
VisitorFunc visit, Error **errp)
{
StringSerializeData *d = datap;
d->string = string_output_get_string(d->sov);
d->siv = string_input_visitor_new(d->string);
visit(string_input_get_visitor(d->siv), native_out, errp);
}
static void string_cleanup(void *datap)
{
StringSerializeData *d = datap;
string_output_visitor_cleanup(d->sov);
string_input_visitor_cleanup(d->siv);
g_free(d->string);
g_free(d);
}
/* visitor registration, test harness */
/* note: to function interchangeably as a serialization mechanism your
* visitor test implementation should pass the test cases for all visitor
* capabilities: primitives, structures, and lists
*/
static const SerializeOps visitors[] = {
{
.type = "QMP",
.serialize = qmp_serialize,
.deserialize = qmp_deserialize,
.cleanup = qmp_cleanup,
.caps = VCAP_PRIMITIVES | VCAP_STRUCTURES | VCAP_LISTS |
VCAP_PRIMITIVE_LISTS
},
{
.type = "String",
.serialize = string_serialize,
.deserialize = string_deserialize,
.cleanup = string_cleanup,
.caps = VCAP_PRIMITIVES
},
{ NULL }
};
static void add_visitor_type(const SerializeOps *ops)
{
char testname_prefix[128];
char testname[128];
TestArgs *args;
int i = 0;
sprintf(testname_prefix, "/visitor/serialization/%s", ops->type);
if (ops->caps & VCAP_PRIMITIVES) {
while (pt_values[i].type != PTYPE_EOL) {
sprintf(testname, "%s/primitives/%s", testname_prefix,
pt_values[i].description);
args = g_malloc0(sizeof(*args));
args->ops = ops;
args->test_data = &pt_values[i];
g_test_add_data_func(testname, args, test_primitives);
i++;
}
}
if (ops->caps & VCAP_STRUCTURES) {
sprintf(testname, "%s/struct", testname_prefix);
args = g_malloc0(sizeof(*args));
args->ops = ops;
args->test_data = NULL;
g_test_add_data_func(testname, args, test_struct);
sprintf(testname, "%s/nested_struct", testname_prefix);
args = g_malloc0(sizeof(*args));
args->ops = ops;
args->test_data = NULL;
g_test_add_data_func(testname, args, test_nested_struct);
}
if (ops->caps & VCAP_LISTS) {
sprintf(testname, "%s/nested_struct_list", testname_prefix);
args = g_malloc0(sizeof(*args));
args->ops = ops;
args->test_data = NULL;
g_test_add_data_func(testname, args, test_nested_struct_list);
}
if (ops->caps & VCAP_PRIMITIVE_LISTS) {
i = 0;
while (pt_values[i].type != PTYPE_EOL) {
sprintf(testname, "%s/primitive_list/%s", testname_prefix,
pt_values[i].description);
args = g_malloc0(sizeof(*args));
args->ops = ops;
args->test_data = &pt_values[i];
g_test_add_data_func(testname, args, test_primitive_lists);
i++;
}
}
}
int main(int argc, char **argv)
{
int i = 0;
g_test_init(&argc, &argv, NULL);
while (visitors[i].type != NULL) {
add_visitor_type(&visitors[i]);
i++;
}
g_test_run();
return 0;
}