接前一篇文章:QEMU源码全解析34 —— Machine(4)
本文内容参考:
《QEMU/KVM》源码解析与应用 —— 李强,机械工业出版社
特此致谢!
上回书说到有3个函数需要弄清楚:(1)object_class_get_list_tramp;(2)object_foreach_tramp;(3)type_table_get。本回对于这3个函数进行解析。
为了便于理解,再次贴出qom/object.c中的object_class_get_list函数以及其调用的同文件中的object_class_foreach函数,代码分别如下:
GSList *object_class_get_list(const char *implements_type,
bool include_abstract)
{
GSList *list = NULL;
object_class_foreach(object_class_get_list_tramp,
implements_type, include_abstract, &list);
return list;
}void object_class_foreach(void (*fn)(ObjectClass *klass, void *opaque),
const char *implements_type, bool include_abstract,
void *opaque)
{
OCFData data = { fn, implements_type, include_abstract, opaque };
enumerating_types = true;
g_hash_table_foreach(type_table_get(), object_class_foreach_tramp, &data);
enumerating_types = false;
}先来看第1个函数type_table_get,也在qom/object.c中,代码如下:
static GHashTable *type_table_get(void)
{
static GHashTable *type_table;
if (type_table == NULL) {
type_table = g_hash_table_new(g_str_hash, g_str_equal);
}
return type_table;
}在全局表type_table_get()即返回的type_table中,对于每一项TypeImpl,都执行object_class_foreach_tramp。
再来看第2个函数object_class_foreach_tramp,从名字上就能看出来,它也是在qom/object.c中。代码如下:
static void object_class_foreach_tramp(gpointer key, gpointer value,
gpointer opaque)
{
OCFData *data = opaque;
TypeImpl *type = value;
ObjectClass *k;
type_initialize(type);
k = type->class;
if (!data->include_abstract && type->abstract) {
return;
}
if (data->implements_type &&
!object_class_dynamic_cast(k, data->implements_type)) {
return;
}
data->fn(k, data->opaque);
}object_class_foreach_tramp函数的参数OCFData *data实际指向了object_class_foreach函数中的data,即OCFData data = { fn, implements_type, include_abstract, opaque }。代入上下文的实际值GSList *machines = object_class_get_list(TYPE_MACHINE, false),最终是:OCFData data = { fn, TYPE_MACHINE, false, &list }。
我们在前文书讲QOM的时候详细解析过type_initialize函数,其作用是类的初始化,这里当然是对TYPE_MACHINE即"machine"类的初始化。type_initialize函数中会调用class_init函数将纸面上的class即TypeImpl转变为ObjectClass。前文书也提到过,ObjectClass是所有Class类的祖先,而这里的MachineClass是其子类。
函数最后的data->fn(k, data->opaque)代入实际值为object_class_get_list_tramp(type->class, &list)。
最后看第3个函数object_class_get_list_tramp,其也在qom/object.c中,代码如下:
static void object_class_get_list_tramp(ObjectClass *klass, void *opaque)
{
GSList **list = opaque;
*list = g_slist_prepend(*list, klass);
}
在命令行中传入"-machine xx-xxx-xxx"也好,不指定相关值而使用默认值也罢,最终都能够找到之前已注册过的TypeImpl,并调用它的class_init函数。因而pc_machine_##suffix##class_init即“.class_init = pc_machine_v7_1_class_init”会被调用。再次给出相关代码,如下:
static void pc_init_v7_1(MachineState *machine)
{
void (*compat)(MachineState *m) = (NULL);
if (compat) {
compat(machine);
}
pc_init1(machine, TYPE_I440FX_PCI_HOST_BRIDGE, \
TYPE_I440FX_PCI_DEVICE);
}
static void pc_machine_v7_1_class_init(ObjectClass *oc, void *data)
{
MachineClass *mc = MACHINE_CLASS(oc);
pc_i440fx_7_1_machine_options(mc);
mc->init = pc_init_v7_1;
}
static const TypeInfo pc_machine_type_v7_1 = {
.name = "pc-i440fx-7.1" TYPE_MACHINE_SUFFIX,
.parent = TYPE_PC_MACHINE,
.class_init = pc_machine_v7_1_class_init,
};
static void pc_machine_init_v7_1(void)
{
type_register(&pc_machine_type_v7_1);
}在pc_machine_##suffix##class_init即pc_machine_v7_1_class_init函数中,pc_i440fx_7_1_machine_options函数才真正被调用以初始化MachineClass,并将MachineClass的init函数设置为pc_init##suffix即pc_init_v7_1。也即,当select_machine执行完毕后,就有一个MachineClass了。
pc_i440fx_7_1_machine_options函数在hw/i386/pc_piix.c中,代码如下:
static void pc_i440fx_7_1_machine_options(MachineClass *m)
{
PCMachineClass *pcmc = PC_MACHINE_CLASS(m);
pc_i440fx_machine_options(m);
m->alias = "pc";
m->is_default = true;
pcmc->default_cpu_version = 1;
pcmc->legacy_no_rng_seed = true;
}pc_i440fx_machine_options函数就在上边,代码如下:
static void pc_i440fx_machine_options(MachineClass *m)
{
PCMachineClass *pcmc = PC_MACHINE_CLASS(m);
pcmc->default_nic_model = "e1000";
pcmc->pci_root_uid = 0;
m->family = "pc_piix";
m->desc = "Standard PC (i440FX + PIIX, 1996)";
m->default_machine_opts = "firmware=bios-256k.bin";
m->default_display = "std";
machine_class_allow_dynamic_sysbus_dev(m, TYPE_RAMFB_DEVICE);
machine_class_allow_dynamic_sysbus_dev(m, TYPE_VMBUS_BRIDGE);
}本回内容较多,需要认真结合前文反复理解,也算作一个对前文的复习回顾。介绍完了这3个函数后,回到select_machine函数中,继续往下进行解析。详情请看下文。