virtio pci设备基础
这段时间又再次revisit了一把virtio,把笔记整理一下贴出来,大部分内容都是网上找的,+上我个人的一些理解在里面
我们首先关注virtio设备的配置空间,virtio设备本身是基于PCI总线的,因此本质上就是一个PCI设备,和所有其他PCI设备一样,virtio也有自己的vendor ID 0x1AF4,device ID从0x1000 - 0x103F,subsystem device ID如下:
Subsystem Device ID |
Virtio Device |
|---|---|
1 |
Network card |
2 |
Block device |
3 |
Console |
4 |
Entropy source |
5 |
Memory ballooning |
6 |
IoMemory |
7 |
Rpmsg |
8 |
SCSI host |
9 |
9P transport |
10 |
Mac80211 wlan |
virtio设备的第一块IO region(BAR0指向的空间?)用来存放virtio设备的配置空间,如下所示:
Bits |
32 |
32 |
32 |
16 |
16 |
16 |
8 |
8 |
|---|---|---|---|---|---|---|---|---|
R/W |
R |
R+W |
R+W |
R |
R+W |
R+W |
R+W |
R |
Purpose |
Device Features |
GuestFeatures |
QueueAddress |
QueueSize |
Queue Select |
Queue Notify |
Device Status |
ISR Status |
Bits |
16 |
16 |
|---|---|---|
R/W |
R+W |
R+W |
Purpose(MSI-X) |
Configuration Vector |
Queue Vector |
如果配置空间包含了后面两个域,即CONFIG_VECTOR以及QUEUE_VECTOR,表明这个PCI设备开启了MSI-X中断,否则后面两个域不会在配置空间中。内核定义了一个VIRTIO_PCI_CONFIG宏,用于计算配置空间的大小,如果开启了MSI-X中断则是24字节,否则是20字节
/* The remaining space is defined by each driver as the per-driver * configuration space */ #define VIRTIO_PCI_CONFIG(dev) ((dev)->msix_enabled ? 24 : 20)
可以从内核include/linux/virtio_pci.h中找到virtio配置空间的定义代码
/* A 32-bit r/o bitmask of the features supported by the host */ #define VIRTIO_PCI_HOST_FEATURES 0 /* A 32-bit r/w bitmask of features activated by the guest */ #define VIRTIO_PCI_GUEST_FEATURES 4 /* A 32-bit r/w PFN for the currently selected queue */ #define VIRTIO_PCI_QUEUE_PFN 8 /* A 16-bit r/o queue size for the currently selected queue */ #define VIRTIO_PCI_QUEUE_NUM 12 /* A 16-bit r/w queue selector */ #define VIRTIO_PCI_QUEUE_SEL 14 /* A 16-bit r/w queue notifier */ #define VIRTIO_PCI_QUEUE_NOTIFY 16 /* An 8-bit device status register. */ #define VIRTIO_PCI_STATUS 18 /* An 8-bit r/o interrupt status register. Reading the value will return the * current contents of the ISR and will also clear it. This is effectively * a read-and-acknowledge. */ #define VIRTIO_PCI_ISR 19 /* The bit of the ISR which indicates a device configuration change. */ #define VIRTIO_PCI_ISR_CONFIG 0x2 /* MSI-X registers: only enabled if MSI-X is enabled. */ /* A 16-bit vector for configuration changes. */ #define VIRTIO_MSI_CONFIG_VECTOR 20 /* A 16-bit vector for selected queue notifications. */ #define VIRTIO_MSI_QUEUE_VECTOR 22 /* Vector value used to disable MSI for queue */ #define VIRTIO_MSI_NO_VECTOR 0xffff在24/20字节之后,会存放设备自己的配置域,这里就不展开了
关于PCI的规范和细节,可以参考如下的文章
http://blog.chinaunix.net/uid-618506-id-204331.html
http://blog.sina.com.cn/s/blog_6472c4cc0100qnht.html
http://blog.csdn.net/yayong/article/details/4013299
按照我的理解,这里virtio设备的配置空间,和PCI设备的配置空间是完全不同的概念,virtio自己的配置实际上是占用的bar0指向的一块IO区域来完成的。对于传统的PCI设备,其配置空间是通过PCI规范严格定义好的,目前对于普通PCI设备是256个字节,对于PCIE设备是2k个字节,其中前64个字节称为PCI配置空间头,其定义如下
| register (offset) | bits 31-24 | bits 23-16 | bits 15-8 | bits 7-0 |
|---|---|---|---|---|
| 00 | Device ID | Vendor ID | ||
| 04 | Status | Command | ||
| 08 | Class code | Subclass | Prog IF | Revision ID |
| 0C | BIST | Header type | Latency Timer | Cache Line Size |
| 10 | Base address #0 (BAR0) | |||
| 14 | Base address #1 (BAR1) | |||
| 18 | Secondary Latency Timer | Subordinate Bus Number | Secondary Bus Number | Primary Bus Number |
| 1C | Secondary Status | I/O Limit | I/O Base | |
| 20 | Memory Limit | Memory Base | ||
| 24 | Prefetchable Memory Limit | Prefetchable Memory Base | ||
| 28 | Prefetchable Base Upper 32 Bits | |||
| 2C | Prefetchable Limit Upper 32 Bits | |||
| 30 | I/O Limit Upper 16 Bits | I/O Base Upper 16 Bits | ||
| 34 | Reserved | Capability Pointer | ||
| 38 | Expansion ROM base address | |||
| 3C | Bridge Control | Interrupt PIN | Interrupt Line | |
pci设备的配置空间可以通过pio或者mmio来访问,其中pio主要用于系统启动时的pci设备枚举,x86会有专门的寄存器来定义如何枚举,请参考相关资料。
host/guest的feature bits需要host和guest通过协商确定,相关的feature bit是根据具体的virtio设备不同而不同的,e.g. virtio_net, virtio_blk, virtio_balloon都有自己特定的feature bit,同时28-31位的feature bit被virtio_ring用来做同步
/* Some virtio feature bits (currently bits 28 through 31) are reserved for the * transport being used (eg. virtio_ring), the rest are per-device feature * bits. */ #define VIRTIO_TRANSPORT_F_START 28 #define VIRTIO_TRANSPORT_F_END 32
目前用到的transport features,是VIRTIO_RING_F_INDIRECT_DESC, VIRTIO_RING_F_EVENT_IDX
device status目前有如下几类
/* Status byte for guest to report progress, and synchronize features. */ /* We have seen device and processed generic fields (VIRTIO_CONFIG_F_VIRTIO) */ #define VIRTIO_CONFIG_S_ACKNOWLEDGE 1 /* We have found a driver for the device. */ #define VIRTIO_CONFIG_S_DRIVER 2 /* Driver has used its parts of the config, and is happy */ #define VIRTIO_CONFIG_S_DRIVER_OK 4 /* We've given up on this device. */ #define VIRTIO_CONFIG_S_FAILED 0x80
对于设备的操作都在virtio_config_ops里面,其定义如下
static struct virtio_config_ops virtio_pci_config_ops = {
.get = vp_get,
.set = vp_set,
.get_status = vp_get_status,
.set_status = vp_set_status,
.reset = vp_reset,
.find_vqs = vp_find_vqs,
.del_vqs = vp_del_vqs,
.get_features = vp_get_features,
.finalize_features = vp_finalize_features,
};
vp_get, vp_set最终都是通过ioread/iowrite操作来读取pci总线地址,这两个函数目前都是对于设备自己的配置做一些读写操作,因此都是在VIRTIO_PCI_CONFIG之后的空间进行
/* virtio config->get() implementation */
static void vp_get(struct virtio_device *vdev, unsigned offset,
void *buf, unsigned len)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
void __iomem *ioaddr = vp_dev->ioaddr +
VIRTIO_PCI_CONFIG(vp_dev) + offset;
u8 *ptr = buf;
int i;
for (i = 0; i < len; i++)
ptr[i] = ioread8(ioaddr + i);
}
/* the config->set() implementation. it's symmetric to the config->get()
* implementation */
static void vp_set(struct virtio_device *vdev, unsigned offset,
const void *buf, unsigned len)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
void __iomem *ioaddr = vp_dev->ioaddr +
VIRTIO_PCI_CONFIG(vp_dev) + offset;
const u8 *ptr = buf;
int i;
for (i = 0; i < len; i++)
iowrite8(ptr[i], ioaddr + i);
}
vp_get_status, vp_set_status用于读写设备状态,由于device status总共只有1个字节,因此只需要一次ioread8/iowrite8即可。而vp_reset相当于把VIRTIO_PCI_STATUS写入0
/* config->{get,set}_status() implementations */
static u8 vp_get_status(struct virtio_device *vdev)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
return ioread8(vp_dev->ioaddr + VIRTIO_PCI_STATUS);
}
static void vp_set_status(struct virtio_device *vdev, u8 status)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
/* We should never be setting status to 0. */
BUG_ON(status == 0);
iowrite8(status, vp_dev->ioaddr + VIRTIO_PCI_STATUS);
}
static void vp_reset(struct virtio_device *vdev)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
/* 0 status means a reset. */
iowrite8(0, vp_dev->ioaddr + VIRTIO_PCI_STATUS);
}
vp_get_features, vp_finalize_features也类似,由于features是32bit的,因此调用ioread32/iowrite32来实现,vp_get_features用于获取host feature,因此会读取VIRTIO_PCI_HOST_FEATURES,vp_finalize_features用于配置guest features
virtio pci设备同样需要按照系统通用的pci初始化方式注册,初始化时调用pci_register_driver,结束时调用pci_unregister_driver
static struct pci_driver virtio_pci_driver = {
.name = "virtio-pci",
.id_table = virtio_pci_id_table,
.probe = virtio_pci_probe,
.remove = virtio_pci_remove,
#ifdef CONFIG_PM
.driver.pm = &virtio_pci_pm_ops,
#endif
};
static int __init virtio_pci_init(void)
{
return pci_register_driver(&virtio_pci_driver);
}
module_init(virtio_pci_init);
static void __exit virtio_pci_exit(void)
{
pci_unregister_driver(&virtio_pci_driver);
}
module_exit(virtio_pci_exit);
下面来看看virtqueue,在virtio的机制中,前端和后端通过virtqueue来进行数据交换,virtqueue的初始化通过config->find_vqs来进行
static int vp_find_vqs(struct virtio_device *vdev, unsigned nvqs,
struct virtqueue *vqs[],
vq_callback_t *callbacks[],
const char *names[])
{
int err;
/* Try MSI-X with one vector per queue. */
err = vp_try_to_find_vqs(vdev, nvqs, vqs, callbacks, names, true, true);
if (!err)
return 0;
/* Fallback: MSI-X with one vector for config, one shared for queues. */
err = vp_try_to_find_vqs(vdev, nvqs, vqs, callbacks, names,
true, false);
if (!err)
return 0;
/* Finally fall back to regular interrupts. */
return vp_try_to_find_vqs(vdev, nvqs, vqs, callbacks, names,
false, false);
}可以看到vp_find_vqs是依次尝试不同的中断模式,具体实现都在函数vp_try_to_find_vqs里面,该函数由三个不同分支组成
1. 如果没有开启msix模式,则调用vp_request_intx申请一个中断,中断处理函数是vp_interrupt
if (!use_msix) {
/* Old style: one normal interrupt for change and all vqs. */
err = vp_request_intx(vdev);
if (err)
goto error_request;
} else {
vp_interrupt实际调用的是vp_vring_interrupt(配置变更的中断除外)
static irqreturn_t vp_interrupt(int irq, void *opaque)
{
struct virtio_pci_device *vp_dev = opaque;
u8 isr;
/* reading the ISR has the effect of also clearing it so it's very
* important to save off the value. */
isr = ioread8(vp_dev->ioaddr + VIRTIO_PCI_ISR);
/* It's definitely not us if the ISR was not high */
if (!isr)
return IRQ_NONE;
/* Configuration change? Tell driver if it wants to know. */
if (isr & VIRTIO_PCI_ISR_CONFIG)
vp_config_changed(irq, opaque);
return vp_vring_interrupt(irq, opaque);
}vp_vring_interrupt会遍历virtio_pci_device的所有virtqueue(多个队列的设备),调用中断处理函数vring_interrupt,最终调用virtqueue注册的callback函数完成中断处理
irqreturn_t vring_interrupt(int irq, void *_vq)
{
struct vring_virtqueue *vq = to_vvq(_vq);
if (!more_used(vq)) {
pr_debug("virtqueue interrupt with no work for %p\n", vq);
return IRQ_NONE;
}
if (unlikely(vq->broken))
return IRQ_HANDLED;
pr_debug("virtqueue callback for %p (%p)\n", vq, vq->vq.callback);
if (vq->vq.callback)
vq->vq.callback(&vq->vq);
return IRQ_HANDLED;
}
2. 开启了msix模式,还要区分不同的模式,要么是所有virtqueue共享一个中断,要么是每个virtqueue独立一个中断,无论是哪种模式,都需要调用vp_request_msix_vectors去申请irq中断资源。还要对每个virtqueue,调用setup_vq来完成初始化
vp_request_msix_vectors用于申请nvectors个中断,其中至少有一个config changed中断,处理函数为vp_config_changed,其余如果是共享模式,则所有队列共享一个msix中断,中断处理函数是vp_vring_interrupt
} else {
if (per_vq_vectors) {
/* Best option: one for change interrupt, one per vq. */
nvectors = 1;
for (i = 0; i < nvqs; ++i)
if (callbacks[i])
++nvectors;
} else {
/* Second best: one for change, shared for all vqs. */
nvectors = 2;
}
err = vp_request_msix_vectors(vdev, nvectors, per_vq_vectors);
if (err)
goto error_request;
}
对于每个virtqueue,都会调用setup_vq初始化对应的virtqueue,同时如果是per-vq中断的模式,还会调用request_irq分配中断资源,中断处理函数是vring_interrupt
vp_dev->per_vq_vectors = per_vq_vectors;
allocated_vectors = vp_dev->msix_used_vectors;
for (i = 0; i < nvqs; ++i) {
if (!callbacks[i] || !vp_dev->msix_enabled)
msix_vec = VIRTIO_MSI_NO_VECTOR;
else if (vp_dev->per_vq_vectors)
msix_vec = allocated_vectors++;
else
msix_vec = VP_MSIX_VQ_VECTOR;
vqs[i] = setup_vq(vdev, i, callbacks[i], names[i], msix_vec);
if (IS_ERR(vqs[i])) {
err = PTR_ERR(vqs[i]);
goto error_find;
}
if (!vp_dev->per_vq_vectors || msix_vec == VIRTIO_MSI_NO_VECTOR)
continue;
/* allocate per-vq irq if available and necessary */
snprintf(vp_dev->msix_names[msix_vec],
sizeof *vp_dev->msix_names,
"%s-%s",
dev_name(&vp_dev->vdev.dev), names[i]);
err = request_irq(vp_dev->msix_entries[msix_vec].vector,
vring_interrupt, 0,
vp_dev->msix_names[msix_vec],
vqs[i]);
if (err) {
vp_del_vq(vqs[i]);
goto error_find;
}
}
return 0;
其中setup_vq的函数如下:
static struct virtqueue *setup_vq(struct virtio_device *vdev, unsigned index,
void (*callback)(struct virtqueue *vq),
const char *name,
u16 msix_vec)
{
struct virtio_pci_device *vp_dev = to_vp_device(vdev);
struct virtio_pci_vq_info *info;
struct virtqueue *vq;
unsigned long flags, size;
u16 num;
int err;
/* Select the queue we're interested in */ /* 把要配置的queue的index写入配置空间地址 */
iowrite16(index, vp_dev->ioaddr + VIRTIO_PCI_QUEUE_SEL);
/* Check if queue is either not available or already active. */ /* num=0说明queue不可用,否则说明地址非空,已经被占用了 */
num = ioread16(vp_dev->ioaddr + VIRTIO_PCI_QUEUE_NUM);
if (!num || ioread32(vp_dev->ioaddr + VIRTIO_PCI_QUEUE_PFN))
return ERR_PTR(-ENOENT);
/* allocate and fill out our structure the represents an active
* queue */
info = kmalloc(sizeof(struct virtio_pci_vq_info), GFP_KERNEL);
if (!info)
return ERR_PTR(-ENOMEM);
info->queue_index = index; /* 队列index */
info->num = num; /* vring size, vring_desc个数 */
info->msix_vector = msix_vec;
size = PAGE_ALIGN(vring_size(num, VIRTIO_PCI_VRING_ALIGN));
info->queue = alloc_pages_exact(size, GFP_KERNEL|__GFP_ZERO); /* vring分配空间 */
if (info->queue == NULL) {
err = -ENOMEM;
goto out_info;
}
/* activate the queue */ /* 把vring的地址写入pci配置空间,触发trap使得qemu可以通知到 */
iowrite32(virt_to_phys(info->queue) >> VIRTIO_PCI_QUEUE_ADDR_SHIFT,
vp_dev->ioaddr + VIRTIO_PCI_QUEUE_PFN);
/* create the vring */ /* 创建vring_virqueue,把vring封装在virtqueue里面 */
vq = vring_new_virtqueue(info->num, VIRTIO_PCI_VRING_ALIGN,
vdev, info->queue, vp_notify, callback, name);
if (!vq) {
err = -ENOMEM;
goto out_activate_queue;
}
vq->priv = info; /* virtqueue->priv指向virtio_pci_vq_info */
info->vq = vq; /* virtio_pci_vq_info->vq指向新创建的virtqueue */
if (msix_vec != VIRTIO_MSI_NO_VECTOR) {
iowrite16(msix_vec, vp_dev->ioaddr + VIRTIO_MSI_QUEUE_VECTOR);
msix_vec = ioread16(vp_dev->ioaddr + VIRTIO_MSI_QUEUE_VECTOR);
if (msix_vec == VIRTIO_MSI_NO_VECTOR) {
err = -EBUSY;
goto out_assign;
}
}
spin_lock_irqsave(&vp_dev->lock, flags);
list_add(&info->node, &vp_dev->virtqueues);
spin_unlock_irqrestore(&vp_dev->lock, flags);
return vq;
out_assign:
vring_del_virtqueue(vq);
out_activate_queue:
iowrite32(0, vp_dev->ioaddr + VIRTIO_PCI_QUEUE_PFN);
free_pages_exact(info->queue, size);
out_info:
kfree(info);
return ERR_PTR(err);
}