转载请注明出处:http://blog.csdn.net/Righthek 谢谢!
上一篇文章已经提到USB接口在wifi模块中的最重要两个函数是usb_read_port()和usb_write_port()。那它们是怎么和wifi扯上关系的呢?我们可以从以下三个方面去分析:
1、首先需要明确wifi模块是USB设备,主控(CPU)端是USB主机;
2、USB主机若需要对wifi模块进行数据的读写时,就必须经过USB接口;
3、既然涉及到数据的读写操作,必然要用相应的读写函数,那么usb_read_port()和usb_write_port()即是它们的读写函数。
我们先从读数据开始进行分析,在分析之前,我们必须了解USB设备驱动的读数据过程。USB读取数据操作流程如下:
(1)通过usb_alloc_urb()函数创建并分配一个URB,作为传输USB数据的载体;
(2)创建并分配DMA缓冲区,以DMA方式快速传输数据;
(3)初始化URB,根据wifi的传输数据量,我们需要初始化为批量URB,相应操作函数为usb_fill_bulk_urb();
(4)将URB提交到USB核心;
(5)提交成功后,URB的完成函数将被USB核心调用。
现在我们一步步地详细分析整个过程,所谓的创建和分配,实质上是对内存的分配。作为一名Linux驱动开发程序员,必须了解Linux内存管理相关知识及合理使用内存。
那么我们应该怎样合理地创建和分配URB和DMA缓冲区呢?很明显,我们应该在用的时候分配,在不用的时候释放。
那么问题来了……什么时候在用,又什么时候不用呢?问题很简单,就是主控端读数据时分配,读完后释放,而只有当wifi模块有数据可读时,主控端才能成功地读取数据。那么wifi模块什么时候有数据可读呢?——下面重点来了!wifi模块通过RF端接收到无线网络数据,然后缓存到wifi芯片的RAM中,此时,wifi模块就有数据可读了。
经过上面的分析,我们找到了一条USB接口与wifi模块扯上关系的线索,就是wifi模块的接收数据,会引发USB接口的读数据;
现在,我们转到wifi模块的接收函数中,看看是不是真的这样?
在wifi接收函数初始化中,我们可以看到usb_alloc_urb()创建一个中断URB。伪代码如下:
- int xxxwifi_init_recv(_adapter *padapter)
- {
- struct recv_priv *precvpriv = &padapter->recvpriv;
- int i, res = _SUCCESS;
- struct recv_buf *precvbuf;
- tasklet_init(&precvpriv->recv_tasklet, (void(*)(unsigned long))rtl8188eu_recv_tasklet, (unsigned long)padapter);
- precvpriv->int_in_urb = usb_alloc_urb(0, GFP_KERNEL); //创建一个中断URB
- precvpriv->int_in_buf = rtw_zmalloc(INTERRUPT_MSG_FORMAT_LEN);
- //init recv_buf
- _rtw_init_queue(&precvpriv->free_recv_buf_queue);
- _rtw_init_queue(&precvpriv->recv_buf_pending_queue);
- precvpriv -> pallocated_recv_buf = rtw_zmalloc(NR_RECVBUFF *sizeof(struct recv_buf) + 4);
- precvbuf = (struct recv_buf*)precvpriv->precv_buf;
- for(i=0; i < NR_RECVBUFF ; i++)
- {
- _rtw_init_listhead(&precvbuf->list);
- _rtw_spinlock_init(&precvbuf->recvbuf_lock);
- precvbuf->alloc_sz = MAX_RECVBUF_SZ;
- res = rtw_os_recvbuf_resource_alloc(padapter, precvbuf);
- precvbuf->ref_cnt = 0;
- precvbuf->adapter =padapter;
- precvbuf++;
- }
- precvpriv->free_recv_buf_queue_cnt = NR_RECVBUFF;
- skb_queue_head_init(&precvpriv->rx_skb_queue);
- #ifdef CONFIG_PREALLOC_RECV_SKB
- {
- int i;
- SIZE_PTR tmpaddr=0;
- SIZE_PTR alignment=0;
- struct sk_buff *pskb=NULL;
- skb_queue_head_init(&precvpriv->free_recv_skb_queue);
- for(i=0; i<NR_PREALLOC_RECV_SKB; i++)
- {
- pskb = rtw_skb_alloc(MAX_RECVBUF_SZ + RECVBUFF_ALIGN_SZ);
- if(pskb)
- {
- pskb->dev = padapter->pnetdev;
- tmpaddr = (SIZE_PTR)pskb->data;
- alignment = tmpaddr & (RECVBUFF_ALIGN_SZ-1);
- skb_reserve(pskb, (RECVBUFF_ALIGN_SZ - alignment));
- skb_queue_tail(&precvpriv->free_recv_skb_queue, pskb);
- }
- pskb=NULL;
- }
- }
- #endif
- return res;
- }
int xxxwifi_init_recv(_adapter *padapter)
{
struct recv_priv *precvpriv = &padapter->recvpriv;
int i, res = _SUCCESS;
struct recv_buf *precvbuf;
tasklet_init(&precvpriv->recv_tasklet, (void(*)(unsigned long))rtl8188eu_recv_tasklet, (unsigned long)padapter);
precvpriv->int_in_urb = usb_alloc_urb(0, GFP_KERNEL); //创建一个中断URB
precvpriv->int_in_buf = rtw_zmalloc(INTERRUPT_MSG_FORMAT_LEN);
//init recv_buf
_rtw_init_queue(&precvpriv->free_recv_buf_queue);
_rtw_init_queue(&precvpriv->recv_buf_pending_queue);
precvpriv -> pallocated_recv_buf = rtw_zmalloc(NR_RECVBUFF *sizeof(struct recv_buf) + 4);
precvbuf = (struct recv_buf*)precvpriv->precv_buf;
for(i=0; i < NR_RECVBUFF ; i++)
{
_rtw_init_listhead(&precvbuf->list);
_rtw_spinlock_init(&precvbuf->recvbuf_lock);
precvbuf->alloc_sz = MAX_RECVBUF_SZ;
res = rtw_os_recvbuf_resource_alloc(padapter, precvbuf);
precvbuf->ref_cnt = 0;
precvbuf->adapter =padapter;
precvbuf++;
}
precvpriv->free_recv_buf_queue_cnt = NR_RECVBUFF;
skb_queue_head_init(&precvpriv->rx_skb_queue);
#ifdef CONFIG_PREALLOC_RECV_SKB
{
int i;
SIZE_PTR tmpaddr=0;
SIZE_PTR alignment=0;
struct sk_buff *pskb=NULL;
skb_queue_head_init(&precvpriv->free_recv_skb_queue);
for(i=0; i<NR_PREALLOC_RECV_SKB; i++)
{
pskb = rtw_skb_alloc(MAX_RECVBUF_SZ + RECVBUFF_ALIGN_SZ);
if(pskb)
{
pskb->dev = padapter->pnetdev;
tmpaddr = (SIZE_PTR)pskb->data;
alignment = tmpaddr & (RECVBUFF_ALIGN_SZ-1);
skb_reserve(pskb, (RECVBUFF_ALIGN_SZ - alignment));
skb_queue_tail(&precvpriv->free_recv_skb_queue, pskb);
}
pskb=NULL;
}
}
#endif
return res;
}
在rtw_os_recvbuf_resource_alloc函数中,创建一个批量URB和一个DMA缓冲区。伪代码如下:
- int rtw_os_recvbuf_resource_alloc(_adapter *padapter, struct recv_buf *precvbuf)
- {
- int res=_SUCCESS;
- struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(padapter);
- struct usb_device *pusbd = pdvobjpriv->pusbdev;
- precvbuf->irp_pending = _FALSE;
- precvbuf->purb = usb_alloc_urb(0, GFP_KERNEL); //创建一个批量URB
- precvbuf->pskb = NULL;
- precvbuf->reuse = _FALSE;
- precvbuf->pallocated_buf = precvbuf->pbuf = NULL;
- precvbuf->pdata = precvbuf->phead = precvbuf->ptail = precvbuf->pend = NULL;
- precvbuf->transfer_len = 0;
- precvbuf->len = 0;
- #ifdef CONFIG_USE_USB_BUFFER_ALLOC_RX
- precvbuf->pallocated_buf = rtw_usb_buffer_alloc(pusbd, (size_t)precvbuf->alloc_sz, &precvbuf->dma_transfer_addr); //创建一个DMA缓冲区
- precvbuf->pbuf = precvbuf->pallocated_buf;
- if(precvbuf->pallocated_buf == NULL)
- return _FAIL;
- #endif //CONFIG_USE_USB_BUFFER_ALLOC_RX
- return res;
- }
int rtw_os_recvbuf_resource_alloc(_adapter *padapter, struct recv_buf *precvbuf)
{
int res=_SUCCESS;
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(padapter);
struct usb_device *pusbd = pdvobjpriv->pusbdev;
precvbuf->irp_pending = _FALSE;
precvbuf->purb = usb_alloc_urb(0, GFP_KERNEL); //创建一个批量URB
precvbuf->pskb = NULL;
precvbuf->reuse = _FALSE;
precvbuf->pallocated_buf = precvbuf->pbuf = NULL;
precvbuf->pdata = precvbuf->phead = precvbuf->ptail = precvbuf->pend = NULL;
precvbuf->transfer_len = 0;
precvbuf->len = 0;
#ifdef CONFIG_USE_USB_BUFFER_ALLOC_RX
precvbuf->pallocated_buf = rtw_usb_buffer_alloc(pusbd, (size_t)precvbuf->alloc_sz, &precvbuf->dma_transfer_addr); //创建一个DMA缓冲区
precvbuf->pbuf = precvbuf->pallocated_buf;
if(precvbuf->pallocated_buf == NULL)
return _FAIL;
#endif //CONFIG_USE_USB_BUFFER_ALLOC_RX
return res;
}
在usb_read_port()函数中,通过usb_fill_bulk_urb()初始化批量URB,并且提交给USB核心,也即USB读取数据操作流程的第3、4步。在usb_fill_bulk_urb()函数中,初始化URB的完成函数usb_read_port_complete(),只有当URB提交完成后,函数usb_read_port_complete()将被调用。伪代码如下:
- static u32 usb_read_port(struct intf_hdl *pintfhdl, u32 addr, u32 cnt, u8 *rmem)
- {
- struct recv_buf *precvbuf = (struct recv_buf *)rmem;
- _adapter *adapter = pintfhdl->padapter;
- struct dvobj_priv *pdvobj = adapter_to_dvobj(adapter);
- struct pwrctrl_priv *pwrctl = dvobj_to_pwrctl(pdvobj);
- struct recv_priv *precvpriv = &adapter->recvpriv;
- struct usb_device *pusbd = pdvobj->pusbdev;
- rtl8188eu_init_recvbuf(adapter, precvbuf);
- precvpriv->rx_pending_cnt++;
- purb = precvbuf->purb;
- //translate DMA FIFO addr to pipehandle
- pipe = ffaddr2pipehdl(pdvobj, addr);
- usb_fill_bulk_urb(purb, pusbd, pipe,
- precvbuf->pbuf,
- MAX_RECVBUF_SZ,
- usb_read_port_complete,
- precvbuf);//context is precvbuf
- err = usb_submit_urb(purb, GFP_ATOMIC);
- return ret;
- }
static u32 usb_read_port(struct intf_hdl *pintfhdl, u32 addr, u32 cnt, u8 *rmem)
{
struct recv_buf *precvbuf = (struct recv_buf *)rmem;
_adapter *adapter = pintfhdl->padapter;
struct dvobj_priv *pdvobj = adapter_to_dvobj(adapter);
struct pwrctrl_priv *pwrctl = dvobj_to_pwrctl(pdvobj);
struct recv_priv *precvpriv = &adapter->recvpriv;
struct usb_device *pusbd = pdvobj->pusbdev;
rtl8188eu_init_recvbuf(adapter, precvbuf);
precvpriv->rx_pending_cnt++;
purb = precvbuf->purb;
//translate DMA FIFO addr to pipehandle
pipe = ffaddr2pipehdl(pdvobj, addr);
usb_fill_bulk_urb(purb, pusbd, pipe,
precvbuf->pbuf,
MAX_RECVBUF_SZ,
usb_read_port_complete,
precvbuf);//context is precvbuf
err = usb_submit_urb(purb, GFP_ATOMIC);
return ret;
}
通过上面的代码,我们可以得知在wifi模块为接收数据做初始化准备时,分配了URB和DMA缓冲区。而在usb_read_port()函数中初始化URB和提交URB。
它为什么要这样做呢?目的是什么?
接下来,我们将在下一篇文章中为大家揭晓。
转载请注明出处:http://blog.csdn.net/Righthek 谢谢!转载请注明出处:http://blog.csdn.net/Righthek 谢谢!
上一篇文章已经提到USB接口在wifi模块中的最重要两个函数是usb_read_port()和usb_write_port()。那它们是怎么和wifi扯上关系的呢?我们可以从以下三个方面去分析:
1、首先需要明确wifi模块是USB设备,主控(CPU)端是USB主机;
2、USB主机若需要对wifi模块进行数据的读写时,就必须经过USB接口;
3、既然涉及到数据的读写操作,必然要用相应的读写函数,那么usb_read_port()和usb_write_port()即是它们的读写函数。
我们先从读数据开始进行分析,在分析之前,我们必须了解USB设备驱动的读数据过程。USB读取数据操作流程如下:
(1)通过usb_alloc_urb()函数创建并分配一个URB,作为传输USB数据的载体;
(2)创建并分配DMA缓冲区,以DMA方式快速传输数据;
(3)初始化URB,根据wifi的传输数据量,我们需要初始化为批量URB,相应操作函数为usb_fill_bulk_urb();
(4)将URB提交到USB核心;
(5)提交成功后,URB的完成函数将被USB核心调用。
现在我们一步步地详细分析整个过程,所谓的创建和分配,实质上是对内存的分配。作为一名Linux驱动开发程序员,必须了解Linux内存管理相关知识及合理使用内存。
那么我们应该怎样合理地创建和分配URB和DMA缓冲区呢?很明显,我们应该在用的时候分配,在不用的时候释放。
那么问题来了……什么时候在用,又什么时候不用呢?问题很简单,就是主控端读数据时分配,读完后释放,而只有当wifi模块有数据可读时,主控端才能成功地读取数据。那么wifi模块什么时候有数据可读呢?——下面重点来了!wifi模块通过RF端接收到无线网络数据,然后缓存到wifi芯片的RAM中,此时,wifi模块就有数据可读了。
经过上面的分析,我们找到了一条USB接口与wifi模块扯上关系的线索,就是wifi模块的接收数据,会引发USB接口的读数据;
现在,我们转到wifi模块的接收函数中,看看是不是真的这样?
在wifi接收函数初始化中,我们可以看到usb_alloc_urb()创建一个中断URB。伪代码如下:
- int xxxwifi_init_recv(_adapter *padapter)
- {
- struct recv_priv *precvpriv = &padapter->recvpriv;
- int i, res = _SUCCESS;
- struct recv_buf *precvbuf;
- tasklet_init(&precvpriv->recv_tasklet, (void(*)(unsigned long))rtl8188eu_recv_tasklet, (unsigned long)padapter);
- precvpriv->int_in_urb = usb_alloc_urb(0, GFP_KERNEL); //创建一个中断URB
- precvpriv->int_in_buf = rtw_zmalloc(INTERRUPT_MSG_FORMAT_LEN);
- //init recv_buf
- _rtw_init_queue(&precvpriv->free_recv_buf_queue);
- _rtw_init_queue(&precvpriv->recv_buf_pending_queue);
- precvpriv -> pallocated_recv_buf = rtw_zmalloc(NR_RECVBUFF *sizeof(struct recv_buf) + 4);
- precvbuf = (struct recv_buf*)precvpriv->precv_buf;
- for(i=0; i < NR_RECVBUFF ; i++)
- {
- _rtw_init_listhead(&precvbuf->list);
- _rtw_spinlock_init(&precvbuf->recvbuf_lock);
- precvbuf->alloc_sz = MAX_RECVBUF_SZ;
- res = rtw_os_recvbuf_resource_alloc(padapter, precvbuf);
- precvbuf->ref_cnt = 0;
- precvbuf->adapter =padapter;
- precvbuf++;
- }
- precvpriv->free_recv_buf_queue_cnt = NR_RECVBUFF;
- skb_queue_head_init(&precvpriv->rx_skb_queue);
- #ifdef CONFIG_PREALLOC_RECV_SKB
- {
- int i;
- SIZE_PTR tmpaddr=0;
- SIZE_PTR alignment=0;
- struct sk_buff *pskb=NULL;
- skb_queue_head_init(&precvpriv->free_recv_skb_queue);
- for(i=0; i<NR_PREALLOC_RECV_SKB; i++)
- {
- pskb = rtw_skb_alloc(MAX_RECVBUF_SZ + RECVBUFF_ALIGN_SZ);
- if(pskb)
- {
- pskb->dev = padapter->pnetdev;
- tmpaddr = (SIZE_PTR)pskb->data;
- alignment = tmpaddr & (RECVBUFF_ALIGN_SZ-1);
- skb_reserve(pskb, (RECVBUFF_ALIGN_SZ - alignment));
- skb_queue_tail(&precvpriv->free_recv_skb_queue, pskb);
- }
- pskb=NULL;
- }
- }
- #endif
- return res;
- }
int xxxwifi_init_recv(_adapter *padapter)
{
struct recv_priv *precvpriv = &padapter->recvpriv;
int i, res = _SUCCESS;
struct recv_buf *precvbuf;
tasklet_init(&precvpriv->recv_tasklet, (void(*)(unsigned long))rtl8188eu_recv_tasklet, (unsigned long)padapter);
precvpriv->int_in_urb = usb_alloc_urb(0, GFP_KERNEL); //创建一个中断URB
precvpriv->int_in_buf = rtw_zmalloc(INTERRUPT_MSG_FORMAT_LEN);
//init recv_buf
_rtw_init_queue(&precvpriv->free_recv_buf_queue);
_rtw_init_queue(&precvpriv->recv_buf_pending_queue);
precvpriv -> pallocated_recv_buf = rtw_zmalloc(NR_RECVBUFF *sizeof(struct recv_buf) + 4);
precvbuf = (struct recv_buf*)precvpriv->precv_buf;
for(i=0; i < NR_RECVBUFF ; i++)
{
_rtw_init_listhead(&precvbuf->list);
_rtw_spinlock_init(&precvbuf->recvbuf_lock);
precvbuf->alloc_sz = MAX_RECVBUF_SZ;
res = rtw_os_recvbuf_resource_alloc(padapter, precvbuf);
precvbuf->ref_cnt = 0;
precvbuf->adapter =padapter;
precvbuf++;
}
precvpriv->free_recv_buf_queue_cnt = NR_RECVBUFF;
skb_queue_head_init(&precvpriv->rx_skb_queue);
#ifdef CONFIG_PREALLOC_RECV_SKB
{
int i;
SIZE_PTR tmpaddr=0;
SIZE_PTR alignment=0;
struct sk_buff *pskb=NULL;
skb_queue_head_init(&precvpriv->free_recv_skb_queue);
for(i=0; i<NR_PREALLOC_RECV_SKB; i++)
{
pskb = rtw_skb_alloc(MAX_RECVBUF_SZ + RECVBUFF_ALIGN_SZ);
if(pskb)
{
pskb->dev = padapter->pnetdev;
tmpaddr = (SIZE_PTR)pskb->data;
alignment = tmpaddr & (RECVBUFF_ALIGN_SZ-1);
skb_reserve(pskb, (RECVBUFF_ALIGN_SZ - alignment));
skb_queue_tail(&precvpriv->free_recv_skb_queue, pskb);
}
pskb=NULL;
}
}
#endif
return res;
}
在rtw_os_recvbuf_resource_alloc函数中,创建一个批量URB和一个DMA缓冲区。伪代码如下:
- int rtw_os_recvbuf_resource_alloc(_adapter *padapter, struct recv_buf *precvbuf)
- {
- int res=_SUCCESS;
- struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(padapter);
- struct usb_device *pusbd = pdvobjpriv->pusbdev;
- precvbuf->irp_pending = _FALSE;
- precvbuf->purb = usb_alloc_urb(0, GFP_KERNEL); //创建一个批量URB
- precvbuf->pskb = NULL;
- precvbuf->reuse = _FALSE;
- precvbuf->pallocated_buf = precvbuf->pbuf = NULL;
- precvbuf->pdata = precvbuf->phead = precvbuf->ptail = precvbuf->pend = NULL;
- precvbuf->transfer_len = 0;
- precvbuf->len = 0;
- #ifdef CONFIG_USE_USB_BUFFER_ALLOC_RX
- precvbuf->pallocated_buf = rtw_usb_buffer_alloc(pusbd, (size_t)precvbuf->alloc_sz, &precvbuf->dma_transfer_addr); //创建一个DMA缓冲区
- precvbuf->pbuf = precvbuf->pallocated_buf;
- if(precvbuf->pallocated_buf == NULL)
- return _FAIL;
- #endif //CONFIG_USE_USB_BUFFER_ALLOC_RX
- return res;
- }
int rtw_os_recvbuf_resource_alloc(_adapter *padapter, struct recv_buf *precvbuf)
{
int res=_SUCCESS;
struct dvobj_priv *pdvobjpriv = adapter_to_dvobj(padapter);
struct usb_device *pusbd = pdvobjpriv->pusbdev;
precvbuf->irp_pending = _FALSE;
precvbuf->purb = usb_alloc_urb(0, GFP_KERNEL); //创建一个批量URB
precvbuf->pskb = NULL;
precvbuf->reuse = _FALSE;
precvbuf->pallocated_buf = precvbuf->pbuf = NULL;
precvbuf->pdata = precvbuf->phead = precvbuf->ptail = precvbuf->pend = NULL;
precvbuf->transfer_len = 0;
precvbuf->len = 0;
#ifdef CONFIG_USE_USB_BUFFER_ALLOC_RX
precvbuf->pallocated_buf = rtw_usb_buffer_alloc(pusbd, (size_t)precvbuf->alloc_sz, &precvbuf->dma_transfer_addr); //创建一个DMA缓冲区
precvbuf->pbuf = precvbuf->pallocated_buf;
if(precvbuf->pallocated_buf == NULL)
return _FAIL;
#endif //CONFIG_USE_USB_BUFFER_ALLOC_RX
return res;
}
在usb_read_port()函数中,通过usb_fill_bulk_urb()初始化批量URB,并且提交给USB核心,也即USB读取数据操作流程的第3、4步。在usb_fill_bulk_urb()函数中,初始化URB的完成函数usb_read_port_complete(),只有当URB提交完成后,函数usb_read_port_complete()将被调用。伪代码如下:
- static u32 usb_read_port(struct intf_hdl *pintfhdl, u32 addr, u32 cnt, u8 *rmem)
- {
- struct recv_buf *precvbuf = (struct recv_buf *)rmem;
- _adapter *adapter = pintfhdl->padapter;
- struct dvobj_priv *pdvobj = adapter_to_dvobj(adapter);
- struct pwrctrl_priv *pwrctl = dvobj_to_pwrctl(pdvobj);
- struct recv_priv *precvpriv = &adapter->recvpriv;
- struct usb_device *pusbd = pdvobj->pusbdev;
- rtl8188eu_init_recvbuf(adapter, precvbuf);
- precvpriv->rx_pending_cnt++;
- purb = precvbuf->purb;
- //translate DMA FIFO addr to pipehandle
- pipe = ffaddr2pipehdl(pdvobj, addr);
- usb_fill_bulk_urb(purb, pusbd, pipe,
- precvbuf->pbuf,
- MAX_RECVBUF_SZ,
- usb_read_port_complete,
- precvbuf);//context is precvbuf
- err = usb_submit_urb(purb, GFP_ATOMIC);
- return ret;
- }
static u32 usb_read_port(struct intf_hdl *pintfhdl, u32 addr, u32 cnt, u8 *rmem)
{
struct recv_buf *precvbuf = (struct recv_buf *)rmem;
_adapter *adapter = pintfhdl->padapter;
struct dvobj_priv *pdvobj = adapter_to_dvobj(adapter);
struct pwrctrl_priv *pwrctl = dvobj_to_pwrctl(pdvobj);
struct recv_priv *precvpriv = &adapter->recvpriv;
struct usb_device *pusbd = pdvobj->pusbdev;
rtl8188eu_init_recvbuf(adapter, precvbuf);
precvpriv->rx_pending_cnt++;
purb = precvbuf->purb;
//translate DMA FIFO addr to pipehandle
pipe = ffaddr2pipehdl(pdvobj, addr);
usb_fill_bulk_urb(purb, pusbd, pipe,
precvbuf->pbuf,
MAX_RECVBUF_SZ,
usb_read_port_complete,
precvbuf);//context is precvbuf
err = usb_submit_urb(purb, GFP_ATOMIC);
return ret;
}
通过上面的代码,我们可以得知在wifi模块为接收数据做初始化准备时,分配了URB和DMA缓冲区。而在usb_read_port()函数中初始化URB和提交URB。
它为什么要这样做呢?目的是什么?
接下来,我们将在下一篇文章中为大家揭晓。
转载请注明出处:http://blog.csdn.net/Righthek 谢谢!