rt-thread-official/components/drivers/usb/usbhost/class/mass.c

648 lines
18 KiB
C

/*
* File : mass.c
* This file is part of RT-Thread RTOS
* COPYRIGHT (C) 2011, RT-Thread Development Team
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rt-thread.org/license/LICENSE
*
* Change Logs:
* Date Author Notes
* 2011-12-12 Yi Qiu first version
*/
#include <rtthread.h>
#include <drivers/usb_host.h>
#include "mass.h"
#ifdef RT_USBH_MSTORAGE
extern rt_err_t rt_udisk_run(struct uhintf* intf);
extern rt_err_t rt_udisk_stop(struct uhintf* intf);
static struct uclass_driver storage_driver;
/**
* This function will do USBREQ_GET_MAX_LUN request for the usb interface instance.
*
* @param intf the interface instance.
* @param max_lun the buffer to save max_lun.
*
* @return the error code, RT_EOK on successfully.
*/
static rt_err_t _pipe_check(struct uhintf* intf, upipe_t pipe)
{
struct uinstance* device;
rt_err_t ret;
ustor_t stor;
int size = 0;
struct ustorage_csw csw;
if(intf == RT_NULL || pipe == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
/* get usb device instance from the interface instance */
device = intf->device;
/* get storage instance from the interface instance */
stor = (ustor_t)intf->user_data;
/* check pipe status */
if(pipe->status == UPIPE_STATUS_OK) return RT_EOK;
if(pipe->status == UPIPE_STATUS_ERROR)
{
rt_kprintf("pipe status error\n");
return -RT_EIO;
}
if(pipe->status == UPIPE_STATUS_STALL)
{
/* clear the pipe stall status */
ret = rt_usbh_clear_feature(device, pipe->ep.bEndpointAddress,
USB_FEATURE_ENDPOINT_HALT);
if(ret != RT_EOK) return ret;
}
rt_thread_delay(50);
rt_kprintf("pipes1 0x%x, 0x%x\n", stor->pipe_in, stor->pipe_out);
stor->pipe_in->status = UPIPE_STATUS_OK;
RT_DEBUG_LOG(RT_DEBUG_USB, ("clean storage in pipe stall\n"));
/* it should receive csw after clear the stall feature */
size = rt_usb_hcd_pipe_xfer(stor->pipe_in->inst->hcd,
stor->pipe_in, &csw, SIZEOF_CSW, 100);
if(size != SIZEOF_CSW)
{
rt_kprintf("receive the csw after stall failed\n");
return -RT_EIO;
}
return -RT_ERROR;
}
/**
* This function will do USBREQ_GET_MAX_LUN request for the usb interface instance.
*
* @param intf the interface instance.
* @param max_lun the buffer to save max_lun.
*
* @return the error code, RT_EOK on successfully.
*/
static rt_err_t rt_usb_bulk_only_xfer(struct uhintf* intf,
ustorage_cbw_t cmd, rt_uint8_t* buffer, int timeout)
{
rt_size_t size;
rt_err_t ret;
upipe_t pipe;
struct ustorage_csw csw;
ustor_t stor;
RT_ASSERT(cmd != RT_NULL);
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
/* get storage instance from the interface instance */
stor = (ustor_t)intf->user_data;
do
{
/* send the cbw */
size = rt_usb_hcd_pipe_xfer(stor->pipe_out->inst->hcd, stor->pipe_out,
cmd, SIZEOF_CBW, timeout);
if(size != SIZEOF_CBW)
{
rt_kprintf("CBW size error\n");
return -RT_EIO;
}
if(cmd->xfer_len != 0)
{
pipe = (cmd->dflags == CBWFLAGS_DIR_IN) ? stor->pipe_in :
stor->pipe_out;
size = rt_usb_hcd_pipe_xfer(pipe->inst->hcd, pipe, (void*)buffer,
cmd->xfer_len, timeout);
if(size != cmd->xfer_len)
{
rt_kprintf("request size %d, transfer size %d\n",
cmd->xfer_len, size);
break;
}
}
/* receive the csw */
size = rt_usb_hcd_pipe_xfer(stor->pipe_in->inst->hcd, stor->pipe_in,
&csw, SIZEOF_CSW, timeout);
if(size != SIZEOF_CSW)
{
rt_kprintf("csw size error\n");
return -RT_EIO;
}
}while(0);
/* check in pipes status */
ret = _pipe_check(intf, stor->pipe_in);
if(ret != RT_EOK)
{
rt_kprintf("in pipe error\n");
return ret;
}
/* check out pipes status */
ret = _pipe_check(intf, stor->pipe_out);
if(ret != RT_EOK)
{
rt_kprintf("out pipe error\n");
return ret;
}
/* check csw status */
if(csw.signature != CSW_SIGNATURE || csw.tag != CBW_TAG_VALUE)
{
rt_kprintf("csw signature error\n");
return -RT_EIO;
}
if(csw.status != 0)
{
//rt_kprintf("csw status error:%d\n",csw.status);
return -RT_ERROR;
}
return RT_EOK;
}
/**
* This function will do USBREQ_GET_MAX_LUN request for the usb interface instance.
*
* @param intf the interface instance.
* @param max_lun the buffer to save max_lun.
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_get_max_lun(struct uhintf* intf, rt_uint8_t* max_lun)
{
struct uinstance* device;
struct urequest setup;
int timeout = 100;
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
/* parameter check */
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_get_max_lun\n"));
/* get usb device instance from the interface instance */
device = intf->device;
/* construct the request */
setup.request_type = USB_REQ_TYPE_DIR_IN | USB_REQ_TYPE_CLASS |
USB_REQ_TYPE_INTERFACE;
setup.bRequest = USBREQ_GET_MAX_LUN;
setup.wValue = intf->intf_desc->bInterfaceNumber;
setup.wIndex = 0;
setup.wLength = 1;
/* do control transfer request */
if(rt_usb_hcd_setup_xfer(device->hcd, device->pipe_ep0_out, &setup, timeout) != 8)
{
return -RT_EIO;
}
if(rt_usb_hcd_pipe_xfer(device->hcd, device->pipe_ep0_in, max_lun, 1, timeout) != 1)
{
return -RT_EIO;
}
if(rt_usb_hcd_pipe_xfer(device->hcd, device->pipe_ep0_out, RT_NULL, 0, timeout) != 0)
{
return -RT_EIO;
}
return RT_EOK;
}
/**
* This function will do USBREQ_MASS_STORAGE_RESET request for the usb interface instance.
*
* @param intf the interface instance.
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_reset(struct uhintf* intf)
{
struct urequest setup;
struct uinstance* device;
int timeout = 100;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_reset\n"));
/* get usb device instance from the interface instance */
device = intf->device;
/* construct the request */
setup.request_type = USB_REQ_TYPE_DIR_OUT | USB_REQ_TYPE_CLASS |
USB_REQ_TYPE_INTERFACE;
setup.bRequest = USBREQ_MASS_STORAGE_RESET;
setup.wIndex = intf->intf_desc->bInterfaceNumber;
setup.wLength = 0;
setup.wValue = 0;
if(rt_usb_hcd_setup_xfer(device->hcd, device->pipe_ep0_out, &setup, timeout) != 8)
{
return -RT_EIO;
}
if(rt_usb_hcd_pipe_xfer(device->hcd, device->pipe_ep0_in, RT_NULL, 0, timeout) != 0)
{
return -RT_EIO;
}
return RT_EOK;
}
/**
* This function will execute SCSI_READ_10 command to read data from the usb device.
*
* @param intf the interface instance.
* @param buffer the data buffer to save read data
* @param sector the start sector address to read.
* @param sector the sector count to read.
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_read10(struct uhintf* intf, rt_uint8_t *buffer,
rt_uint32_t sector, rt_size_t count, int timeout)
{
struct ustorage_cbw cmd;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_read10\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = SECTOR_SIZE * count;
cmd.dflags = CBWFLAGS_DIR_IN;
cmd.lun = 0;
cmd.cb_len = 10;
cmd.cb[0] = SCSI_READ_10;
cmd.cb[1] = 0;
cmd.cb[2] = (rt_uint8_t)(sector >> 24);
cmd.cb[3] = (rt_uint8_t)(sector >> 16);
cmd.cb[4] = (rt_uint8_t)(sector >> 8);
cmd.cb[5] = (rt_uint8_t)sector;
cmd.cb[6] = 0;
cmd.cb[7] = (count & 0xff00) >> 8;
cmd.cb[8] = (rt_uint8_t) count & 0xff;
return rt_usb_bulk_only_xfer(intf, &cmd, buffer, timeout);
}
/**
* This function will execute SCSI_WRITE_10 command to write data to the usb device.
*
* @param intf the interface instance.
* @param buffer the data buffer to save write data
* @param sector the start sector address to write.
* @param sector the sector count to write.
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_write10(struct uhintf* intf, rt_uint8_t *buffer,
rt_uint32_t sector, rt_size_t count, int timeout)
{
struct ustorage_cbw cmd;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_write10\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = SECTOR_SIZE * count;
cmd.dflags = CBWFLAGS_DIR_OUT;
cmd.lun = 0;
cmd.cb_len = 10;
cmd.cb[0] = SCSI_WRITE_10;
cmd.cb[1] = 0;
cmd.cb[2] = (rt_uint8_t)(sector >> 24);
cmd.cb[3] = (rt_uint8_t)(sector >> 16);
cmd.cb[4] = (rt_uint8_t)(sector >> 8);
cmd.cb[5] = (rt_uint8_t)sector;
cmd.cb[6] = 0;
cmd.cb[7] = (count & 0xff00) >> 8;
cmd.cb[8] = (rt_uint8_t) count & 0xff;
return rt_usb_bulk_only_xfer(intf, &cmd, buffer, timeout);
}
/**
* This function will execute SCSI_REQUEST_SENSE command to get sense data.
*
* @param intf the interface instance.
* @param buffer the data buffer to save sense data
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_request_sense(struct uhintf* intf, rt_uint8_t* buffer)
{
struct ustorage_cbw cmd;
int timeout = 200;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_request_sense\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = 18;
cmd.dflags = CBWFLAGS_DIR_IN;
cmd.lun = 0;
cmd.cb_len = 6;
cmd.cb[0] = SCSI_REQUEST_SENSE;
cmd.cb[4] = 18;
return rt_usb_bulk_only_xfer(intf, &cmd, buffer, timeout);
}
/**
* This function will execute SCSI_TEST_UNIT_READY command to get unit ready status.
*
* @param intf the interface instance.
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_test_unit_ready(struct uhintf* intf)
{
struct ustorage_cbw cmd;
int timeout = 200;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_test_unit_ready\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = 0;
cmd.dflags = CBWFLAGS_DIR_OUT;
cmd.lun = 0;
cmd.cb_len = 12;
cmd.cb[0] = SCSI_TEST_UNIT_READY;
return rt_usb_bulk_only_xfer(intf, &cmd, RT_NULL, timeout);
}
/**
* This function will execute SCSI_INQUIRY_CMD command to get inquiry data.
*
* @param intf the interface instance.
* @param buffer the data buffer to save inquiry data
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_inquiry(struct uhintf* intf, rt_uint8_t* buffer)
{
struct ustorage_cbw cmd;
int timeout = 200;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_inquiry\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = 36;
cmd.dflags = CBWFLAGS_DIR_IN;
cmd.lun = 0;
cmd.cb_len = 6;//12
cmd.cb[0] = SCSI_INQUIRY_CMD;
cmd.cb[4] = 36;
return rt_usb_bulk_only_xfer(intf, &cmd, buffer, timeout);
}
/**
* This function will execute SCSI_READ_CAPACITY command to get capacity data.
*
* @param intf the interface instance.
* @param buffer the data buffer to save capacity data
*
* @return the error code, RT_EOK on successfully.
*/
rt_err_t rt_usbh_storage_get_capacity(struct uhintf* intf, rt_uint8_t* buffer)
{
struct ustorage_cbw cmd;
int timeout = 200;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_get_capacity\n"));
/* construct the command block wrapper */
rt_memset(&cmd, 0, sizeof(struct ustorage_cbw));
cmd.signature = CBW_SIGNATURE;
cmd.tag = CBW_TAG_VALUE;
cmd.xfer_len = 8;
cmd.dflags = CBWFLAGS_DIR_IN;
cmd.lun = 0;
cmd.cb_len = 12;
cmd.cb[0] = SCSI_READ_CAPACITY;
return rt_usb_bulk_only_xfer(intf, &cmd, buffer, timeout);
}
/**
* This function will run mass storage class driver when usb device is detected
* and identified as a mass storage class device, it will continue to do the enumulate
* process.
*
* @param arg the argument.
*
* @return the error code, RT_EOK on successfully.
*/
static rt_err_t rt_usbh_storage_enable(void* arg)
{
int i = 0;
rt_err_t ret;
ustor_t stor;
struct uhintf* intf = (struct uhintf*)arg;
/* parameter check */
if(intf == RT_NULL)
{
rt_kprintf("the interface is not available\n");
return -RT_EIO;
}
RT_DEBUG_LOG(RT_DEBUG_USB, ("subclass %d, protocal %d\n",
intf->intf_desc->bInterfaceSubClass,
intf->intf_desc->bInterfaceProtocol));
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_run\n"));
/* only support SCSI subclass and bulk only protocal */
stor = rt_malloc(sizeof(struct ustor));
RT_ASSERT(stor != RT_NULL);
/* initilize the data structure */
rt_memset(stor, 0, sizeof(struct ustor));
intf->user_data = (void*)stor;
for(i=0; i<intf->intf_desc->bNumEndpoints; i++)
{
uep_desc_t ep_desc;
/* get endpoint descriptor from interface descriptor */
rt_usbh_get_endpoint_descriptor(intf->intf_desc, i, &ep_desc);
if(ep_desc == RT_NULL)
{
rt_kprintf("rt_usb_get_endpoint_descriptor error\n");
return -RT_ERROR;
}
/* the endpoint type of mass storage class should be BULK */
if((ep_desc->bmAttributes & USB_EP_ATTR_TYPE_MASK) != USB_EP_ATTR_BULK)
continue;
/* allocate pipes according to the endpoint type */
if(ep_desc->bEndpointAddress & USB_DIR_IN)
{
/* alloc an in pipe for the storage instance */
stor->pipe_in = rt_usb_instance_find_pipe(intf->device,ep_desc->bEndpointAddress);
}
else
{
/* alloc an output pipe for the storage instance */
stor->pipe_out = rt_usb_instance_find_pipe(intf->device,ep_desc->bEndpointAddress);
}
}
/* check pipes infomation */
if(stor->pipe_in == RT_NULL || stor->pipe_out == RT_NULL)
{
rt_kprintf("pipe error, unsupported device\n");
return -RT_ERROR;
}
/* should implement as callback */
ret = rt_udisk_run(intf);
if(ret != RT_EOK) return ret;
return RT_EOK;
}
/**
* This function will be invoked when usb device plug out is detected and it would clean
* and release all mass storage class related resources.
*
* @param arg the argument.
*
* @return the error code, RT_EOK on successfully.
*/
static rt_err_t rt_usbh_storage_disable(void* arg)
{
ustor_t stor;
struct uhintf* intf = (struct uhintf*)arg;
/* parameter check */
RT_ASSERT(intf != RT_NULL);
RT_ASSERT(intf->user_data != RT_NULL);
RT_ASSERT(intf->device != RT_NULL);
RT_DEBUG_LOG(RT_DEBUG_USB, ("rt_usbh_storage_stop\n"));
/* get storage instance from interface instance */
stor = (ustor_t)intf->user_data;
rt_udisk_stop(intf);
/* free storage instance */
if(stor != RT_NULL) rt_free(stor);
return RT_EOK;
}
/**
* This function will register mass storage class driver to the usb class driver manager.
* and it should be invoked in the usb system initialization.
*
* @return the error code, RT_EOK on successfully.
*/
ucd_t rt_usbh_class_driver_storage(void)
{
storage_driver.class_code = USB_CLASS_MASS_STORAGE;
storage_driver.enable = rt_usbh_storage_enable;
storage_driver.disable = rt_usbh_storage_disable;
return &storage_driver;
}
#endif