/* * File : mstorage.c * This file is part of RT-Thread RTOS * COPYRIGHT (C) 2012, 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 * 2012-10-01 Yi Qiu first version * 2012-11-25 Heyuanjie87 reduce the memory consumption * 2012-12-09 Heyuanjie87 change class and endpoint handler */ #include #include #include #include "mstorage.h" #ifdef RT_USB_DEVICE_MSTORAGE #define STATUS_CBW 0x00 #define STATUS_CSW 0x01 #define STATUS_RECEIVE 0x02 #define STATUS_SEND 0x03 static int status = STATUS_CBW; ALIGN(RT_ALIGN_SIZE) static struct ustorage_csw csw; static rt_device_t disk; static rt_uint32_t _block; static rt_uint32_t _count, _size; static struct rt_device_blk_geometry geometry; static struct udevice_descriptor dev_desc = { USB_DESC_LENGTH_DEVICE, //bLength; USB_DESC_TYPE_DEVICE, //type; USB_BCD_VERSION, //bcdUSB; USB_CLASS_MASS_STORAGE, //bDeviceClass; 0x00, //bDeviceSubClass; 0x00, //bDeviceProtocol; 0x40, //bMaxPacketSize0; _VENDOR_ID, //idVendor; _PRODUCT_ID, //idProduct; USB_BCD_DEVICE, //bcdDevice; USB_STRING_MANU_INDEX, //iManufacturer; USB_STRING_PRODUCT_INDEX, //iProduct; USB_STRING_SERIAL_INDEX, //iSerialNumber; USB_DYNAMIC, //bNumConfigurations; }; const static struct umass_descriptor _mass_desc = { USB_DESC_LENGTH_INTERFACE, //bLength; USB_DESC_TYPE_INTERFACE, //type; USB_DYNAMIC, //bInterfaceNumber; 0x00, //bAlternateSetting; 0x02, //bNumEndpoints USB_CLASS_MASS_STORAGE, //bInterfaceClass; 0x06, //bInterfaceSubClass; 0x50, //bInterfaceProtocol; 0x00, //iInterface; USB_DESC_LENGTH_ENDPOINT, //bLength; USB_DESC_TYPE_ENDPOINT, //type; USB_DYNAMIC | USB_DIR_OUT, //bEndpointAddress; USB_EP_ATTR_BULK, //bmAttributes; 0x40, //wMaxPacketSize; 0x00, //bInterval; USB_DESC_LENGTH_ENDPOINT, //bLength; USB_DESC_TYPE_ENDPOINT, //type; USB_DYNAMIC | USB_DIR_IN, //bEndpointAddress; USB_EP_ATTR_BULK, //bmAttributes; 0x40, //wMaxPacketSize; 0x00, //bInterval; }; /** * This function will allocate an usb device instance from system. * * @param parent the hub instance to which the new allocated device attached. * @param port the hub port. * * @return the allocate instance on successful, or RT_NULL on failure. */ static rt_err_t _inquiry_cmd(udevice_t device, uep_t ep_in) { rt_uint8_t data[36]; *(rt_uint32_t*)&data[0] = 0x0 | (0x80 << 8); *(rt_uint32_t*)&data[4] = 31; rt_memset(&data[8], 0x20, 28); rt_memcpy(&data[8], "RTT", 3); rt_memcpy(&data[16], "USB Disk", 8); dcd_ep_write(device->dcd, ep_in, (rt_uint8_t*)&data, 36); return RT_EOK; } /** * This function will handle sense request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _request_sense(udevice_t device, uep_t ep_in) { struct request_sense_data data; data.ErrorCode = 0x70; data.Valid = 0; data.SenseKey = 5; data.Information[0] = 0; data.Information[1] = 0; data.Information[2] = 0; data.Information[3] = 0; data.AdditionalSenseLength = 0x0b; data.AdditionalSenseCode = 0x20; data.AdditionalSenseCodeQualifier =0; dcd_ep_write(device->dcd, ep_in, (rt_uint8_t*)&data, sizeof(struct request_sense_data)); return RT_EOK; } /** * This function will handle mode_sense_6 request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _mode_sense_6(udevice_t device, uep_t ep_in) { rt_uint8_t data[4]; data[0]=3; data[1]=0; data[2]=0; data[3]=0; dcd_ep_write(device->dcd, ep_in, (rt_uint8_t*)&data, 4); return RT_EOK; } /** * This function will handle read_capacities request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _read_capacities(udevice_t device, uep_t ep_in) { rt_uint8_t data[12]; rt_uint32_t sector_count, sector_size; RT_ASSERT(device != RT_NULL); sector_count = geometry.sector_count; sector_size = geometry.bytes_per_sector; *(rt_uint32_t*)&data[0] = 0x08000000; data[4] = sector_count >> 24; data[5] = 0xff & (sector_count >> 16); data[6] = 0xff & (sector_count >> 8); data[7] = 0xff & (sector_count); data[8] = 0x02; data[9] = 0xff & (sector_size >> 16); data[10] = 0xff & (sector_size >> 8); data[11] = 0xff & sector_size; dcd_ep_write(device->dcd, ep_in, (rt_uint8_t*)&data, 12); return RT_EOK; } /** * This function will handle read_capacity request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _read_capacity(udevice_t device, uep_t ep_in) { rt_uint8_t data[8]; rt_uint32_t sector_count, sector_size; RT_ASSERT(device != RT_NULL); sector_count = geometry.sector_count; sector_size = geometry.bytes_per_sector; data[0] = sector_count >> 24; data[1] = 0xff & (sector_count >> 16); data[2] = 0xff & (sector_count >> 8); data[3] = 0xff & (sector_count); data[4] = 0x0; data[5] = 0xff & (sector_size >> 16); data[6] = 0xff & (sector_size >> 8); data[7] = 0xff & sector_size; dcd_ep_write(device->dcd, ep_in, (rt_uint8_t*)&data, 8); return RT_EOK; } /** * This function will handle read_10 request. * * @param device the usb device object. * @param cbw the command block wrapper. * * @return RT_EOK on successful. */ static rt_err_t _read_10(udevice_t device, ustorage_cbw_t cbw, uep_t ep_in) { RT_ASSERT(device != RT_NULL); RT_ASSERT(cbw != RT_NULL); _block = cbw->cb[2]<<24 | cbw->cb[3]<<16 | cbw->cb[4]<<8 | cbw->cb[5]<<0 ; _count = cbw->cb[7]<<8 | cbw->cb[8]<<0 ; RT_ASSERT(_count < geometry.sector_count); rt_device_read(disk, _block, ep_in->buffer, 1); dcd_ep_write(device->dcd, ep_in, ep_in->buffer, geometry.bytes_per_sector); _count --; if (_count) { _block ++; status = STATUS_SEND; } else { status = STATUS_CSW; } return RT_EOK; } /** * This function will handle write_10 request. * * @param device the usb device object. * @param cbw the command block wrapper. * * @return RT_EOK on successful. */ static rt_err_t _write_10(udevice_t device, ustorage_cbw_t cbw, uep_t ep_out) { RT_ASSERT(device != RT_NULL); RT_ASSERT(cbw != RT_NULL); _block = cbw->cb[2]<<24 | cbw->cb[3]<<16 | cbw->cb[4]<<8 | cbw->cb[5]<<0 ; _count = cbw->cb[7]<<8 | cbw->cb[8]<<0; csw.data_reside = cbw->xfer_len; _size = _count * geometry.bytes_per_sector; RT_DEBUG_LOG(RT_DEBUG_USB, ("_write_10 count 0x%x 0x%x\n", _count, geometry.sector_count)); dcd_ep_read(device->dcd, ep_out, ep_out->buffer, geometry.bytes_per_sector); return RT_EOK; } /** * This function will handle verify_10 request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _verify_10(udevice_t device) { return RT_EOK; } /** * This function will handle mass storage bulk in endpoint request. * * @param device the usb device object. * @param size request size. * * @return RT_EOK. */ static rt_err_t _ep_in_handler(udevice_t device, uclass_t cls, rt_size_t size) { mass_eps_t eps; RT_ASSERT(device != RT_NULL); eps = cls->eps; if(status == STATUS_CSW) { dcd_ep_write(device->dcd, eps->ep_in, (rt_uint8_t*)&csw, SIZEOF_CSW); status = STATUS_CBW; dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, SIZEOF_CBW); } if(status == STATUS_SEND) { rt_device_read(disk, _block, eps->ep_in->buffer, 1); dcd_ep_write(device->dcd, eps->ep_in, eps->ep_in->buffer, geometry.bytes_per_sector); _count --; if (_count) { _block ++; status = STATUS_SEND; } else { status = STATUS_CSW; } } return RT_EOK; } #ifdef MASS_CBW_DUMP static void cbw_dump(struct ustorage_cbw* cbw) { RT_ASSERT(cbw != RT_NULL); RT_DEBUG_LOG(RT_DEBUG_USB, ("signature 0x%x\n", cbw->signature)); RT_DEBUG_LOG(RT_DEBUG_USB, ("tag 0x%x\n", cbw->tag)); RT_DEBUG_LOG(RT_DEBUG_USB, ("xfer_len 0x%x\n", cbw->xfer_len)); RT_DEBUG_LOG(RT_DEBUG_USB, ("dflags 0x%x\n", cbw->dflags)); RT_DEBUG_LOG(RT_DEBUG_USB, ("lun 0x%x\n", cbw->lun)); RT_DEBUG_LOG(RT_DEBUG_USB, ("cb_len 0x%x\n", cbw->cb_len)); RT_DEBUG_LOG(RT_DEBUG_USB, ("cb[0] 0x%x\n", cbw->cb[0])); } #endif /** * This function will handle mass storage bulk out endpoint request. * * @param device the usb device object. * @param size request size. * * @return RT_EOK. */ static rt_err_t _ep_out_handler(udevice_t device, uclass_t cls, rt_size_t size) { mass_eps_t eps; RT_ASSERT(device != RT_NULL); eps = (mass_eps_t)cls->eps; if(status == STATUS_CBW) { struct ustorage_cbw* cbw; /* dump cbw information */ cbw = (struct ustorage_cbw*)eps->ep_out->buffer; if(cbw->signature == CBW_SIGNATURE) { csw.signature = CSW_SIGNATURE; csw.tag = cbw->tag; csw.data_reside = 0; csw.status = 0; } else return -RT_ERROR; switch(cbw->cb[0]) { case SCSI_TEST_UNIT_READY: dcd_ep_write(device->dcd, eps->ep_in, (rt_uint8_t*)&csw, SIZEOF_CSW); dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, SIZEOF_CBW); break; case SCSI_REQUEST_SENSE: _request_sense(device, eps->ep_in); status = STATUS_CSW; break; case SCSI_INQUIRY_CMD: _inquiry_cmd(device, eps->ep_in); status = STATUS_CSW; break; case SCSI_MODE_SENSE_6: _mode_sense_6(device, eps->ep_in); status = STATUS_CSW; break; case SCSI_ALLOW_MEDIUM_REMOVAL: dcd_ep_write(device->dcd, eps->ep_in, (rt_uint8_t*)&csw, SIZEOF_CSW); dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, SIZEOF_CBW); break; case SCSI_READ_CAPACITIES: _read_capacities(device, eps->ep_in); status = STATUS_CSW; break; case SCSI_READ_CAPACITY: _read_capacity(device, eps->ep_in); status = STATUS_CSW; break; case SCSI_READ_10: _read_10(device, cbw, eps->ep_in); break; case SCSI_WRITE_10: _write_10(device, cbw, eps->ep_out); status = STATUS_RECEIVE; break; case SCSI_VERIFY_10: _verify_10(device); break; } } else if(status == STATUS_RECEIVE) { RT_DEBUG_LOG(RT_DEBUG_USB, ("write size 0x%x block 0x%x oount 0x%x\n", size, _block, _size)); _size -= size; csw.data_reside -= size; rt_device_write(disk, _block, eps->ep_in->buffer, 1); _block ++; if(_size == 0) { dcd_ep_write(device->dcd, eps->ep_in, (rt_uint8_t*)&csw, SIZEOF_CSW); dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, SIZEOF_CBW); status = STATUS_CBW; } else { dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, geometry.bytes_per_sector); } } else { rt_kprintf("none cbw status\n"); } return RT_EOK; } /** * This function will handle mass storage interface request. * * @param device the usb device object. * @param setup the setup request. * * @return RT_EOK on successful. */ static rt_err_t _interface_handler(udevice_t device, uclass_t cls, ureq_t setup) { rt_uint8_t lun = 0; RT_ASSERT(device != RT_NULL); RT_ASSERT(setup != RT_NULL); RT_DEBUG_LOG(RT_DEBUG_USB, ("_interface_handler\n")); switch(setup->request) { case USBREQ_GET_MAX_LUN: dcd_ep_write(device->dcd, 0, &lun, 1); break; case USBREQ_MASS_STORAGE_RESET: break; default: rt_kprintf("unknown interface request\n"); break; } return RT_EOK; } /** * This function will run mass storage class, it will be called on handle set configuration request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _class_run(udevice_t device, uclass_t cls) { mass_eps_t eps; rt_uint8_t *buffer; RT_ASSERT(device != RT_NULL); RT_DEBUG_LOG(RT_DEBUG_USB, ("mass storage run\n")); eps = (mass_eps_t)cls->eps; disk = rt_device_find(RT_USB_MSTORAGE_DISK_NAME); if(disk == RT_NULL) { rt_kprintf("no disk named %s\n", RT_USB_MSTORAGE_DISK_NAME); return -RT_ERROR; } if(rt_device_control(disk, RT_DEVICE_CTRL_BLK_GETGEOME, (void*)&geometry) != RT_EOK) return -RT_ERROR; buffer = (rt_uint8_t*)rt_malloc(geometry.bytes_per_sector); if(buffer == RT_NULL) return -RT_ENOMEM; eps->ep_out->buffer = buffer; eps->ep_in->buffer = buffer; dcd_ep_read(device->dcd, eps->ep_out, eps->ep_out->buffer, SIZEOF_CBW); return RT_EOK; } /** * This function will stop mass storage class, it will be called on handle set configuration request. * * @param device the usb device object. * * @return RT_EOK on successful. */ static rt_err_t _class_stop(udevice_t device, uclass_t cls) { mass_eps_t eps; RT_ASSERT(device != RT_NULL); RT_DEBUG_LOG(RT_DEBUG_USB, ("mass storage stop\n")); eps = (mass_eps_t)cls->eps; rt_free(eps->ep_in->buffer); eps->ep_out->buffer = RT_NULL; eps->ep_in->buffer = RT_NULL; return RT_EOK; } static struct uclass_ops ops = { _class_run, _class_stop, RT_NULL, }; /** * This function will create a mass storage class instance. * * @param device the usb device object. * * @return RT_EOK on successful. */ uclass_t rt_usbd_class_mstorage_create(udevice_t device) { uintf_t intf; mass_eps_t eps; uclass_t mstorage; ualtsetting_t setting; umass_desc_t mass_desc; /* parameter check */ RT_ASSERT(device != RT_NULL); /* create a mass storage class */ mstorage = rt_usbd_class_create(device, &dev_desc, &ops); /* create a mass storage endpoints collection */ eps = (mass_eps_t)rt_malloc(sizeof(struct mass_eps)); mstorage->eps = (void*)eps; /* create an interface */ intf = rt_usbd_interface_create(device, _interface_handler); /* create an alternate setting */ setting = rt_usbd_altsetting_create(sizeof(struct umass_descriptor)); /* config desc in alternate setting */ rt_usbd_altsetting_config_descriptor(setting, &_mass_desc, 0); /* create a bulk out and a bulk in endpoint */ mass_desc = (umass_desc_t)setting->desc; eps->ep_in = rt_usbd_endpoint_create(&mass_desc->ep_in_desc, _ep_in_handler); eps->ep_out = rt_usbd_endpoint_create(&mass_desc->ep_out_desc, _ep_out_handler); /* add the bulk out and bulk in endpoint to the alternate setting */ rt_usbd_altsetting_add_endpoint(setting, eps->ep_out); rt_usbd_altsetting_add_endpoint(setting, eps->ep_in); /* add the alternate setting to the interface, then set default setting */ rt_usbd_interface_add_altsetting(intf, setting); rt_usbd_set_altsetting(intf, 0); /* add the interface to the mass storage class */ rt_usbd_class_add_interface(mstorage, intf); return mstorage; } #endif