/**************************************************************************** * drivers/usbdev/usbmsc.c * * Copyright (C) 2008-2012, 2016-2017 Gregory Nutt. All rights reserved. * Author: Gregory Nutt * * Mass storage class device. Bulk-only with SCSI subclass. * * References: * "Universal Serial Bus Mass Storage Class, Specification Overview," * Revision 1.2, USB Implementer's Forum, June 23, 2003. * * "Universal Serial Bus Mass Storage Class, Bulk-Only Transport," * Revision 1.0, USB Implementer's Forum, September 31, 1999. * * "SCSI Primary Commands - 3 (SPC-3)," American National Standard * for Information Technology, May 4, 2005 * * "SCSI Primary Commands - 4 (SPC-4)," American National Standard * for Information Technology, July 19, 2008 * * "SCSI Block Commands -2 (SBC-2)," American National Standard * for Information Technology, November 13, 2004 * * "SCSI Multimedia Commands - 3 (MMC-3)," American National Standard * for Information Technology, November 12, 2001 * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "usbmsc.h" #ifdef CONFIG_USBMSC_COMPOSITE # include # include "composite.h" #endif /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ /**************************************************************************** * Private Types ****************************************************************************/ /* The internal version of the class driver */ struct usbmsc_driver_s { struct usbdevclass_driver_s drvr; FAR struct usbmsc_dev_s *dev; }; /* This is what is allocated */ struct usbmsc_alloc_s { struct usbmsc_dev_s dev; struct usbmsc_driver_s drvr; }; /**************************************************************************** * Private Function Prototypes ****************************************************************************/ /* Class Driver Support *****************************************************/ static void usbmsc_ep0incomplete(FAR struct usbdev_ep_s *ep, FAR struct usbdev_req_s *req); static struct usbdev_req_s *usbmsc_allocreq(FAR struct usbdev_ep_s *ep, uint16_t len); static void usbmsc_freereq(FAR struct usbdev_ep_s *ep, FAR struct usbdev_req_s *req); /* Class Driver Operations (most at interrupt level) ************************/ static int usbmsc_bind(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev); static void usbmsc_unbind(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev); static int usbmsc_setup(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev, FAR const struct usb_ctrlreq_s *ctrl, FAR uint8_t *dataout, size_t outlen); static void usbmsc_disconnect(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev); /* Initialization/Uninitialization ******************************************/ static void usbmsc_lununinitialize(struct usbmsc_lun_s *lun); #ifdef CONFIG_USBMSC_COMPOSITE static int usbmsc_exportluns(FAR void *handle); #endif /**************************************************************************** * Private Data ****************************************************************************/ /* Driver operations ********************************************************/ static struct usbdevclass_driverops_s g_driverops = { usbmsc_bind, /* bind */ usbmsc_unbind, /* unbind */ usbmsc_setup, /* setup */ usbmsc_disconnect, /* disconnect */ NULL, /* suspend */ NULL /* resume */ }; /* Used to hand-off the state structure when the SCSI worker thread is started */ FAR struct usbmsc_dev_s *g_usbmsc_handoff; /**************************************************************************** * Public Data ****************************************************************************/ /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Class Driver Support ****************************************************************************/ /**************************************************************************** * Name: usbmsc_ep0incomplete * * Description: * Handle completion of EP0 control operations * ****************************************************************************/ static void usbmsc_ep0incomplete(FAR struct usbdev_ep_s *ep, FAR struct usbdev_req_s *req) { if (req->result || req->xfrd != req->len) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_REQRESULT), (uint16_t)-req->result); } } /**************************************************************************** * Name: usbmsc_allocreq * * Description: * Allocate a request instance along with its buffer * ****************************************************************************/ static struct usbdev_req_s *usbmsc_allocreq(FAR struct usbdev_ep_s *ep, uint16_t len) { FAR struct usbdev_req_s *req; req = EP_ALLOCREQ(ep); if (req != NULL) { req->len = len; req->buf = EP_ALLOCBUFFER(ep, len); if (!req->buf) { EP_FREEREQ(ep, req); req = NULL; } } return req; } /**************************************************************************** * Name: usbmsc_freereq * * Description: * Free a request instance along with its buffer * ****************************************************************************/ static void usbmsc_freereq(FAR struct usbdev_ep_s *ep, struct usbdev_req_s *req) { if (ep != NULL && req != NULL) { if (req->buf != NULL) { EP_FREEBUFFER(ep, req->buf); } EP_FREEREQ(ep, req); } } /**************************************************************************** * Class Driver Interfaces ****************************************************************************/ /**************************************************************************** * Name: usbmsc_bind * * Description: * Invoked when the driver is bound to a USB device driver * ****************************************************************************/ static int usbmsc_bind(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev) { FAR struct usbmsc_dev_s *priv = ((FAR struct usbmsc_driver_s *)driver)->dev; FAR struct usbmsc_req_s *reqcontainer; irqstate_t flags; int ret = OK; int i; usbtrace(TRACE_CLASSBIND, 0); /* Bind the structures */ priv->usbdev = dev; /* Save the reference to our private data structure in EP0 so that it * can be recovered in ep0 completion events (Unless we are part of * a composite device and, in that case, the composite device owns * EP0). */ #ifndef CONFIG_USBMSC_COMPOSITE dev->ep0->priv = priv; #endif /* The configured EP0 size should match the reported EP0 size. We could * easily adapt to the reported EP0 size, but then we could not use the * const, canned descriptors. */ DEBUGASSERT(CONFIG_USBMSC_EP0MAXPACKET == dev->ep0->maxpacket); /* Preallocate control request */ priv->ctrlreq = usbmsc_allocreq(dev->ep0, USBMSC_MXDESCLEN); if (priv->ctrlreq == NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_ALLOCCTRLREQ), 0); ret = -ENOMEM; goto errout; } priv->ctrlreq->callback = usbmsc_ep0incomplete; /* Pre-allocate all endpoints... the endpoints will not be functional * until the SET CONFIGURATION request is processed in usbmsc_setconfig. * This is done here because there may be calls to kmm_malloc and the SET * CONFIGURATION processing probably occurrs within interrupt handling * logic where kmm_malloc calls will fail. */ /* Pre-allocate the IN bulk endpoint */ priv->epbulkin = DEV_ALLOCEP(dev, USBMSC_MKEPBULKIN(&priv->devinfo), true, USB_EP_ATTR_XFER_BULK); if (!priv->epbulkin) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EPBULKINALLOCFAIL), 0); ret = -ENODEV; goto errout; } priv->epbulkin->priv = priv; /* Pre-allocate the OUT bulk endpoint */ priv->epbulkout = DEV_ALLOCEP(dev, USBMSC_MKEPBULKOUT(&priv->devinfo), false, USB_EP_ATTR_XFER_BULK); if (!priv->epbulkout) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EPBULKOUTALLOCFAIL), 0); ret = -ENODEV; goto errout; } priv->epbulkout->priv = priv; /* Pre-allocate read requests */ for (i = 0; i < CONFIG_USBMSC_NRDREQS; i++) { reqcontainer = &priv->rdreqs[i]; reqcontainer->req = usbmsc_allocreq(priv->epbulkout, CONFIG_USBMSC_BULKOUTREQLEN); if (reqcontainer->req == NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDALLOCREQ), (uint16_t)-ret); ret = -ENOMEM; goto errout; } reqcontainer->req->priv = reqcontainer; reqcontainer->req->callback = usbmsc_rdcomplete; } /* Pre-allocate write request containers and put in a free list */ for (i = 0; i < CONFIG_USBMSC_NWRREQS; i++) { reqcontainer = &priv->wrreqs[i]; reqcontainer->req = usbmsc_allocreq(priv->epbulkin, CONFIG_USBMSC_BULKINREQLEN); if (reqcontainer->req == NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_WRALLOCREQ), (uint16_t)-ret); ret = -ENOMEM; goto errout; } reqcontainer->req->priv = reqcontainer; reqcontainer->req->callback = usbmsc_wrcomplete; flags = enter_critical_section(); sq_addlast((FAR sq_entry_t *)reqcontainer, &priv->wrreqlist); leave_critical_section(flags); } /* Report if we are selfpowered (unless we are part of a composite device) */ #ifndef CONFIG_USBMSC_COMPOSITE #ifdef CONFIG_USBDEV_SELFPOWERED DEV_SETSELFPOWERED(dev); #endif /* And pull-up the data line for the soft connect function (unless we are * part of a composite device) */ DEV_CONNECT(dev); #endif return OK; errout: usbmsc_unbind(driver, dev); return ret; } /**************************************************************************** * Name: usbmsc_unbind * * Description: * Invoked when the driver is unbound from a USB device driver * ****************************************************************************/ static void usbmsc_unbind(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev) { FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_req_s *reqcontainer; irqstate_t flags; int i; usbtrace(TRACE_CLASSUNBIND, 0); #ifdef CONFIG_DEBUG_FEATURES if (!driver || !dev || !dev->ep0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNBINDINVALIDARGS), 0); return; } #endif /* Extract reference to private data */ priv = ((FAR struct usbmsc_driver_s *)driver)->dev; #ifdef CONFIG_DEBUG_FEATURES if (!priv) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EP0NOTBOUND1), 0); return; } #endif /* The worker thread should have already been stopped by the * driver un-initialize logic. */ DEBUGASSERT(priv->thstate == USBMSC_STATE_TERMINATED || priv->thstate == USBMSC_STATE_NOTSTARTED); /* Make sure that we are not already unbound */ if (priv != NULL) { /* Make sure that the endpoints have been unconfigured. If * we were terminated gracefully, then the configuration should * already have been reset. If not, then calling usbmsc_resetconfig * should cause the endpoints to immediately terminate all * transfers and return the requests to us (with result == -ESHUTDOWN) */ usbmsc_resetconfig(priv); up_mdelay(50); /* Free the pre-allocated control request */ if (priv->ctrlreq != NULL) { usbmsc_freereq(dev->ep0, priv->ctrlreq); priv->ctrlreq = NULL; } /* Free pre-allocated read requests (which should all have * been returned to the free list at this time -- we don't check) */ for (i = 0; i < CONFIG_USBMSC_NRDREQS; i++) { reqcontainer = &priv->rdreqs[i]; if (reqcontainer->req) { usbmsc_freereq(priv->epbulkout, reqcontainer->req); reqcontainer->req = NULL; } } /* Free the bulk OUT endpoint */ if (priv->epbulkout) { DEV_FREEEP(dev, priv->epbulkout); priv->epbulkout = NULL; } /* Free write requests that are not in use (which should be all * of them */ flags = enter_critical_section(); while (!sq_empty(&priv->wrreqlist)) { reqcontainer = (struct usbmsc_req_s *) sq_remfirst(&priv->wrreqlist); if (reqcontainer->req != NULL) { usbmsc_freereq(priv->epbulkin, reqcontainer->req); } } /* Free the bulk IN endpoint */ if (priv->epbulkin) { DEV_FREEEP(dev, priv->epbulkin); priv->epbulkin = NULL; } leave_critical_section(flags); } } /**************************************************************************** * Name: usbmsc_setup * * Description: * Invoked for ep0 control requests. This function probably executes * in the context of an interrupt handler. * ****************************************************************************/ static int usbmsc_setup(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev, FAR const struct usb_ctrlreq_s *ctrl, FAR uint8_t *dataout, size_t outlen) { FAR struct usbmsc_dev_s *priv; FAR struct usbdev_req_s *ctrlreq; uint16_t value; uint16_t index; uint16_t len; int ret = -EOPNOTSUPP; #ifdef CONFIG_DEBUG_FEATURES if (!driver || !dev || !dev->ep0 || !ctrl) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_SETUPINVALIDARGS), 0); return -EIO; } #endif /* Extract reference to private data */ usbtrace(TRACE_CLASSSETUP, ctrl->req); priv = ((FAR struct usbmsc_driver_s *)driver)->dev; #ifdef CONFIG_DEBUG_FEATURES if (!priv || !priv->ctrlreq) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EP0NOTBOUND2), 0); return -ENODEV; } #endif ctrlreq = priv->ctrlreq; /* Extract the little-endian 16-bit values to host order */ value = GETUINT16(ctrl->value); index = GETUINT16(ctrl->index); len = GETUINT16(ctrl->len); uinfo("type=%02x req=%02x value=%04x index=%04x len=%04x\n", ctrl->type, ctrl->req, value, index, len); if ((ctrl->type & USB_REQ_TYPE_MASK) == USB_REQ_TYPE_STANDARD) { /********************************************************************** * Standard Requests **********************************************************************/ switch (ctrl->req) { case USB_REQ_GETDESCRIPTOR: { /* The value field specifies the descriptor type in the MS byte and the * descriptor index in the LS byte (order is little endian) */ switch (ctrl->value[1]) { /* If the mass storage device is used in as part of a * composite device, then the device descriptor is is * provided by logic in the composite device implementation. */ #ifndef CONFIG_USBMSC_COMPOSITE case USB_DESC_TYPE_DEVICE: { ret = USB_SIZEOF_DEVDESC; memcpy(ctrlreq->buf, usbmsc_getdevdesc(), ret); } break; #endif /* If the mass storage device is used in as part of a * composite device, then the device qualifier descriptor is * provided by logic in the composite device implementation. */ #if !defined(CONFIG_USBMSC_COMPOSITE) && defined(CONFIG_USBDEV_DUALSPEED) case USB_DESC_TYPE_DEVICEQUALIFIER: { ret = USB_SIZEOF_QUALDESC; memcpy(ctrlreq->buf, usbmsc_getqualdesc(), ret); } break; case USB_DESC_TYPE_OTHERSPEEDCONFIG: #endif /* If the mass storage device is used in as part of a composite device, * then the configuration descriptor is provided by logic in the * composite device implementation. */ #ifndef CONFIG_USBMSC_COMPOSITE case USB_DESC_TYPE_CONFIG: { #ifdef CONFIG_USBDEV_DUALSPEED ret = usbmsc_mkcfgdesc(ctrlreq->buf, &priv->devinfo, dev->speed, ctrl->value[1]); #else ret = usbmsc_mkcfgdesc(ctrlreq->buf, &priv->devinfo); #endif } break; #endif /* If the mass storage device is used in as part of a * composite device, then the language string descriptor is * provided by logic in the composite device implementation. */ #ifndef CONFIG_USBMSC_COMPOSITE case USB_DESC_TYPE_STRING: { /* index == language code. */ ret = usbmsc_mkstrdesc(ctrl->value[0], (struct usb_strdesc_s *)ctrlreq->buf); } break; #endif default: { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_GETUNKNOWNDESC), value); } break; } } break; case USB_REQ_SETCONFIGURATION: { if (ctrl->type == 0) { /* Signal the worker thread to instantiate the new * configuration. */ priv->theventset |= USBMSC_EVENT_CFGCHANGE; priv->thvalue = value; usbmsc_scsi_signal(priv); /* Return here... the response will be provided later by the * worker thread. */ return OK; } } break; /* If the mass storage device is used in as part of a composite * device, then the overall composite class configuration is * managed by logic in the composite device implementation. */ #ifndef CONFIG_USBMSC_COMPOSITE case USB_REQ_GETCONFIGURATION: { if (ctrl->type == USB_DIR_IN) { ctrlreq->buf[0] = priv->config; ret = 1; } } break; #endif case USB_REQ_SETINTERFACE: { if (ctrl->type == USB_REQ_RECIPIENT_INTERFACE) { if (priv->config == USBMSC_CONFIGID && index == USBMSC_INTERFACEID && value == USBMSC_ALTINTERFACEID) { /* Signal to instantiate the interface change */ priv->theventset |= USBMSC_EVENT_IFCHANGE; usbmsc_scsi_signal(priv); /* Return here... the response will be provided later by * the worker thread. */ return OK; } } } break; case USB_REQ_GETINTERFACE: { if (ctrl->type == (USB_DIR_IN | USB_REQ_RECIPIENT_INTERFACE) && priv->config == USBMSC_CONFIGIDNONE) { if (index != USBMSC_INTERFACEID) { ret = -EDOM; } else { ctrlreq->buf[0] = USBMSC_ALTINTERFACEID; ret = 1; } } } break; default: usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNSUPPORTEDSTDREQ), ctrl->req); break; } } else if ((ctrl->type & USB_REQ_TYPE_MASK) == USB_REQ_TYPE_CLASS) { /********************************************************************** * Bulk-Only Mass Storage Class Requests **********************************************************************/ /* Verify that we are configured */ if (!priv->config) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_NOTCONFIGURED), 0); return ret; } switch (ctrl->req) { case USBMSC_REQ_MSRESET: /* Reset mass storage device and interface */ { if (ctrl->type == USBMSC_TYPE_SETUPOUT && value == 0 && len == 0) { /* Only one interface is supported */ if (index != USBMSC_INTERFACEID) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_MSRESETNDX), index); ret = -EDOM; } else { /* Signal to stop the current operation and reinitialize * state. */ priv->theventset |= USBMSC_EVENT_RESET; usbmsc_scsi_signal(priv); /* Return here... the response will be provided later by * the worker thread. */ return OK; } } } break; case USBMSC_REQ_GETMAXLUN: /* Return number LUNs supported */ { if (ctrl->type == USBMSC_TYPE_SETUPIN && value == 0 && len == 1) { /* Only one interface is supported */ if (index != USBMSC_INTERFACEID) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_GETMAXLUNNDX), index); ret = -EDOM; } else { ctrlreq->buf[0] = priv->nluns - 1; ret = 1; } } } break; default: usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BADREQUEST), ctrl->req); break; } } else { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNSUPPORTEDTYPE), ctrl->type); } /* Respond to the setup command if data was returned. On an error return * value (ret < 0), the USB driver will stall EP0. */ if (ret >= 0) { /* Configure the response */ ctrlreq->len = MIN(len, ret); ctrlreq->flags = USBDEV_REQFLAGS_NULLPKT; /* Send the response -- either directly to the USB controller or * indirectly in the case where this class is a member of a composite * device. */ #ifndef CONFIG_USBMSC_COMPOSITE ret = EP_SUBMIT(dev->ep0, ctrlreq); #else ret = composite_ep0submit(driver, dev, ctrlreq); #endif if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EPRESPQ), (uint16_t)-ret); #if 0 /* Not necessary */ ctrlreq->result = OK; usbmsc_ep0incomplete(dev->ep0, ctrlreq); #endif } } return ret; } /**************************************************************************** * Name: usbmsc_disconnect * * Description: * Invoked after all transfers have been stopped, when the host is * disconnected. This function is probably called from the context of an * interrupt handler. * ****************************************************************************/ static void usbmsc_disconnect(FAR struct usbdevclass_driver_s *driver, FAR struct usbdev_s *dev) { struct usbmsc_dev_s *priv; irqstate_t flags; usbtrace(TRACE_CLASSDISCONNECT, 0); #ifdef CONFIG_DEBUG_FEATURES if (!driver || !dev || !dev->ep0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_DISCONNECTINVALIDARGS), 0); return; } #endif /* Extract reference to private data */ priv = ((FAR struct usbmsc_driver_s *)driver)->dev; #ifdef CONFIG_DEBUG_FEATURES if (!priv) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EP0NOTBOUND3), 0); return; } #endif /* Reset the configuration */ flags = enter_critical_section(); usbmsc_resetconfig(priv); /* Signal the worker thread */ priv->theventset |= USBMSC_EVENT_DISCONNECT; usbmsc_scsi_signal(priv); leave_critical_section(flags); /* Perform the soft connect function so that we will we can be * re-enumerated (unless we are part of a composite device) */ #ifndef CONFIG_USBMSC_COMPOSITE DEV_CONNECT(dev); #endif } /**************************************************************************** * Initialization/Un-Initialization ****************************************************************************/ /**************************************************************************** * Name: usbmsc_lununinitialize ****************************************************************************/ static void usbmsc_lununinitialize(struct usbmsc_lun_s *lun) { /* Has a block driver has been bound to the LUN? */ if (lun->inode) { /* Close the block driver */ (void)close_blockdriver(lun->inode); } memset(lun, 0, sizeof(struct usbmsc_lun_s)); } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Internal Interfaces ****************************************************************************/ /**************************************************************************** * Name: usbmsc_setconfig * * Description: * Set the device configuration by allocating and configuring endpoints and * by allocating and queuing read and write requests. * ****************************************************************************/ int usbmsc_setconfig(FAR struct usbmsc_dev_s *priv, uint8_t config) { FAR struct usbmsc_req_s *privreq; FAR struct usbdev_req_s *req; struct usb_epdesc_s epdesc; bool hispeed = false; int i; int ret = 0; #ifdef CONFIG_DEBUG_FEATURES if (priv == NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_SETCONFIGINVALIDARGS), 0); return -EIO; } #endif if (config == priv->config) { /* Already configured -- Do nothing */ usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_ALREADYCONFIGURED), 0); return OK; } #ifdef CONFIG_USBDEV_DUALSPEED hispeed = (priv->usbdev->speed == USB_SPEED_HIGH); #endif /* Discard the previous configuration data */ usbmsc_resetconfig(priv); /* Was this a request to simply discard the current configuration? */ if (config == USBMSC_CONFIGIDNONE) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_CONFIGNONE), 0); return OK; } /* We only accept one configuration */ if (config != USBMSC_CONFIGID) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_CONFIGIDBAD), 0); return -EINVAL; } /* Configure the IN bulk endpoint */ usbmsc_copy_epdesc(USBMSC_EPBULKIN, &epdesc, &priv->devinfo, hispeed); ret = EP_CONFIGURE(priv->epbulkin, &epdesc, false); if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EPBULKINCONFIGFAIL), 0); goto errout; } priv->epbulkin->priv = priv; /* Configure the OUT bulk endpoint */ usbmsc_copy_epdesc(USBMSC_EPBULKOUT, &epdesc, &priv->devinfo, hispeed); ret = EP_CONFIGURE(priv->epbulkout, &epdesc, true); if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EPBULKOUTCONFIGFAIL), 0); goto errout; } priv->epbulkout->priv = priv; /* Queue read requests in the bulk OUT endpoint */ for (i = 0; i < CONFIG_USBMSC_NRDREQS; i++) { privreq = &priv->rdreqs[i]; req = privreq->req; req->len = CONFIG_USBMSC_BULKOUTREQLEN; req->priv = privreq; req->callback = usbmsc_rdcomplete; ret = EP_SUBMIT(priv->epbulkout, req); if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDSUBMIT), (uint16_t)-ret); goto errout; } } priv->config = config; return OK; errout: usbmsc_resetconfig(priv); return ret; } /**************************************************************************** * Name: usbmsc_resetconfig * * Description: * Mark the device as not configured and disable all endpoints. * ****************************************************************************/ void usbmsc_resetconfig(FAR struct usbmsc_dev_s *priv) { /* Are we configured? */ if (priv->config != USBMSC_CONFIGIDNONE) { /* Yes.. but not anymore */ priv->config = USBMSC_CONFIGIDNONE; /* Disable endpoints. This should force completion of all pending * transfers. */ EP_DISABLE(priv->epbulkin); EP_DISABLE(priv->epbulkout); } } /**************************************************************************** * Name: usbmsc_wrcomplete * * Description: * Handle completion of write request. This function probably executes * in the context of an interrupt handler. * ****************************************************************************/ void usbmsc_wrcomplete(FAR struct usbdev_ep_s *ep, FAR struct usbdev_req_s *req) { FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_req_s *privreq; irqstate_t flags; /* Sanity check */ #ifdef CONFIG_DEBUG_FEATURES if (!ep || !ep->priv || !req || !req->priv) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_WRCOMPLETEINVALIDARGS), 0); return; } #endif /* Extract references to private data */ priv = (FAR struct usbmsc_dev_s *)ep->priv; privreq = (FAR struct usbmsc_req_s *)req->priv; /* Return the write request to the free list */ flags = enter_critical_section(); sq_addlast((FAR sq_entry_t *)privreq, &priv->wrreqlist); leave_critical_section(flags); /* Process the received data unless this is some unusual condition */ switch (req->result) { case OK: /* Normal completion */ usbtrace(TRACE_CLASSWRCOMPLETE, req->xfrd); break; case -ESHUTDOWN: /* Disconnection */ usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_WRSHUTDOWN), 0); break; default: /* Some other error occurred */ usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_WRUNEXPECTED), (uint16_t)-req->result); break; }; /* Inform the worker thread that a write request has been returned */ priv->theventset |= USBMSC_EVENT_WRCOMPLETE; usbmsc_scsi_signal(priv); } /**************************************************************************** * Name: usbmsc_rdcomplete * * Description: * Handle completion of read request on the bulk OUT endpoint. This * is handled like the receipt of serial data on the "UART" * ****************************************************************************/ void usbmsc_rdcomplete(FAR struct usbdev_ep_s *ep, FAR struct usbdev_req_s *req) { FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_req_s *privreq; irqstate_t flags; int ret; /* Sanity check */ #ifdef CONFIG_DEBUG_FEATURES if (!ep || !ep->priv || !req || !req->priv) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDCOMPLETEINVALIDARGS), 0); return; } #endif /* Extract references to private data */ priv = (FAR struct usbmsc_dev_s *)ep->priv; privreq = (FAR struct usbmsc_req_s *)req->priv; /* Process the received data unless this is some unusual condition */ switch (req->result) { case 0: /* Normal completion */ { usbtrace(TRACE_CLASSRDCOMPLETE, req->xfrd); /* Add the filled read request from the rdreqlist */ flags = enter_critical_section(); sq_addlast((FAR sq_entry_t *)privreq, &priv->rdreqlist); leave_critical_section(flags); /* Signal the worker thread that there is received data to be processed */ priv->theventset |= USBMSC_EVENT_RDCOMPLETE; usbmsc_scsi_signal(priv); } break; case -ESHUTDOWN: /* Disconnection */ { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDSHUTDOWN), 0); /* Drop the read request... it will be cleaned up later */ } break; default: /* Some other error occurred */ { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDUNEXPECTED), (uint16_t)-req->result); /* Return the read request to the bulk out endpoint for re-filling */ req = privreq->req; req->priv = privreq; req->callback = usbmsc_rdcomplete; ret = EP_SUBMIT(priv->epbulkout, req); if (ret != OK) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_RDCOMPLETERDSUBMIT), (uint16_t)-ret); } } break; } } /**************************************************************************** * Name: usbmsc_deferredresponse * * Description: * Some EP0 setup request cannot be responded to immediately becuase they * require some asynchronous action from the SCSI worker thread. This * function is provided for the SCSI thread to make that deferred response. * The specific requests that require this deferred response are: * * 1. USB_REQ_SETCONFIGURATION, * 2. USB_REQ_SETINTERFACE, or * 3. USBMSC_REQ_MSRESET * * In all cases, the success reponse is a zero-length packet; the failure * response is an EP0 stall. * * Input Parameters: * priv - Private state structure for this USB storage instance * stall - true is the action failed and a stall is required * ****************************************************************************/ void usbmsc_deferredresponse(FAR struct usbmsc_dev_s *priv, bool failed) { FAR struct usbdev_s *dev; FAR struct usbdev_req_s *ctrlreq; int ret; #ifdef CONFIG_DEBUG_FEATURES if (!priv || !priv->usbdev || !priv->ctrlreq) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_DEFERREDRESPINVALIDARGS), 0); return; } #endif dev = priv->usbdev; ctrlreq = priv->ctrlreq; /* If no error occurs, respond to the deferred setup command with a null * packet. */ if (!failed) { ctrlreq->len = 0; ctrlreq->flags = USBDEV_REQFLAGS_NULLPKT; ret = EP_SUBMIT(dev->ep0, ctrlreq); if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_DEFERREDRESPSUBMIT), (uint16_t)-ret); #if 0 /* Not necessary */ ctrlreq->result = OK; usbmsc_ep0incomplete(dev->ep0, ctrlreq); #endif } } else { /* On a failure, the USB driver will stall. */ usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_DEFERREDRESPSTALLED), 0); EP_STALL(dev->ep0); } } /**************************************************************************** * Name: usbmsc_sync_wait * * Description: * Wait for the worker thread to obtain the USB MSC state data * ****************************************************************************/ static inline void usbmsc_sync_wait(FAR struct usbmsc_dev_s *priv) { int ret; do { ret = nxsem_wait(&priv->thsynch); DEBUGASSERT(ret == OK || ret == -EINTR); } while (ret == -EINTR); } /**************************************************************************** * User Interfaces ****************************************************************************/ /**************************************************************************** * Name: usbmsc_configure * * Description: * One-time initialization of the USB storage driver. The initialization * sequence is as follows: * * 1. Call usbmsc_configure to perform one-time initialization specifying * the number of luns. * 2. Call usbmsc_bindlun to configure each supported LUN * 3. Call usbmsc_exportluns when all LUNs are configured * * Input Parameters: * nluns - the number of LUNs that will be registered * handle - Location to return a handle that is used in other API calls. * * Returned Value: * 0 on success; a negated errno on failure * ****************************************************************************/ int usbmsc_configure(unsigned int nluns, void **handle) { FAR struct usbmsc_alloc_s *alloc; FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_driver_s *drvr; int ret; #ifdef CONFIG_DEBUG_FEATURES if (nluns > 15) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_TOOMANYLUNS), 0); return -EDOM; } #endif /* Allocate the structures needed */ alloc = (FAR struct usbmsc_alloc_s *)kmm_malloc(sizeof(struct usbmsc_alloc_s)); if (!alloc) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_ALLOCDEVSTRUCT), 0); return -ENOMEM; } /* Initialize the USB storage driver structure */ priv = &alloc->dev; memset(priv, 0, sizeof(struct usbmsc_dev_s)); /* Initialize semaphores */ nxsem_init(&priv->thsynch, 0, 0); nxsem_init(&priv->thlock, 0, 1); nxsem_init(&priv->thwaitsem, 0, 0); /* The thsynch and thwaitsem semaphores are used for signaling and, hence, * should not have priority inheritance enabled. */ nxsem_setprotocol(&priv->thsynch, SEM_PRIO_NONE); nxsem_setprotocol(&priv->thwaitsem, SEM_PRIO_NONE); sq_init(&priv->wrreqlist); priv->nluns = nluns; /* Allocate the LUN table */ priv->luntab = (FAR struct usbmsc_lun_s *) kmm_malloc(priv->nluns*sizeof(struct usbmsc_lun_s)); if (!priv->luntab) { ret = -ENOMEM; goto errout; } memset(priv->luntab, 0, priv->nluns * sizeof(struct usbmsc_lun_s)); /* Initialize the USB class driver structure */ drvr = &alloc->drvr; #ifdef CONFIG_USBDEV_DUALSPEED drvr->drvr.speed = USB_SPEED_HIGH; #else drvr->drvr.speed = USB_SPEED_FULL; #endif drvr->drvr.ops = &g_driverops; drvr->dev = priv; /* Initialize the device information if we are not part of a composite. * If we are part of a composite, the device information will be * initialized through coordinated actions of usbmsc_get_composite_devdesc() * and board-specific logic. */ #ifndef CONFIG_USBMSC_COMPOSITE /* minor - not used */ /* Interfaces (ifnobase == 0) */ priv->devinfo.ninterfaces = USBMSC_NINTERFACES; /* Number of interfaces in the configuration */ /* Strings (strbase == 0) */ priv->devinfo.nstrings = USBMSC_NSTRIDS; /* Number of Strings */ /* Endpoints */ priv->devinfo.nendpoints = USBMSC_NENDPOINTS; priv->devinfo.epno[USBMSC_EP_BULKIN_IDX] = CONFIG_USBMSC_EPBULKIN; priv->devinfo.epno[USBMSC_EP_BULKOUT_IDX] = CONFIG_USBMSC_EPBULKOUT; #endif /* Return the handle and success */ *handle = (FAR void *)alloc; return OK; errout: usbmsc_uninitialize(alloc); return ret; } /**************************************************************************** * Name: usbmsc_bindlun * * Description: * Bind the block driver specified by drvrpath to a USB storage LUN. * * Input Parameters: * handle - The handle returned by a previous call to usbmsc_configure(). * drvrpath - the full path to the block driver * startsector - A sector offset into the block driver to the start of the * partition on drvrpath (0 if no partitions) * nsectors - The number of sectors in the partition (if 0, all sectors * to the end of the media will be exported). * lunno - the LUN to bind to * * Returned Value: * 0 on success; a negated errno on failure. * ****************************************************************************/ int usbmsc_bindlun(FAR void *handle, FAR const char *drvrpath, unsigned int lunno, off_t startsector, size_t nsectors, bool readonly) { FAR struct usbmsc_alloc_s *alloc = (FAR struct usbmsc_alloc_s *)handle; FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_lun_s *lun; FAR struct inode *inode; struct geometry geo; int ret; #ifdef CONFIG_DEBUG_FEATURES if (!alloc || !drvrpath || startsector < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BINLUNINVALIDARGS1), 0); return -EINVAL; } #endif priv = &alloc->dev; #ifdef CONFIG_DEBUG_FEATURES if (!priv->luntab) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_INTERNALCONFUSION1), 0); return -EIO; } if (lunno > priv->nluns) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BINDLUNINVALIDARGS2), 0); return -EINVAL; } #endif lun = &priv->luntab[lunno]; #ifdef CONFIG_DEBUG_FEATURES if (lun->inode != NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_LUNALREADYBOUND), 0); return -EBUSY; } #endif /* Open the block driver */ ret = open_blockdriver(drvrpath, 0, &inode); if (ret < 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BLKDRVEOPEN), 0); return ret; } /* Get the drive geometry */ if (!inode || !inode->u.i_bops || !inode->u.i_bops->geometry || inode->u.i_bops->geometry(inode, &geo) != OK || !geo.geo_available) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_NOGEOMETRY), 0); return -ENODEV; } /* Verify that the partition parameters are valid */ if (startsector >= geo.geo_nsectors) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BINDLUNINVALIDARGS3), 0); return -EDOM; } else if (nsectors == 0) { nsectors = geo.geo_nsectors - startsector; } else if (startsector + nsectors >= geo.geo_nsectors) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_BINDLUNINVALIDARGS4), 0); return -EDOM; } /* Initialize the LUN structure */ memset(lun, 0, sizeof(struct usbmsc_lun_s)); /* Allocate an I/O buffer big enough to hold one hardware sector. SCSI * commands are processed one at a time so all LUNs may share a single I/O * buffer. The I/O buffer will be allocated so that is it as large as the * largest block device sector size */ if (!priv->iobuffer) { priv->iobuffer = (FAR uint8_t *)kmm_malloc(geo.geo_sectorsize); if (!priv->iobuffer) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_ALLOCIOBUFFER), geo.geo_sectorsize); return -ENOMEM; } priv->iosize = geo.geo_sectorsize; } else if (priv->iosize < geo.geo_sectorsize) { FAR void *tmp; tmp = (FAR void *)kmm_realloc(priv->iobuffer, geo.geo_sectorsize); if (!tmp) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_REALLOCIOBUFFER), geo.geo_sectorsize); return -ENOMEM; } priv->iobuffer = (FAR uint8_t *)tmp; priv->iosize = geo.geo_sectorsize; } lun->inode = inode; lun->startsector = startsector; lun->nsectors = nsectors; lun->sectorsize = geo.geo_sectorsize; lun->readonly = readonly; /* If the driver does not support the write method, then this is read-only */ if (!inode->u.i_bops->write) { lun->readonly = true; } return OK; } /**************************************************************************** * Name: usbmsc_unbindlun * * Description: * Un-bind the block driver for the specified LUN * * Input Parameters: * handle - The handle returned by a previous call to usbmsc_configure(). * lun - the LUN to unbind from * * Returned Value: * 0 on success; a negated errno on failure. * ****************************************************************************/ int usbmsc_unbindlun(FAR void *handle, unsigned int lunno) { FAR struct usbmsc_alloc_s *alloc = (FAR struct usbmsc_alloc_s *)handle; FAR struct usbmsc_dev_s *priv; FAR struct usbmsc_lun_s *lun; int ret; #ifdef CONFIG_DEBUG_FEATURES if (!alloc) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNBINDLUNINVALIDARGS1), 0); return -EINVAL; } #endif priv = &alloc->dev; #ifdef CONFIG_DEBUG_FEATURES if (!priv->luntab) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_INTERNALCONFUSION2), 0); return -EIO; } if (lunno > priv->nluns) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNBINDLUNINVALIDARGS2), 0); return -EINVAL; } #endif lun = &priv->luntab[lunno]; usbmsc_scsi_lock(priv); #ifdef CONFIG_DEBUG_FEATURES if (lun->inode == NULL) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_LUNNOTBOUND), 0); ret = -EBUSY; } else #endif { /* Close the block driver */ usbmsc_lununinitialize(lun); ret = OK; } usbmsc_scsi_unlock(priv); return ret; } /**************************************************************************** * Name: usbmsc_exportluns * * Description: * After all of the LUNs have been bound, this function may be called * in order to export those LUNs in the USB storage device. * * Input Parameters: * handle - The handle returned by a previous call to usbmsc_configure(). * * Returned Value: * 0 on success; a negated errno on failure * ****************************************************************************/ #ifdef CONFIG_USBMSC_COMPOSITE static #endif int usbmsc_exportluns(FAR void *handle) { FAR struct usbmsc_alloc_s *alloc = (FAR struct usbmsc_alloc_s *)handle; FAR struct usbmsc_dev_s *priv; #ifndef CONFIG_USBMSC_COMPOSITE FAR struct usbmsc_driver_s *drvr; #endif irqstate_t flags; int ret = OK; #ifdef CONFIG_DEBUG_FEATURES if (!alloc) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_EXPORTLUNSINVALIDARGS), 0); return -ENXIO; } #endif priv = &alloc->dev; #ifndef CONFIG_USBMSC_COMPOSITE drvr = &alloc->drvr; #endif /* Start the worker thread * * REVISIT: g_usbmsc_handoff is a global and, hence, really requires * some protection against re-entrant usage. */ usbmsc_scsi_lock(priv); priv->thstate = USBMSC_STATE_NOTSTARTED; priv->theventset = USBMSC_EVENT_NOEVENTS; g_usbmsc_handoff = priv; uinfo("Starting SCSI worker thread\n"); priv->thpid = kthread_create("scsid", CONFIG_USBMSC_SCSI_PRIO, CONFIG_USBMSC_SCSI_STACKSIZE, usbmsc_scsi_main, NULL); if (priv->thpid <= 0) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_THREADCREATE), (uint16_t)errno); goto errout_with_lock; } /* Wait for the worker thread to run and initialize */ uinfo("Waiting for the SCSI worker thread\n"); usbmsc_sync_wait(priv); DEBUGASSERT(g_usbmsc_handoff == NULL); /* Register the USB storage class driver (unless we are part of a composite device) */ #ifndef CONFIG_USBMSC_COMPOSITE ret = usbdev_register(&drvr->drvr); if (ret != OK) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_DEVREGISTER), (uint16_t)-ret); goto errout_with_lock; } #endif /* Signal to start the thread */ uinfo("Signalling for the SCSI worker thread\n"); flags = enter_critical_section(); priv->theventset |= USBMSC_EVENT_READY; usbmsc_scsi_signal(priv); leave_critical_section(flags); errout_with_lock: usbmsc_scsi_unlock(priv); return ret; } /**************************************************************************** * Name: usbmsc_classobject * * Description: * Register USB mass storage device and return the class object. * * Input Parameters: * classdev - The location to return the CDC serial class' device * instance. * * Returned Value: * 0 on success; a negated errno on failure * ****************************************************************************/ #ifdef CONFIG_USBMSC_COMPOSITE int usbmsc_classobject(FAR void *handle, FAR struct usbdev_devinfo_s *devinfo, FAR struct usbdevclass_driver_s **classdev) { FAR struct usbmsc_alloc_s *alloc = (FAR struct usbmsc_alloc_s *)handle; int ret; DEBUGASSERT(handle != NULL && classdev != NULL); /* Save the device description */ memcpy(&alloc->dev.devinfo, devinfo, sizeof(struct usbdev_devinfo_s)); /* Export the LUNs as with the "standalone" USB mass storage driver, but * don't register the class instance with the USB device infrastructure. */ ret = usbmsc_exportluns(handle); if (ret == OK) { /* On success, return an (typed) instance of the class instance */ *classdev = &alloc->drvr.drvr; } return ret; } #endif /**************************************************************************** * Name: usbmsc_uninitialize * * Description: * Un-initialize the USB storage class driver * * Input Parameters: * handle - The handle returned by a previous call to usbmsc_configure(). * * Returned Value: * None * ****************************************************************************/ void usbmsc_uninitialize(FAR void *handle) { FAR struct usbmsc_alloc_s *alloc = (FAR struct usbmsc_alloc_s *)handle; FAR struct usbmsc_dev_s *priv; irqstate_t flags; int i; #ifdef CONFIG_DEBUG_FEATURES if (!handle) { usbtrace(TRACE_CLSERROR(USBMSC_TRACEERR_UNINITIALIZEINVALIDARGS), 0); return; } #endif priv = &alloc->dev; #ifdef CONFIG_USBMSC_COMPOSITE /* Check for pass 2 uninitialization. We did most of the work on the * first pass uninitialization. */ if (priv->thpid == 0) { /* In this second and final pass, all that remains to be done is to * free the memory resources. */ kmm_free(priv); return; } #endif /* If the thread hasn't already exitted, tell it to exit now */ if (priv->thstate != USBMSC_STATE_NOTSTARTED) { /* The thread was started.. Is it still running? */ usbmsc_scsi_lock(priv); if (priv->thstate != USBMSC_STATE_TERMINATED) { /* Yes.. Ask the thread to stop */ flags = enter_critical_section(); priv->theventset |= USBMSC_EVENT_TERMINATEREQUEST; usbmsc_scsi_signal(priv); leave_critical_section(flags); } usbmsc_scsi_unlock(priv); /* Wait for the thread to exit */ while ((priv->theventset & USBMSC_EVENT_TERMINATEREQUEST) != 0) { usbmsc_sync_wait(priv); } } priv->thpid = 0; /* Unregister the driver (unless we are a part of a composite device) */ #ifndef CONFIG_USBMSC_COMPOSITE usbdev_unregister(&alloc->drvr.drvr); #endif /* Uninitialize and release the LUNs */ for (i = 0; i < priv->nluns; ++i) { usbmsc_lununinitialize(&priv->luntab[i]); } kmm_free(priv->luntab); /* Release the I/O buffer */ if (priv->iobuffer) { kmm_free(priv->iobuffer); } /* Uninitialize and release the driver structure */ nxsem_destroy(&priv->thsynch); nxsem_destroy(&priv->thlock); nxsem_destroy(&priv->thwaitsem); #ifndef CONFIG_USBMSC_COMPOSITE /* For the case of the composite driver, there is a two pass * uninitialization sequence. We cannot yet free the driver structure. * We will do that on the second pass (and we will know that it is the * second pass because of priv->thpid == 0) */ kmm_free(priv); #endif } /**************************************************************************** * Name: usbmsc_get_composite_devdesc * * Description: * Helper function to fill in some constants into the composite * configuration struct. * * Input Parameters: * dev - Pointer to the configuration struct we should fill * * Returned Value: * None * ****************************************************************************/ #if defined(CONFIG_USBDEV_COMPOSITE) && defined(CONFIG_USBMSC_COMPOSITE) void usbmsc_get_composite_devdesc(FAR struct composite_devdesc_s *dev) { memset(dev, 0, sizeof(struct composite_devdesc_s)); /* The callback functions for the CDC/ACM class. * * classobject() and uninitialize() must be provided by board-specific * logic */ dev->mkconfdesc = usbmsc_mkcfgdesc; dev->mkstrdesc = usbmsc_mkstrdesc; dev->nconfigs = USBMSC_NCONFIGS; /* Number of configurations supported */ dev->configid = USBMSC_CONFIGID; /* The only supported configuration ID */ dev->cfgdescsize = SIZEOF_USBMSC_CFGDESC; /* The size of the config descriptor */ /* Board-specific logic must provide the device minor */ /* Interfaces. * * ifnobase must be provided by board-specific logic */ dev->devinfo.ninterfaces = USBMSC_NINTERFACES; /* Number of interfaces in the configuration */ /* Strings. * * strbase must be provided by board-specific logic */ dev->devinfo.nstrings = USBMSC_NSTRIDS; /* Number of Strings */ /* Endpoints. * * Endpoint numbers must be provided by board-specific logic. */ dev->devinfo.nendpoints = USBMSC_NENDPOINTS; } #endif