/**************************************************************************** * drivers/usbhost/usbhost_enumerate.c * * Copyright (C) 2011-2012, 2015, 2017 Gregory Nutt. All rights reserved. * Authors: Gregory Nutt * * 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 "usbhost_composite.h" /**************************************************************************** * Private Function Prototypes ****************************************************************************/ static inline uint16_t usbhost_getle16(const uint8_t *val); static void usbhost_putle16(uint8_t *dest, uint16_t val); static inline int usbhost_devdesc(const struct usb_devdesc_s *devdesc, FAR struct usbhost_id_s *id); static inline int usbhost_configdesc(const uint8_t *configdesc, int desclen, FAR struct usbhost_id_s *id); static inline int usbhost_classbind(FAR struct usbhost_hubport_s *hport, FAR const uint8_t *configdesc, int desclen, FAR struct usbhost_id_s *id, FAR struct usbhost_class_s **devclass); /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: usbhost_getle16 * * Description: * Get a (possibly unaligned) 16-bit little endian value. * ****************************************************************************/ static inline uint16_t usbhost_getle16(const uint8_t *val) { return (uint16_t)val[1] << 8 | (uint16_t)val[0]; } /**************************************************************************** * Name: usbhost_putle16 * * Description: * Put a (possibly unaligned) 16-bit little endian value. * ****************************************************************************/ static void usbhost_putle16(uint8_t *dest, uint16_t val) { dest[0] = val & 0xff; /* Little endian means LS byte first in byte stream */ dest[1] = val >> 8; } /**************************************************************************** * Name: usbhost_devdesc * * Description: * A configuration descriptor has been obtained from the device. Find the * ID information for the class that supports this device. * ****************************************************************************/ static inline int usbhost_devdesc(FAR const struct usb_devdesc_s *devdesc, FAR struct usbhost_id_s *id) { /* Clear the ID info */ memset(id, 0, sizeof(struct usbhost_id_s)); /* Pick off the class ID info */ id->base = devdesc->classid; id->subclass = devdesc->subclass; id->proto = devdesc->protocol; /* Pick off the VID and PID as well (for vendor specific devices) */ id->vid = usbhost_getle16(devdesc->vendor); id->pid = usbhost_getle16(devdesc->product); uinfo("class:%d subclass:%04x protocol:%04x vid:%d pid:%d\n", id->base, id->subclass, id->proto, id->vid, id->pid); return OK; } /**************************************************************************** * Name: usbhost_configdesc * * Description: * A configuration descriptor has been obtained from the device. Find the * ID information for the class that supports this device. * ****************************************************************************/ static inline int usbhost_configdesc(const uint8_t *configdesc, int cfglen, struct usbhost_id_s *id) { FAR struct usb_cfgdesc_s *cfgdesc; FAR struct usb_ifdesc_s *ifdesc; int remaining; DEBUGASSERT(configdesc != NULL && cfglen >= USB_SIZEOF_CFGDESC); /* Verify that we were passed a configuration descriptor */ cfgdesc = (struct usb_cfgdesc_s *)configdesc; uinfo("cfg len:%d total len:%d\n", cfgdesc->len, cfglen); if (cfgdesc->type != USB_DESC_TYPE_CONFIG) { return -EINVAL; } /* Skip to the next entry descriptor */ configdesc += cfgdesc->len; remaining = cfglen - cfgdesc->len; /* Loop while there are more descriptors to examine */ memset(id, 0, sizeof(FAR struct usb_desc_s)); while (remaining >= sizeof(struct usb_desc_s)) { /* What is the next descriptor? Is it an interface descriptor? */ ifdesc = (struct usb_ifdesc_s *)configdesc; if (ifdesc->type == USB_DESC_TYPE_INTERFACE) { /* Yes, extract the class information from the interface descriptor. * Typically these values are zero meaning that the "real" ID * information resides in the device descriptor. */ DEBUGASSERT(remaining >= sizeof(struct usb_ifdesc_s)); id->base = ifdesc->classid; id->subclass = ifdesc->subclass; id->proto = ifdesc->protocol; uinfo("class:%d subclass:%d protocol:%d\n", id->base, id->subclass, id->proto); return OK; } /* Increment the address of the next descriptor */ configdesc += ifdesc->len; remaining -= ifdesc->len; } return -ENOENT; } /**************************************************************************** * Name: usbhost_classbind * * Description: * A configuration descriptor has been obtained from the device. Try to * bind this configuration descriptor with a supported class. * ****************************************************************************/ static inline int usbhost_classbind(FAR struct usbhost_hubport_s *hport, const uint8_t *configdesc, int desclen, struct usbhost_id_s *id, FAR struct usbhost_class_s **usbclass) { FAR struct usbhost_class_s *devclass; FAR const struct usbhost_registry_s *reg; int ret = -EINVAL; /* Is there is a class implementation registered to support this device. */ reg = usbhost_findclass(id); uinfo("usbhost_findclass: %p\n", reg); if (reg != NULL) { /* Yes.. there is a class for this device. Get an instance of * its interface. */ ret = -ENOMEM; devclass = CLASS_CREATE(reg, hport, id); uinfo("CLASS_CREATE: %p\n", devclass); if (devclass != NULL) { /* Then bind the newly instantiated class instance */ ret = CLASS_CONNECT(devclass, configdesc, desclen); if (ret < 0) { /* On failures, call the class disconnect method which * should then free the allocated devclass instance. */ uerr("ERROR: CLASS_CONNECT failed: %d\n", ret); CLASS_DISCONNECTED(devclass); } else { *usbclass = devclass; } } } uinfo("Returning: %d\n", ret); return ret; } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: usbhost_enumerate * * Description: * Enumerate the connected device. As part of this enumeration process, * the driver will (1) get the device's configuration descriptor, (2) * extract the class ID info from the configuration descriptor, (3) call * usbhost_findclass() to find the class that supports this device, (4) * call the create() method on the struct usbhost_registry_s interface * to get a class instance, and finally (5) call the configdesc() method * of the struct usbhost_class_s interface. After that, the class is in * charge of the sequence of operations. * * Input Parameters: * hport - The hub port that manages the new class. * devclass - If the class driver for the device is successful located * and bound to the hub port, the allocated class instance is returned * into this caller-provided memory location. * * Returned Value: * On success, zero (OK) is returned. On a failure, a negated errno value is * returned indicating the nature of the failure * * Assumptions: * - Only a single class bound to a single device is supported. * - Called from a single thread so no mutual exclusion is required. * - Never called from an interrupt handler. * ****************************************************************************/ int usbhost_enumerate(FAR struct usbhost_hubport_s *hport, FAR struct usbhost_class_s **devclass) { FAR struct usb_ctrlreq_s *ctrlreq = NULL; struct usbhost_id_s id; size_t maxlen; unsigned int cfglen; uint8_t maxpacketsize; uint8_t descsize; uint8_t funcaddr = 0; FAR uint8_t *buffer = NULL; int ret; DEBUGASSERT(hport != NULL && hport->drvr != NULL); /* Allocate descriptor buffers for use in this function. We will need two: * One for the request and one for the data buffer. */ ret = DRVR_ALLOC(hport->drvr, (FAR uint8_t **)&ctrlreq, &maxlen); if (ret < 0) { uerr("ERROR: DRVR_ALLOC failed: %d\n", ret); return ret; } ret = DRVR_ALLOC(hport->drvr, &buffer, &maxlen); if (ret < 0) { uerr("ERROR: DRVR_ALLOC failed: %d\n", ret); goto errout; } /* Pick an appropriate packet size for this device * * USB 2.0, Paragraph 5.5.3 "Control Transfer Packet Size Constraints" * * "An endpoint for control transfers specifies the maximum data * payload size that the endpoint can accept from or transmit to * the bus. The allowable maximum control transfer data payload * sizes for full-speed devices is 8, 16, 32, or 64 bytes; for * high-speed devices, it is 64 bytes and for low-speed devices, * it is 8 bytes. This maximum applies to the data payloads of the * Data packets following a Setup..." */ if (hport->speed == USB_SPEED_HIGH) { /* For high-speed, we must use 64 bytes */ maxpacketsize = 64; descsize = USB_SIZEOF_DEVDESC; } else { /* Eight will work for both low- and full-speed */ maxpacketsize = 8; descsize = 8; } /* Configure EP0 with the initial maximum packet size */ DRVR_EP0CONFIGURE(hport->drvr, hport->ep0, 0, hport->speed, maxpacketsize); /* Read first bytes of the device descriptor */ ctrlreq->type = USB_REQ_DIR_IN | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_GETDESCRIPTOR; usbhost_putle16(ctrlreq->value, (USB_DESC_TYPE_DEVICE << 8)); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, descsize); ret = DRVR_CTRLIN(hport->drvr, hport->ep0, ctrlreq, buffer); if (ret < 0) { uerr("ERROR: Failed to get device descriptor, length=%d: %d\n", descsize, ret); goto errout; } /* Extract the correct max packetsize from the device descriptor */ maxpacketsize = ((struct usb_devdesc_s *)buffer)->mxpacketsize; uinfo("maxpacksetsize: %d\n", maxpacketsize); /* And reconfigure EP0 with the correct maximum packet size */ DRVR_EP0CONFIGURE(hport->drvr, hport->ep0, 0, hport->speed, maxpacketsize); /* Now read the full device descriptor (if we have not already done so) */ if (descsize < USB_SIZEOF_DEVDESC) { ctrlreq->type = USB_REQ_DIR_IN | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_GETDESCRIPTOR; usbhost_putle16(ctrlreq->value, (USB_DESC_TYPE_DEVICE << 8)); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, USB_SIZEOF_DEVDESC); ret = DRVR_CTRLIN(hport->drvr, hport->ep0, ctrlreq, buffer); if (ret < 0) { uerr("ERROR: Failed to get device descriptor, length=%d: %d\n", USB_SIZEOF_DEVDESC, ret); goto errout; } } /* Get class identification information from the device descriptor. Most * devices set this to USB_CLASS_PER_INTERFACE (zero) and provide the * identification information in the interface descriptor(s). That allows * a device to support multiple, different classes. */ usbhost_devdesc((struct usb_devdesc_s *)buffer, &id); /* Assign a function address to the device connected to this port */ funcaddr = usbhost_devaddr_create(hport); if (funcaddr < 0) { uerr("ERROR: usbhost_devaddr_create failed: %d\n", ret); goto errout; } /* Set the USB device address */ ctrlreq->type = USB_REQ_DIR_OUT | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_SETADDRESS; usbhost_putle16(ctrlreq->value, (uint16_t)funcaddr); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, 0); ret = DRVR_CTRLOUT(hport->drvr, hport->ep0, ctrlreq, NULL); if (ret < 0) { uerr("ERROR: Failed to set address: %d\n"); goto errout; } nxsig_usleep(2*1000); /* Assign the function address to the port */ DEBUGASSERT(hport->funcaddr == 0 && funcaddr != 0); hport->funcaddr = funcaddr; /* And reconfigure EP0 with the correct address */ DRVR_EP0CONFIGURE(hport->drvr, hport->ep0, hport->funcaddr, hport->speed, maxpacketsize); /* Get the configuration descriptor (only), index == 0. Should not be * hard-coded! More logic is needed in order to handle devices with * multiple configurations. */ ctrlreq->type = USB_REQ_DIR_IN | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_GETDESCRIPTOR; usbhost_putle16(ctrlreq->value, (USB_DESC_TYPE_CONFIG << 8)); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, USB_SIZEOF_CFGDESC); ret = DRVR_CTRLIN(hport->drvr, hport->ep0, ctrlreq, buffer); if (ret < 0) { uerr("ERROR: Failed to get configuration descriptor, length=%d: %d\n", USB_SIZEOF_CFGDESC, ret); goto errout; } /* Extract the full size of the configuration data */ cfglen = (unsigned int)usbhost_getle16(((struct usb_cfgdesc_s *)buffer)->totallen); uinfo("sizeof config data: %d\n", cfglen); if (cfglen > maxlen) { uerr("ERROR: Configuration doesn't fit in buffer, length=%d, maxlen=%d\n", cfglen, maxlen); ret = -E2BIG; goto errout; } /* Get all of the configuration descriptor data, index == 0 (Should not be * hard-coded!) */ ctrlreq->type = USB_REQ_DIR_IN | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_GETDESCRIPTOR; usbhost_putle16(ctrlreq->value, (USB_DESC_TYPE_CONFIG << 8)); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, cfglen); ret = DRVR_CTRLIN(hport->drvr, hport->ep0, ctrlreq, buffer); if (ret < 0) { uerr("ERROR: Failed to get configuration descriptor, length=%d: %d\n", cfglen, ret); goto errout; } /* Select device configuration 1 (Should not be hard-coded!) */ ctrlreq->type = USB_REQ_DIR_OUT | USB_REQ_RECIPIENT_DEVICE; ctrlreq->req = USB_REQ_SETCONFIGURATION; usbhost_putle16(ctrlreq->value, 1); usbhost_putle16(ctrlreq->index, 0); usbhost_putle16(ctrlreq->len, 0); ret = DRVR_CTRLOUT(hport->drvr, hport->ep0, ctrlreq, NULL); if (ret < 0) { uerr("ERROR: Failed to set configuration: %d\n", ret); goto errout; } /* Was the class identification information provided in the device * descriptor? Or do we need to find it in the interface descriptor(s)? */ if (id.base == USB_CLASS_PER_INTERFACE) { /* Get the class identification information for this device from the * interface descriptor(s). Hmmm.. More logic is need to handle the * case of multiple interface descriptors. */ ret = usbhost_configdesc(buffer, cfglen, &id); if (ret < 0) { uerr("ERROR: usbhost_configdesc failed: %d\n", ret); goto errout; } } /* Some devices may require some delay before initialization */ nxsig_usleep(100*1000); #ifdef CONFIG_USBHOST_COMPOSITE /* Check if the device attached to the downstream port if a USB composite * device and, if so, create the composite device wrapper and bind it to * the HCD. * * usbhost_composite() will return a negated errno value is on any * failure. The value -ENOENT, in particular means that the attached * device is not a composite device. Other values would indicate other * various, unexpected failures. We make no real distinction here. */ ret = usbhost_composite(hport, buffer, cfglen, &id, devclass); if (ret >= 0) { uinfo("usbhost_composite has bound the composite device\n"); } /* Apparently this is not a composite device */ else #endif { /* Parse the configuration descriptor and bind to the class instance * for the device. This needs to be the last thing done because the * class driver will begin configuring the device. */ ret = usbhost_classbind(hport, buffer, cfglen, &id, devclass); if (ret < 0) { uerr("ERROR: usbhost_classbind failed %d\n", ret); } } errout: if (ret < 0) { /* Release the device function address on any failure */ usbhost_devaddr_destroy(hport, funcaddr); hport->funcaddr = 0; } /* Release temporary buffers in any event */ if (buffer != NULL) { DRVR_FREE(hport->drvr, buffer); } if (ctrlreq) { DRVR_FREE(hport->drvr, (FAR uint8_t *)ctrlreq); } return ret; }