// Main code for handling USB controllers and devices. // // Copyright (C) 2009-2013 Kevin O'Connor // // This file may be distributed under the terms of the GNU LGPLv3 license. #include "biosvar.h" // GET_GLOBAL #include "config.h" // CONFIG_* #include "malloc.h" // free #include "output.h" // dprintf #include "string.h" // memset #include "usb.h" // struct usb_s #include "usb-ehci.h" // ehci_setup #include "usb-xhci.h" // xhci_setup #include "usb-hid.h" // usb_keyboard_setup #include "usb-hub.h" // usb_hub_setup #include "usb-msc.h" // usb_msc_setup #include "usb-ohci.h" // ohci_setup #include "usb-uas.h" // usb_uas_setup #include "usb-uhci.h" // uhci_setup #include "util.h" // msleep #include "x86.h" // __fls /**************************************************************** * Controller function wrappers ****************************************************************/ // Allocate, update, or free a usb pipe. static struct usb_pipe * usb_realloc_pipe(struct usbdevice_s *usbdev, struct usb_pipe *pipe , struct usb_endpoint_descriptor *epdesc) { switch (usbdev->hub->cntl->type) { default: case USB_TYPE_UHCI: return uhci_realloc_pipe(usbdev, pipe, epdesc); case USB_TYPE_OHCI: return ohci_realloc_pipe(usbdev, pipe, epdesc); case USB_TYPE_EHCI: return ehci_realloc_pipe(usbdev, pipe, epdesc); case USB_TYPE_XHCI: return xhci_realloc_pipe(usbdev, pipe, epdesc); } } // Send a message on a control pipe using the default control descriptor. static int usb_send_pipe(struct usb_pipe *pipe_fl, int dir, const void *cmd , void *data, int datasize) { switch (GET_LOWFLAT(pipe_fl->type)) { default: case USB_TYPE_UHCI: return uhci_send_pipe(pipe_fl, dir, cmd, data, datasize); case USB_TYPE_OHCI: if (MODESEGMENT) return -1; return ohci_send_pipe(pipe_fl, dir, cmd, data, datasize); case USB_TYPE_EHCI: return ehci_send_pipe(pipe_fl, dir, cmd, data, datasize); case USB_TYPE_XHCI: if (MODESEGMENT) return -1; return xhci_send_pipe(pipe_fl, dir, cmd, data, datasize); } } int usb_poll_intr(struct usb_pipe *pipe_fl, void *data) { ASSERT16(); switch (GET_LOWFLAT(pipe_fl->type)) { default: case USB_TYPE_UHCI: return uhci_poll_intr(pipe_fl, data); case USB_TYPE_OHCI: return ohci_poll_intr(pipe_fl, data); case USB_TYPE_EHCI: return ehci_poll_intr(pipe_fl, data); case USB_TYPE_XHCI: ; return call32_params(xhci_poll_intr, pipe_fl , MAKE_FLATPTR(GET_SEG(SS), data), 0, -1); } } int usb_32bit_pipe(struct usb_pipe *pipe_fl) { return (CONFIG_USB_XHCI && GET_LOWFLAT(pipe_fl->type) == USB_TYPE_XHCI) || (CONFIG_USB_OHCI && GET_LOWFLAT(pipe_fl->type) == USB_TYPE_OHCI); } /**************************************************************** * Helper functions ****************************************************************/ // Allocate a usb pipe. struct usb_pipe * usb_alloc_pipe(struct usbdevice_s *usbdev , struct usb_endpoint_descriptor *epdesc) { return usb_realloc_pipe(usbdev, NULL, epdesc); } // Free an allocated control or bulk pipe. void usb_free_pipe(struct usbdevice_s *usbdev, struct usb_pipe *pipe) { if (!pipe) return; usb_realloc_pipe(usbdev, pipe, NULL); } // Send a message to the default control pipe of a device. int usb_send_default_control(struct usb_pipe *pipe, const struct usb_ctrlrequest *req , void *data) { return usb_send_pipe(pipe, req->bRequestType & USB_DIR_IN, req , data, req->wLength); } // Send a message to a bulk endpoint int usb_send_bulk(struct usb_pipe *pipe_fl, int dir, void *data, int datasize) { return usb_send_pipe(pipe_fl, dir, NULL, data, datasize); } // Check if a pipe for a given controller is on the freelist int usb_is_freelist(struct usb_s *cntl, struct usb_pipe *pipe) { return pipe->cntl != cntl; } // Add a pipe to the controller's freelist void usb_add_freelist(struct usb_pipe *pipe) { if (!pipe) return; struct usb_s *cntl = pipe->cntl; pipe->freenext = cntl->freelist; cntl->freelist = pipe; } // Check for an available pipe on the freelist. struct usb_pipe * usb_get_freelist(struct usb_s *cntl, u8 eptype) { struct usb_pipe **pfree = &cntl->freelist; for (;;) { struct usb_pipe *pipe = *pfree; if (!pipe) return NULL; if (pipe->eptype == eptype) { *pfree = pipe->freenext; return pipe; } pfree = &pipe->freenext; } } // Fill "pipe" endpoint info from an endpoint descriptor. void usb_desc2pipe(struct usb_pipe *pipe, struct usbdevice_s *usbdev , struct usb_endpoint_descriptor *epdesc) { pipe->cntl = usbdev->hub->cntl; pipe->type = usbdev->hub->cntl->type; pipe->ep = epdesc->bEndpointAddress & USB_ENDPOINT_NUMBER_MASK; pipe->devaddr = usbdev->devaddr; pipe->speed = usbdev->speed; pipe->maxpacket = epdesc->wMaxPacketSize; pipe->eptype = epdesc->bmAttributes & USB_ENDPOINT_XFERTYPE_MASK; } // Find the exponential period of the requested interrupt end point. int usb_get_period(struct usbdevice_s *usbdev , struct usb_endpoint_descriptor *epdesc) { int period = epdesc->bInterval; if (usbdev->speed != USB_HIGHSPEED) return (period <= 0) ? 0 : __fls(period); return (period <= 4) ? 0 : period - 4; } // Maximum time (in ms) a data transfer should take int usb_xfer_time(struct usb_pipe *pipe, int datalen) { // Use the maximum command time (5 seconds), except for // set_address commands where we don't want to stall the boot if // the device doesn't actually exist. Add 100ms to account for // any controller delays. if (!GET_LOWFLAT(pipe->devaddr)) return USB_TIME_STATUS + 100; return USB_TIME_COMMAND + 100; } // Find the first endpoint of a given type in an interface description. struct usb_endpoint_descriptor * usb_find_desc(struct usbdevice_s *usbdev, int type, int dir) { struct usb_endpoint_descriptor *epdesc = (void*)&usbdev->iface[1]; for (;;) { if ((void*)epdesc >= (void*)usbdev->iface + usbdev->imax || epdesc->bDescriptorType == USB_DT_INTERFACE) { return NULL; } if (epdesc->bDescriptorType == USB_DT_ENDPOINT && (epdesc->bEndpointAddress & USB_ENDPOINT_DIR_MASK) == dir && (epdesc->bmAttributes & USB_ENDPOINT_XFERTYPE_MASK) == type) return epdesc; epdesc = (void*)epdesc + epdesc->bLength; } } // Get the first 8 bytes of the device descriptor. static int get_device_info8(struct usb_pipe *pipe, struct usb_device_descriptor *dinfo) { struct usb_ctrlrequest req; req.bRequestType = USB_DIR_IN | USB_TYPE_STANDARD | USB_RECIP_DEVICE; req.bRequest = USB_REQ_GET_DESCRIPTOR; req.wValue = USB_DT_DEVICE<<8; req.wIndex = 0; req.wLength = 8; return usb_send_default_control(pipe, &req, dinfo); } static struct usb_config_descriptor * get_device_config(struct usb_pipe *pipe) { struct usb_config_descriptor cfg; struct usb_ctrlrequest req; req.bRequestType = USB_DIR_IN | USB_TYPE_STANDARD | USB_RECIP_DEVICE; req.bRequest = USB_REQ_GET_DESCRIPTOR; req.wValue = USB_DT_CONFIG<<8; req.wIndex = 0; req.wLength = sizeof(cfg); int ret = usb_send_default_control(pipe, &req, &cfg); if (ret) return NULL; void *config = malloc_tmphigh(cfg.wTotalLength); if (!config) { warn_noalloc(); return NULL; } req.wLength = cfg.wTotalLength; ret = usb_send_default_control(pipe, &req, config); if (ret) { free(config); return NULL; } //hexdump(config, cfg.wTotalLength); return config; } static int set_configuration(struct usb_pipe *pipe, u16 val) { struct usb_ctrlrequest req; req.bRequestType = USB_DIR_OUT | USB_TYPE_STANDARD | USB_RECIP_DEVICE; req.bRequest = USB_REQ_SET_CONFIGURATION; req.wValue = val; req.wIndex = 0; req.wLength = 0; return usb_send_default_control(pipe, &req, NULL); } /**************************************************************** * Initialization and enumeration ****************************************************************/ static const int speed_to_ctlsize[] = { [ USB_FULLSPEED ] = 8, [ USB_LOWSPEED ] = 8, [ USB_HIGHSPEED ] = 64, [ USB_SUPERSPEED ] = 512, }; // Assign an address to a device in the default state on the given // controller. static int usb_set_address(struct usbdevice_s *usbdev) { ASSERT32FLAT(); struct usb_s *cntl = usbdev->hub->cntl; dprintf(3, "set_address %p\n", cntl); if (cntl->maxaddr >= USB_MAXADDR) return -1; msleep(USB_TIME_RSTRCY); // Create a pipe for the default address. struct usb_endpoint_descriptor epdesc = { .wMaxPacketSize = speed_to_ctlsize[usbdev->speed], .bmAttributes = USB_ENDPOINT_XFER_CONTROL, }; usbdev->defpipe = usb_alloc_pipe(usbdev, &epdesc); if (!usbdev->defpipe) return -1; // Send set_address command. struct usb_ctrlrequest req; req.bRequestType = USB_DIR_OUT | USB_TYPE_STANDARD | USB_RECIP_DEVICE; req.bRequest = USB_REQ_SET_ADDRESS; req.wValue = cntl->maxaddr + 1; req.wIndex = 0; req.wLength = 0; int ret = usb_send_default_control(usbdev->defpipe, &req, NULL); if (ret) { usb_free_pipe(usbdev, usbdev->defpipe); return -1; } msleep(USB_TIME_SETADDR_RECOVERY); cntl->maxaddr++; usbdev->devaddr = cntl->maxaddr; usbdev->defpipe = usb_realloc_pipe(usbdev, usbdev->defpipe, &epdesc); if (!usbdev->defpipe) return -1; return 0; } // Called for every found device - see if a driver is available for // this device and do setup if so. static int configure_usb_device(struct usbdevice_s *usbdev) { ASSERT32FLAT(); dprintf(3, "config_usb: %p\n", usbdev->defpipe); // Set the max packet size for endpoint 0 of this device. struct usb_device_descriptor dinfo; int ret = get_device_info8(usbdev->defpipe, &dinfo); if (ret) return 0; u16 maxpacket = dinfo.bMaxPacketSize0; if (dinfo.bcdUSB >= 0x0300) maxpacket = 1 << dinfo.bMaxPacketSize0; dprintf(3, "device rev=%04x cls=%02x sub=%02x proto=%02x size=%d\n" , dinfo.bcdUSB, dinfo.bDeviceClass, dinfo.bDeviceSubClass , dinfo.bDeviceProtocol, maxpacket); if (maxpacket < 8) return 0; struct usb_endpoint_descriptor epdesc = { .wMaxPacketSize = maxpacket, .bmAttributes = USB_ENDPOINT_XFER_CONTROL, }; usbdev->defpipe = usb_realloc_pipe(usbdev, usbdev->defpipe, &epdesc); if (!usbdev->defpipe) return -1; // Get configuration struct usb_config_descriptor *config = get_device_config(usbdev->defpipe); if (!config) return 0; // Determine if a driver exists for this device - only look at the // first interface of the first configuration. struct usb_interface_descriptor *iface = (void*)(&config[1]); if (iface->bInterfaceClass != USB_CLASS_HID && iface->bInterfaceClass != USB_CLASS_MASS_STORAGE && iface->bInterfaceClass != USB_CLASS_HUB) // Not a supported device. goto fail; // Set the configuration. ret = set_configuration(usbdev->defpipe, config->bConfigurationValue); if (ret) goto fail; // Configure driver. usbdev->config = config; usbdev->iface = iface; usbdev->imax = (void*)config + config->wTotalLength - (void*)iface; if (iface->bInterfaceClass == USB_CLASS_HUB) ret = usb_hub_setup(usbdev); else if (iface->bInterfaceClass == USB_CLASS_MASS_STORAGE) { if (iface->bInterfaceProtocol == US_PR_BULK) ret = usb_msc_setup(usbdev); if (iface->bInterfaceProtocol == US_PR_UAS) ret = usb_uas_setup(usbdev); } else ret = usb_hid_setup(usbdev); if (ret) goto fail; free(config); return 1; fail: free(config); return 0; } static void usb_hub_port_setup(void *data) { struct usbdevice_s *usbdev = data; struct usbhub_s *hub = usbdev->hub; u32 port = usbdev->port; for (;;) { // Detect if device present (and possibly start reset) int ret = hub->op->detect(hub, port); if (ret > 0) // Device connected. break; if (ret < 0 || timer_check(hub->detectend)) // No device found. goto done; msleep(5); } // XXX - wait USB_TIME_ATTDB time? // Reset port and determine device speed mutex_lock(&hub->cntl->resetlock); int ret = hub->op->reset(hub, port); if (ret < 0) // Reset failed goto resetfail; usbdev->speed = ret; // Set address of port ret = usb_set_address(usbdev); if (ret) { hub->op->disconnect(hub, port); goto resetfail; } mutex_unlock(&hub->cntl->resetlock); // Configure the device int count = configure_usb_device(usbdev); usb_free_pipe(usbdev, usbdev->defpipe); if (!count) hub->op->disconnect(hub, port); hub->devcount += count; done: hub->threads--; free(usbdev); return; resetfail: mutex_unlock(&hub->cntl->resetlock); goto done; } void usb_enumerate(struct usbhub_s *hub) { u32 portcount = hub->portcount; hub->threads = portcount; hub->detectend = timer_calc(USB_TIME_SIGATT); // Launch a thread for every port. int i; for (i=0; ihub = hub; usbdev->port = i; run_thread(usb_hub_port_setup, usbdev); } // Wait for threads to complete. while (hub->threads) yield(); } void __usb_setup(void *data) { dprintf(3, "init usb\n"); xhci_setup(); ehci_setup(); uhci_setup(); ohci_setup(); } void usb_setup(void) { ASSERT32FLAT(); if (! CONFIG_USB) return; run_thread(__usb_setup, NULL); }