/*-------------------------------------------------------------------------*/ /*-------------------------------------------------------------------------* * simple generic USB HCD frontend Version 0.9.5 (10/28/2001) * for embedded HCs (SL811HS) * * USB URB handling, hci_ hcs_ * URB queueing, qu_ * Transfer scheduling, sh_ * * *-------------------------------------------------------------------------* * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * *-------------------------------------------------------------------------*/ /* main lock for urb access */ static spinlock_t usb_urb_lock = SPIN_LOCK_UNLOCKED; /*-------------------------------------------------------------------------*/ /*-------------------------------------------------------------------------*/ /* URB HCD API function layer * * * */ /*************************************************************************** * Function Name : hcs_urb_queue * * This function initializes the urb status and length before queueing the * urb. * * Input: hci = data structure for the host controller * urb = USB request block data structure * * Return: 0 **************************************************************************/ static inline int hcs_urb_queue (hci_t * hci, struct urb * urb) { int i; DBGFUNC ("enter hcs_urb_queue\n"); if (usb_pipeisoc (urb->pipe)) { DBGVERBOSE ("hcs_urb_queue: isoc pipe\n"); for (i = 0; i < urb->number_of_packets; i++) { urb->iso_frame_desc[i].actual_length = 0; urb->iso_frame_desc[i].status = -EXDEV; } /* urb->next hack : 1 .. resub, 0 .. single shot */ /* urb->interval = urb->next ? 1 : 0; */ } urb->status = -EINPROGRESS; urb->actual_length = 0; urb->error_count = 0; if (usb_pipecontrol (urb->pipe)) hc_flush_data_cache (hci, urb->setup_packet, 8); if (usb_pipeout (urb->pipe)) hc_flush_data_cache (hci, urb->transfer_buffer, urb->transfer_buffer_length); qu_queue_urb (hci, urb); return 0; } /*************************************************************************** * Function Name : hcs_return_urb * * This function the return path of URB back to the USB core. It calls the * the urb complete function if exist, and also handles the resubmition of * interrupt URBs. * * Input: hci = data structure for the host controller * urb = USB request block data structure * resub_ok = resubmit flag: 1 = submit urb again, 0 = not submit * * Return: 0 **************************************************************************/ static int hcs_return_urb (hci_t * hci, struct urb * urb, int resub_ok) { struct usb_device *dev = urb->dev; int resubmit = 0; DBGFUNC ("enter hcs_return_urb, urb pointer = 0x%x, " "transferbuffer point = 0x%x, " " setup packet pointer = 0x%x, context pointer = 0x%x \n", (__u32 *) urb, (__u32 *) urb->transfer_buffer, (__u32 *) urb->setup_packet, (__u32 *) urb->context); if (urb_debug) urb_print (urb, "RET", usb_pipeout (urb->pipe)); resubmit = urb->interval && resub_ok; urb->dev = urb->hcpriv = NULL; if (urb->complete) { urb->complete (urb); /* call complete */ } if (resubmit) { /* requeue the URB */ urb->dev = dev; hcs_urb_queue (hci, urb); } return 0; } /*************************************************************************** * Function Name : hci_submit_urb * * This function is called by the USB core API when an URB is available to * process. This function does the following * * 1) Check the validity of the URB * 2) Parse the device number from the URB * 3) Pass the URB to the root hub routine if its intended for the hub, else * queue the urb for the attached device. * * Input: urb = USB request block data structure * * Return: 0 if success or error code **************************************************************************/ static int hci_submit_urb (struct urb * urb) { hci_t *hci; unsigned int pipe = urb->pipe; unsigned long flags; int ret; DBGFUNC ("enter hci_submit_urb, pipe = 0x%x\n", urb->pipe); if (!urb->dev || !urb->dev->bus || urb->hcpriv) return -EINVAL; if (usb_endpoint_halted (urb->dev, usb_pipeendpoint (pipe), usb_pipeout (pipe))) { printk ("hci_submit_urb: endpoint_halted\n"); return -EPIPE; } hci = (hci_t *) urb->dev->bus->hcpriv; /* a request to the virtual root hub */ if (usb_pipedevice (pipe) == hci->rh.devnum) { if (urb_debug > 1) urb_print (urb, "SUB-RH", usb_pipein (pipe)); return rh_submit_urb (urb); } /* queue the URB to its endpoint-queue */ spin_lock_irqsave (&usb_urb_lock, flags); ret = hcs_urb_queue (hci, urb); if (ret != 0) { /* error on return */ DBGERR ("hci_submit_urb: return err, ret = 0x%x, urb->status = 0x%x\n", ret, urb->status); } spin_unlock_irqrestore (&usb_urb_lock, flags); return ret; } /*************************************************************************** * Function Name : hci_unlink_urb * * This function mark the URB to unlink * * Input: urb = USB request block data structure * * Return: 0 if success or error code **************************************************************************/ static int hci_unlink_urb (struct urb * urb) { unsigned long flags; hci_t *hci; DECLARE_WAITQUEUE (wait, current); void *comp = NULL; DBGFUNC ("enter hci_unlink_urb\n"); if (!urb) /* just to be sure */ return -EINVAL; if (!urb->dev || !urb->dev->bus) return -ENODEV; hci = (hci_t *) urb->dev->bus->hcpriv; /* a request to the virtual root hub */ if (usb_pipedevice (urb->pipe) == hci->rh.devnum) { return rh_unlink_urb (urb); } if (urb_debug) urb_print (urb, "UNLINK", 1); spin_lock_irqsave (&usb_urb_lock, flags); if (!list_empty (&urb->urb_list) && urb->status == -EINPROGRESS) { /* URB active? */ if (urb-> transfer_flags & (USB_ASYNC_UNLINK | USB_TIMEOUT_KILLED)) { /* asynchron with callback */ list_del (&urb->urb_list); /* relink the urb to the del list */ list_add (&urb->urb_list, &hci->del_list); spin_unlock_irqrestore (&usb_urb_lock, flags); } else { /* synchron without callback */ add_wait_queue (&hci->waitq, &wait); set_current_state (TASK_UNINTERRUPTIBLE); comp = urb->complete; urb->complete = NULL; list_del (&urb->urb_list); /* relink the urb to the del list */ list_add (&urb->urb_list, &hci->del_list); spin_unlock_irqrestore (&usb_urb_lock, flags); schedule_timeout (HZ / 50); if (!list_empty (&urb->urb_list)) list_del (&urb->urb_list); urb->complete = comp; urb->hcpriv = NULL; remove_wait_queue (&hci->waitq, &wait); } } else { /* hcd does not own URB but we keep the driver happy anyway */ spin_unlock_irqrestore (&usb_urb_lock, flags); if (urb->complete && (urb->transfer_flags & USB_ASYNC_UNLINK)) { urb->status = -ENOENT; urb->actual_length = 0; urb->complete (urb); urb->status = 0; } else { urb->status = -ENOENT; } } return 0; } /*************************************************************************** * Function Name : hci_alloc_dev * * This function allocates private data space for the usb device and * initialize the endpoint descriptor heads. * * Input: usb_dev = pointer to the usb device * * Return: 0 if success or error code **************************************************************************/ static int hci_alloc_dev (struct usb_device *usb_dev) { struct hci_device *dev; int i; DBGFUNC ("enter hci_alloc_dev\n"); dev = kmalloc (sizeof (*dev), GFP_KERNEL); if (!dev) return -ENOMEM; memset (dev, 0, sizeof (*dev)); for (i = 0; i < 32; i++) { INIT_LIST_HEAD (&(dev->ed[i].urb_queue)); dev->ed[i].pipe_head = NULL; } usb_dev->hcpriv = dev; DBGVERBOSE ("USB HC dev alloc %d bytes\n", sizeof (*dev)); return 0; } /*************************************************************************** * Function Name : hci_free_dev * * This function de-allocates private data space for the usb devic * * Input: usb_dev = pointer to the usb device * * Return: 0 **************************************************************************/ static int hci_free_dev (struct usb_device *usb_dev) { DBGFUNC ("enter hci_free_dev\n"); if (usb_dev->hcpriv) kfree (usb_dev->hcpriv); usb_dev->hcpriv = NULL; return 0; } /*************************************************************************** * Function Name : hci_get_current_frame_number * * This function get the current USB frame number * * Input: usb_dev = pointer to the usb device * * Return: frame number **************************************************************************/ static int hci_get_current_frame_number (struct usb_device *usb_dev) { hci_t *hci = usb_dev->bus->hcpriv; DBGFUNC ("enter hci_get_current_frame_number, frame = 0x%x \r\n", hci->frame_number); return (hci->frame_number); } /*************************************************************************** * List of all io-functions **************************************************************************/ static struct usb_operations hci_device_operations = { allocate: hci_alloc_dev, deallocate: hci_free_dev, get_frame_number: hci_get_current_frame_number, submit_urb: hci_submit_urb, unlink_urb: hci_unlink_urb, }; /*************************************************************************** * URB queueing: * * For each type of transfer (INTR, BULK, ISO, CTRL) there is a list of * active URBs. * (hci->intr_list, hci->bulk_list, hci->iso_list, hci->ctrl_list) * For every endpoint the head URB of the queued URBs is linked to one of * those lists. * * The rest of the queued URBs of an endpoint are linked into a * private URB list for each endpoint. (hci_dev->ed [endpoint_io].urb_queue) * hci_dev->ed [endpoint_io].pipe_head .. points to the head URB which is * in one of the active URB lists. * * The index of an endpoint consists of its number and its direction. * * The state of an intr and iso URB is 0. * For ctrl URBs the states are US_CTRL_SETUP, US_CTRL_DATA, US_CTRL_ACK * Bulk URBs states are US_BULK and US_BULK0 (with 0-len packet) * **************************************************************************/ /*************************************************************************** * Function Name : qu_urb_timeout * * This function is called when the URB timeout. The function unlinks the * URB. * * Input: lurb: URB * * Return: none **************************************************************************/ #ifdef HC_URB_TIMEOUT static void qu_urb_timeout (unsigned long lurb) { struct urb *urb = (struct urb *) lurb; DBGFUNC ("enter qu_urb_timeout\n"); urb->transfer_flags |= USB_TIMEOUT_KILLED; hci_unlink_urb (urb); } #endif /*************************************************************************** * Function Name : qu_pipeindex * * This function gets the index of the pipe. * * Input: pipe: the urb pipe * * Return: index **************************************************************************/ static inline int qu_pipeindex (__u32 pipe) { DBGFUNC ("enter qu_pipeindex\n"); return (usb_pipeendpoint (pipe) << 1) | (usb_pipecontrol (pipe) ? 0 : usb_pipeout (pipe)); } /*************************************************************************** * Function Name : qu_seturbstate * * This function set the state of the URB. * * control pipe: 3 states -- Setup, data, status * interrupt and bulk pipe: 1 state -- data * * Input: urb = USB request block data structure * state = the urb state * * Return: none **************************************************************************/ static inline void qu_seturbstate (struct urb * urb, int state) { DBGFUNC ("enter qu_seturbstate\n"); urb->pipe &= ~0x1f; urb->pipe |= state & 0x1f; } /*************************************************************************** * Function Name : qu_urbstate * * This function get the current state of the URB. * * Input: urb = USB request block data structure * * Return: none **************************************************************************/ static inline int qu_urbstate (struct urb * urb) { DBGFUNC ("enter qu_urbstate\n"); return urb->pipe & 0x1f; } /*************************************************************************** * Function Name : qu_queue_active_urb * * This function adds the urb to the appropriate active urb list and set * the urb state. * * There are four active lists: isochoronous list, interrupt list, * control list, and bulk list. * * Input: hci = data structure for the host controller * urb = USB request block data structure * ed = endpoint descriptor * * Return: none **************************************************************************/ static inline void qu_queue_active_urb (hci_t * hci, struct urb * urb, epd_t * ed) { int urb_state = 0; DBGFUNC ("enter qu_queue_active_urb\n"); switch (usb_pipetype (urb->pipe)) { case PIPE_CONTROL: list_add (&urb->urb_list, &hci->ctrl_list); urb_state = US_CTRL_SETUP; break; case PIPE_BULK: list_add (&urb->urb_list, &hci->bulk_list); if ((urb->transfer_flags & USB_ZERO_PACKET) && urb->transfer_buffer_length > 0 && ((urb->transfer_buffer_length % usb_maxpacket (urb->dev, urb->pipe, usb_pipeout (urb->pipe))) == 0)) { urb_state = US_BULK0; } break; case PIPE_INTERRUPT: urb->start_frame = hci->frame_number; list_add (&urb->urb_list, &hci->intr_list); break; case PIPE_ISOCHRONOUS: list_add (&urb->urb_list, &hci->iso_list); break; } #ifdef HC_URB_TIMEOUT if (urb->timeout) { ed->timeout.data = (unsigned long) urb; ed->timeout.expires = urb->timeout + jiffies; ed->timeout.function = qu_urb_timeout; add_timer (&ed->timeout); } #endif qu_seturbstate (urb, urb_state); } /*************************************************************************** * Function Name : qu_queue_urb * * This function adds the urb to the endpoint descriptor list * * Input: hci = data structure for the host controller * urb = USB request block data structure * * Return: none **************************************************************************/ static int qu_queue_urb (hci_t * hci, struct urb * urb) { struct hci_device *hci_dev = usb_to_hci (urb->dev); epd_t *ed = &hci_dev->ed[qu_pipeindex (urb->pipe)]; DBGFUNC ("Enter qu_queue_urb\n"); /* for ISOC transfers calculate start frame index */ if (usb_pipeisoc (urb->pipe) && urb->transfer_flags & USB_ISO_ASAP) { urb->start_frame = ((ed->pipe_head) ? (ed->last_iso + 1) : hci_get_current_frame_number (urb-> dev) + 1) & 0xffff; } if (ed->pipe_head) { __list_add (&urb->urb_list, ed->urb_queue.prev, &(ed->urb_queue)); } else { ed->pipe_head = urb; qu_queue_active_urb (hci, urb, ed); if (++hci->active_urbs == 1) hc_start_int (hci); } return 0; } /*************************************************************************** * Function Name : qu_next_urb * * This function removes the URB from the queue and add the next URB to * active list. * * Input: hci = data structure for the host controller * urb = USB request block data structure * resub_ok = resubmit flag * * Return: pointer to the next urb **************************************************************************/ static struct urb *qu_next_urb (hci_t * hci, struct urb * urb, int resub_ok) { struct hci_device *hci_dev = usb_to_hci (urb->dev); epd_t *ed = &hci_dev->ed[qu_pipeindex (urb->pipe)]; DBGFUNC ("enter qu_next_urb\n"); list_del (&urb->urb_list); INIT_LIST_HEAD (&urb->urb_list); if (ed->pipe_head == urb) { #ifdef HC_URB_TIMEOUT if (urb->timeout) del_timer (&ed->timeout); #endif if (!--hci->active_urbs) hc_stop_int (hci); if (!list_empty (&ed->urb_queue)) { urb = list_entry (ed->urb_queue.next, struct urb, urb_list); list_del (&urb->urb_list); INIT_LIST_HEAD (&urb->urb_list); ed->pipe_head = urb; qu_queue_active_urb (hci, urb, ed); } else { ed->pipe_head = NULL; urb = NULL; } } return urb; } /*************************************************************************** * Function Name : qu_return_urb * * This function is part of the return path. * * Input: hci = data structure for the host controller * urb = USB request block data structure * resub_ok = resubmit flag * * Return: pointer to the next urb **************************************************************************/ static struct urb *qu_return_urb (hci_t * hci, struct urb * urb, int resub_ok) { struct urb *next_urb; DBGFUNC ("enter qu_return_rub\n"); next_urb = qu_next_urb (hci, urb, resub_ok); hcs_return_urb (hci, urb, resub_ok); return next_urb; } /*************************************************************************** * Function Name : sh_scan_iso_urb_list * * This function goes throught the isochronous urb list and schedule the * the transfer. * * Note: This function has not tested yet * * Input: hci = data structure for the host controller * list_lh = pointer to the isochronous list * frame_number = the frame number * * Return: 0 = unsuccessful; 1 = successful **************************************************************************/ static int sh_scan_iso_urb_list (hci_t * hci, struct list_head *list_lh, int frame_number) { struct list_head *lh = list_lh->next; struct urb *urb; DBGFUNC ("enter sh_scan_iso_urb_list\n"); hci->td_array->len = 0; while (lh != list_lh) { urb = list_entry (lh, struct urb, urb_list); lh = lh->next; if (((frame_number - urb->start_frame) & 0x7ff) < urb->number_of_packets) { if (!sh_add_packet (hci, urb)) { return 0; } else { if (((frame_number - urb->start_frame) & 0x7ff) > 0x400) { if (qu_urbstate (urb) > 0) urb = qu_return_urb (hci, urb, 1); else urb = qu_next_urb (hci, urb, 1); if (lh == list_lh && urb) lh = &urb->urb_list; } } } } return 1; } /*************************************************************************** * Function Name : sh_scan_urb_list * * This function goes through the urb list and schedule the * the transaction. * * Input: hci = data structure for the host controller * list_lh = pointer to the isochronous list * * Return: 0 = unsuccessful; 1 = successful **************************************************************************/ static int sh_scan_urb_list (hci_t * hci, struct list_head *list_lh) { struct list_head *lh = NULL; struct urb *urb; if (list_lh == NULL) { DBGERR ("sh_scan_urb_list: error, list_lh == NULL\n"); } DBGFUNC ("enter sh_scan_urb_list: frame# \n"); list_for_each (lh, list_lh) { urb = list_entry (lh, struct urb, urb_list); if (urb == NULL) return 1; if (!usb_pipeint (urb->pipe) || (((hci->frame_number - urb->start_frame) & 0x7ff) >= urb->interval)) { DBGVERBOSE ("sh_scan_urb_list !INT: %d fr_no: %d int: %d pint: %d\n", urb->start_frame, hci->frame_number, urb->interval, usb_pipeint (urb->pipe)); if (!sh_add_packet (hci, urb)) { return 0; } else { DBGVERBOSE ("INT: start: %d fr_no: %d int: %d pint: %d\n", urb->start_frame, hci->frame_number, urb->interval, usb_pipeint (urb->pipe)); urb->start_frame = hci->frame_number; return 0; } } } return 1; } /*************************************************************************** * Function Name : sh_shedule_trans * * This function schedule the USB transaction. * This function will process the endpoint in the following order: * interrupt, control, and bulk. * * Input: hci = data structure for the host controller * isSOF = flag indicate if Start Of Frame has occurred * * Return: 0 **************************************************************************/ static int sh_schedule_trans (hci_t * hci, int isSOF) { int units_left = 1; struct list_head *lh; if (hci == NULL) { DBGERR ("sh_schedule_trans: hci == NULL\n"); return 0; } if (hci->td_array == NULL) { DBGERR ("sh_schedule_trans: hci->td_array == NULL\n"); return 0; } if (hci->td_array->len != 0) { DBGERR ("ERROR: schedule, hci->td_array->len = 0x%x, s/b: 0\n", hci->td_array->len); } /* schedule the next available interrupt transfer or the next * stage of the interrupt transfer */ if (hci->td_array->len == 0 && !list_empty (&hci->intr_list)) { units_left = sh_scan_urb_list (hci, &hci->intr_list); } /* schedule the next available control transfer or the next * stage of the control transfer */ if (hci->td_array->len == 0 && !list_empty (&hci->ctrl_list) && units_left > 0) { units_left = sh_scan_urb_list (hci, &hci->ctrl_list); } /* schedule the next available bulk transfer or the next * stage of the bulk transfer */ if (hci->td_array->len == 0 && !list_empty (&hci->bulk_list) && units_left > 0) { sh_scan_urb_list (hci, &hci->bulk_list); /* be fair to each BULK URB (move list head around) * only when the new SOF happens */ lh = hci->bulk_list.next; list_del (&hci->bulk_list); list_add (&hci->bulk_list, lh); } return 0; } /*************************************************************************** * Function Name : sh_add_packet * * This function forms the packet and transmit the packet. This function * will handle all endpoint type: isochoronus, interrupt, control, and * bulk. * * Input: hci = data structure for the host controller * urb = USB request block data structure * * Return: 0 = unsucessful; 1 = successful **************************************************************************/ static int sh_add_packet (hci_t * hci, struct urb * urb) { __u8 *data = NULL; int len = 0; int toggle = 0; int maxps = usb_maxpacket (urb->dev, urb->pipe, usb_pipeout (urb->pipe)); int endpoint = usb_pipeendpoint (urb->pipe); int address = usb_pipedevice (urb->pipe); int slow = (((urb->pipe) >> 26) & 1); int out = usb_pipeout (urb->pipe); int pid = 0; int ret; int i = 0; int iso = 0; DBGFUNC ("enter sh_add_packet\n"); if (maxps == 0) maxps = 8; /* calculate len, toggle bit and add the transaction */ switch (usb_pipetype (urb->pipe)) { case PIPE_ISOCHRONOUS: pid = out ? PID_OUT : PID_IN; iso = 1; i = hci->frame_number - urb->start_frame; data = urb->transfer_buffer + urb->iso_frame_desc[i].offset; len = urb->iso_frame_desc[i].length; break; case PIPE_BULK: /* BULK and BULK0 */ case PIPE_INTERRUPT: pid = out ? PID_OUT : PID_IN; len = urb->transfer_buffer_length - urb->actual_length; data = urb->transfer_buffer + urb->actual_length; toggle = usb_gettoggle (urb->dev, endpoint, out); break; case PIPE_CONTROL: switch (qu_urbstate (urb)) { case US_CTRL_SETUP: len = 8; pid = PID_SETUP; data = urb->setup_packet; toggle = 0; break; case US_CTRL_DATA: if (!hci->last_packet_nak) { /* The last packet received is not a nak: * reset the nak count */ hci->nakCnt = 0; } if (urb->transfer_buffer_length != 0) { pid = out ? PID_OUT : PID_IN; len = urb->transfer_buffer_length - urb->actual_length; data = urb->transfer_buffer + urb->actual_length; toggle = (urb->actual_length & maxps) ? 0 : 1; usb_settoggle (urb->dev, usb_pipeendpoint (urb->pipe), usb_pipeout (urb->pipe), toggle); break; } else { /* correct state and fall through */ qu_seturbstate (urb, US_CTRL_ACK); } case US_CTRL_ACK: len = 0; /* reply in opposite direction */ pid = !out ? PID_OUT : PID_IN; toggle = 1; usb_settoggle (urb->dev, usb_pipeendpoint (urb->pipe), usb_pipeout (urb->pipe), toggle); break; } } ret = hc_add_trans (hci, len, data, toggle, maxps, slow, endpoint, address, pid, iso, qu_urbstate (urb)); DBGVERBOSE ("transfer_pa: addr:%d ep:%d pid:%x tog:%x iso:%x sl:%x " "max:%d\n len:%d ret:%d data:%p left:%d\n", address, endpoint, pid, toggle, iso, slow, maxps, len, ret, data, hci->hp.units_left); if (ret >= 0) { hci->td_array->td[hci->td_array->len].urb = urb; hci->td_array->td[hci->td_array->len].len = ret; hci->td_array->td[hci->td_array->len].iso_index = i; hci->td_array->len++; hci->active_trans = 1; return 1; } return 0; } /*************************************************************************** * Function Name : cc_to_error * * This function maps the SL811HS hardware error code to the linux USB error * code. * * Input: cc = hardware error code * * Return: USB error code **************************************************************************/ static int cc_to_error (int cc) { int errCode = 0; if (cc & SL11H_STATMASK_ERROR) { errCode |= -EILSEQ; } else if (cc & SL11H_STATMASK_OVF) { errCode |= -EOVERFLOW; } else if (cc & SL11H_STATMASK_STALL) { errCode |= -EPIPE; } return errCode; } /*************************************************************************** * Function Name : sh_done_list * * This function process the packet when it has done finish transfer. * * 1) It handles hardware error * 2) It updates the URB state * 3) If the USB transaction is complete, it start the return stack path. * * Input: hci = data structure for the host controller * isExcessNak = flag tells if there excess NAK condition occurred * * Return: urb_state or -1 if the transaction has complete **************************************************************************/ static int sh_done_list (hci_t * hci, int *isExcessNak) { int actbytes = 0; int active = 0; void *data = NULL; int cc; int maxps; int toggle; struct urb *urb; int urb_state = 0; int ret = 1; /* -1 parse abbort, 1 parse ok, 0 last element */ int trans = 0; int len; int iso_index = 0; int out; int pid = 0; int debugLen = 0; *isExcessNak = 0; DBGFUNC ("enter sh_done_list: td_array->len = 0x%x\n", hci->td_array->len); debugLen = hci->td_array->len; if (debugLen > 1) DBGERR ("sh_done_list: td_array->len = 0x%x > 1\n", hci->td_array->len); for (trans = 0; ret && trans < hci->td_array->len && trans < MAX_TRANS; trans++) { urb = hci->td_array->td[trans].urb; len = hci->td_array->td[trans].len; out = usb_pipeout (urb->pipe); if (usb_pipeisoc (urb->pipe)) { iso_index = hci->td_array->td[trans].iso_index; data = urb->transfer_buffer + urb->iso_frame_desc[iso_index].offset; toggle = 0; } else { data = urb->transfer_buffer + urb->actual_length; toggle = usb_gettoggle (urb->dev, usb_pipeendpoint (urb->pipe), usb_pipeout (urb->pipe)); } urb_state = qu_urbstate (urb); pid = out ? PID_OUT : PID_IN; ret = hc_parse_trans (hci, &actbytes, data, &cc, &toggle, len, pid, urb_state); maxps = usb_maxpacket (urb->dev, urb->pipe, usb_pipeout (urb->pipe)); if (maxps == 0) maxps = 8; active = (urb_state != US_CTRL_SETUP) && (actbytes && !(actbytes & (maxps - 1))); /* If the transfer is not bulk in, then it is necessary to get all * data specify by the urb->transfer_len. */ if (!(usb_pipebulk (urb->pipe) && usb_pipein (urb->pipe))) active = active && (urb->transfer_buffer_length != urb->actual_length + actbytes); if (urb->transfer_buffer_length == urb->actual_length + actbytes) active = 0; if ((cc & (SL11H_STATMASK_ERROR | SL11H_STATMASK_TMOUT | SL11H_STATMASK_OVF | SL11H_STATMASK_STALL)) && !(cc & SL11H_STATMASK_NAK)) { if (++urb->error_count > 3) { DBGERR ("done_list: excessive error: errcount = 0x%x, cc = 0x%x\n", urb->error_count, cc); urb_state = 0; active = 0; } else { DBGERR ("done_list: packet err, cc = 0x%x, " " urb->length = 0x%x, actual_len = 0x%x," " urb_state =0x%x\n", cc, urb->transfer_buffer_length, urb->actual_length, urb_state); // if (cc & SL11H_STATMASK_STALL) { /* The USB function is STALLED on a control pipe (0), * then it needs to send the SETUP command again to * clear the STALL condition */ // if (usb_pipeendpoint (urb->pipe) == 0) { // urb_state = 2; // active = 0; // } // } else active = 1; } } else { if (cc & SL11H_STATMASK_NAK) { if (hci->nakCnt < 0x10000) { hci->nakCnt++; hci->last_packet_nak = 1; active = 1; *isExcessNak = 0; } else { DBGERR ("done_list: nak count exceed limit\n"); active = 0; *isExcessNak = 1; hci->nakCnt = 0; } } else { hci->nakCnt = 0; hci->last_packet_nak = 0; } if (urb_state != US_CTRL_SETUP) { /* no error */ urb->actual_length += actbytes; usb_settoggle (urb->dev, usb_pipeendpoint (urb->pipe), usb_pipeout (urb->pipe), toggle); } if (usb_pipeisoc (urb->pipe)) { urb->iso_frame_desc[iso_index].actual_length = actbytes; urb->iso_frame_desc[iso_index].status = cc_to_error (cc); active = (iso_index < urb->number_of_packets); } } if (!active) { if (!urb_state) { urb->status = cc_to_error (cc); if (urb->status) { DBGERR ("error on received packet: urb->status = 0x%x\n", urb->status); } hci->td_array->len = 0; qu_return_urb (hci, urb, 1); return -1; } else { /* We do not want to decrement the urb_state if exceeded nak, * because we need to finish the data stage of the control * packet */ if (!(*isExcessNak)) urb_state--; qu_seturbstate (urb, urb_state); } } } if (urb_state < 0) DBGERR ("ERROR: done_list, urb_state = %d, suppose > 0\n", urb_state); if (debugLen != hci->td_array->len) { DBGERR ("ERROR: done_list, debugLen!= td_array->len," "debugLen = 0x%x, hci->td_array->len = 0x%x\n", debugLen, hci->td_array->len); } hci->td_array->len = 0; return urb_state; }