VOID
compdev_set_cfg_completion(PURB purb, PVOID context)
{
DEV_HANDLE dev_handle;
PUSB_DEV_MANAGER dev_mgr;
PUSB_DRIVER pdriver;
NTSTATUS status;
PUSB_DEV pdev;
USE_BASIC_NON_PENDING_IRQL;
if (purb == NULL || context == NULL)
return;
dev_handle = purb->endp_handle & ~0xffff;
dev_mgr = (PUSB_DEV_MANAGER) context;
pdriver = (PUSB_DRIVER) purb->reference;
if (purb->status != STATUS_SUCCESS)
{
usb_free_mem(purb);
return;
}
usb_free_mem(purb);
purb = NULL;
// set the dev state
status = usb_query_and_lock_dev(dev_mgr, dev_handle, &pdev);
if (status != STATUS_SUCCESS)
{
usb_unlock_dev(pdev);
return;
}
// safe to release the pdev ref since we are in urb completion
usb_unlock_dev(pdev);
lock_dev(pdev, TRUE);
if (dev_state(pdev) >= USB_DEV_STATE_BEFORE_ZOMB)
{
unlock_dev(pdev, TRUE);
return;
}
if (dev_mgr_set_driver(dev_mgr, dev_handle, pdriver, pdev) == FALSE)
return;
//transit the state to configured
pdev->flags &= ~USB_DEV_STATE_MASK;
pdev->flags |= USB_DEV_STATE_CONFIGURED;
unlock_dev(pdev, TRUE);
//
// we change to use our thread for driver choosing. it will reduce
// the race condition when different pnp event comes simultaneously
//
usb_dbg_print(DBGLVL_MAXIMUM, ("compdev_set_cfg_completion(): start select driver for the dev\n"));
compdev_post_event_select_driver(dev_mgr, dev_handle);
return;
}
LockFile::LockFile( const std::string &dev,
int lockPid )
: dev_(dev),
lockPid_(lockPid)
{
lock_dev( dev_.c_str(), lockPid_ );
}
BOOLEAN
compdev_post_event_select_driver(PUSB_DEV_MANAGER dev_mgr, DEV_HANDLE dev_handle)
{
PUSB_EVENT pevent;
BOOLEAN bret;
PUSB_DEV pdev;
USE_BASIC_NON_PENDING_IRQL;
if (dev_mgr == NULL || dev_handle == 0)
return FALSE;
if (usb_query_and_lock_dev(dev_mgr, dev_handle, &pdev) != STATUS_SUCCESS)
return FALSE;
KeAcquireSpinLockAtDpcLevel(&dev_mgr->event_list_lock);
lock_dev(pdev, TRUE);
if (dev_state(pdev) == USB_DEV_STATE_ZOMB)
{
bret = FALSE;
goto LBL_OUT;
}
pevent = alloc_event(&dev_mgr->event_pool, 1);
if (pevent == NULL)
{
bret = FALSE;
goto LBL_OUT;
}
pevent->flags = USB_EVENT_FLAG_ACTIVE;
pevent->event = USB_EVENT_DEFAULT;
pevent->pdev = pdev;
pevent->context = 0;
pevent->param = 0;
pevent->pnext = 0; //vertical queue for serialized operation
pevent->process_event = compdev_event_select_if_driver;
pevent->process_queue = event_list_default_process_queue;
InsertTailList(&dev_mgr->event_list, &pevent->event_link);
KeSetEvent(&dev_mgr->wake_up_event, 0, FALSE); // wake up the dev_mgr_thread
bret = TRUE;
LBL_OUT:
unlock_dev(pdev, TRUE);
KeReleaseSpinLockFromDpcLevel(&dev_mgr->event_list_lock);
usb_unlock_dev(pdev);
return bret;
}
Stream_t *XdfOpen(struct device *dev, char *name,
int mode, char *errmsg, struct xdf_info *info)
{
Xdf_t *This;
off_t begin, end;
struct bootsector *boot;
int type;
if(dev && (!SHOULD_USE_XDF(dev) || check_geom(dev, 0, 0)))
return NULL;
This = New(Xdf_t);
if (!This)
return NULL;
This->Class = &XdfClass;
This->sector_size = 512;
This->stretch = 0;
precmd(dev);
This->fd = open(name, mode | dev->mode | O_EXCL | O_NDELAY);
if(This->fd < 0) {
#ifdef HAVE_SNPRINTF
snprintf(errmsg,199,"xdf floppy: open: \"%s\"", strerror(errno));
#else
sprintf(errmsg,"xdf floppy: open: \"%s\"", strerror(errno));
#endif
goto exit_0;
}
closeExec(This->fd);
This->drive = GET_DRIVE(This->fd);
if(This->drive < 0)
goto exit_1;
/* allocate buffer */
This->buffer = (char *) malloc(96 * 512);
if (!This->buffer)
goto exit_1;
This->current_track = -1;
This->track_map = (TrackMap_t *)
calloc(96, sizeof(TrackMap_t));
if(!This->track_map)
goto exit_2;
/* lock the device on writes */
if (lock_dev(This->fd, mode == O_RDWR, dev)) {
#ifdef HAVE_SNPRINTF
snprintf(errmsg,199,"xdf floppy: device \"%s\" busy:",
dev->name);
#else
sprintf(errmsg,"xdf floppy: device \"%s\" busy:",
dev->name);
#endif
goto exit_3;
}
/* Before reading the boot sector, assume dummy values suitable
* for reading at least the boot sector */
This->track_size = 11;
This->track0_size = 6;
This->rate = 0;
This->FatSize = 9;
This->RootDirSize = 1;
decompose(This, 0, 512, &begin, &end, 0);
if (load_data(This, 0, 1, 1) < 0 ) {
This->rate = 0x43;
if(load_data(This, 0, 1, 1) < 0)
goto exit_3;
}
boot = (struct bootsector *) This->buffer;
This->FatSize = WORD(fatlen);
This->RootDirSize = WORD(dirents)/16;
This->track_size = WORD(nsect);
for(type=0; type < NUMBER(xdf_table); type++) {
if(xdf_table[type].track_size == This->track_size) {
This->map = xdf_table[type].map;
This->track0_size = xdf_table[type].track0_size;
This->rootskip = xdf_table[type].rootskip;
break;
}
}
if(type == NUMBER(xdf_table))
goto exit_3;
if(info) {
info->RootDirSize = This->RootDirSize;
info->FatSize = This->FatSize;
info->BadSectors = 5;
}
decompose(This, 0, 512, &begin, &end, 1);
This->refs = 1;
This->Next = 0;
This->Buffer = 0;
if(dev)
set_geom(boot, dev);
return (Stream_t *) This;
exit_3:
Free(This->track_map);
exit_2:
Free(This->buffer);
exit_1:
close(This->fd);
exit_0:
Free(This);
return NULL;
}
//this function is called by the hcd's
//dispatch when they have done their job.
NTSTATUS
dev_mgr_dispatch(IN PUSB_DEV_MANAGER dev_mgr, IN PIRP irp)
{
PIO_STACK_LOCATION irp_stack;
NTSTATUS status;
ULONG ctrl_code;
USE_NON_PENDING_IRQL;
ASSERT(irp);
if (dev_mgr == NULL)
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
status = STATUS_SUCCESS;
irp_stack = IoGetCurrentIrpStackLocation(irp);
ctrl_code = irp_stack->Parameters.DeviceIoControl.IoControlCode;
switch (irp_stack->MajorFunction)
{
case IRP_MJ_CREATE:
{
InterlockedIncrement(&dev_mgr->open_count);
EXIT_DISPATCH(STATUS_SUCCESS, irp);
}
case IRP_MJ_CLOSE:
{
InterlockedDecrement(&dev_mgr->open_count);
EXIT_DISPATCH(STATUS_SUCCESS, irp);
}
case IRP_MJ_INTERNAL_DEVICE_CONTROL:
case IRP_MJ_DEVICE_CONTROL:
{
switch (ctrl_code)
{
case IOCTL_GET_DEV_COUNT:
{
LONG dev_count;
irp->IoStatus.Information = 0;
if (irp_stack->Parameters.DeviceIoControl.OutputBufferLength < sizeof(LONG))
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
KeAcquireSpinLock(&dev_mgr->dev_list_lock, &old_irql);
dev_count = usb_count_list(&dev_mgr->dev_list);
KeReleaseSpinLock(&dev_mgr->dev_list_lock, old_irql);
*((PLONG) irp->AssociatedIrp.SystemBuffer) = dev_count;
irp->IoStatus.Information = sizeof(LONG);
EXIT_DISPATCH(STATUS_SUCCESS, irp);
}
case IOCTL_ENUM_DEVICES:
{
PLIST_ENTRY pthis, pnext;
LONG dev_count, array_size, i, j = 0;
PUSB_DEV pdev;
PENUM_DEV_ARRAY peda;
irp->IoStatus.Information = 0;
if (irp_stack->Parameters.DeviceIoControl.InputBufferLength < sizeof(LONG))
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
if (irp_stack->Parameters.DeviceIoControl.OutputBufferLength < sizeof(ENUM_DEV_ARRAY))
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
array_size = *((PULONG) irp->AssociatedIrp.SystemBuffer);
KeAcquireSpinLock(&dev_mgr->dev_list_lock, &old_irql);
dev_count = usb_count_list(&dev_mgr->dev_list);
dev_count = dev_count > array_size ? array_size : dev_count;
peda = (PENUM_DEV_ARRAY) irp->AssociatedIrp.SystemBuffer;
RtlZeroMemory(peda, sizeof(ENUM_DEV_ARRAY) + (dev_count - 1) * sizeof(ENUM_DEV_ELEMENT));
if (dev_count)
{
ListFirst(&dev_mgr->dev_list, pthis);
for(i = 0, j = 0; i < dev_count; i++)
{
pdev = struct_ptr(pthis, USB_DEV, dev_link);
ListNext(&dev_mgr->dev_list, pthis, pnext);
pthis = pnext;
lock_dev(pdev, FALSE);
if (dev_state(pdev) == USB_DEV_STATE_ZOMB)
{
unlock_dev(pdev, FALSE);
continue;
}
if (dev_state(pdev) < USB_DEV_STATE_ADDRESSED)
{
unlock_dev(pdev, FALSE);
continue;
}
peda->dev_arr[i].dev_handle = (pdev->dev_id << 16);
//may not get the desc yet
if (pdev->pusb_dev_desc)
{
peda->dev_arr[i].product_id = pdev->pusb_dev_desc->idProduct;
peda->dev_arr[i].vendor_id = pdev->pusb_dev_desc->idVendor;
}
else
{
peda->dev_arr[i].product_id = 0xffff;
peda->dev_arr[i].vendor_id = 0xffff;
}
peda->dev_arr[i].dev_addr = pdev->dev_addr;
unlock_dev(pdev, FALSE);
j++;
}
}
peda->dev_count = dev_count ? j : 0;
KeReleaseSpinLock(&dev_mgr->dev_list_lock, old_irql);
irp->IoStatus.Information =
sizeof(ENUM_DEV_ARRAY) + (dev_count - 1) * sizeof(ENUM_DEV_ELEMENT);
EXIT_DISPATCH(STATUS_SUCCESS, irp);
}
case IOCTL_GET_DEV_DESC:
{
GET_DEV_DESC_REQ gddr;
PUSB_DESC_HEADER pusb_desc_header;
PUSB_DEV pdev;
LONG buf_size;
if (irp_stack->Parameters.DeviceIoControl.InputBufferLength < sizeof(GET_DEV_DESC_REQ))
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
if (irp_stack->Parameters.DeviceIoControl.OutputBufferLength < 8)
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
status = STATUS_SUCCESS;
buf_size = irp_stack->Parameters.DeviceIoControl.OutputBufferLength;
RtlCopyMemory(&gddr, irp->AssociatedIrp.SystemBuffer, sizeof(GET_DEV_DESC_REQ));
pusb_desc_header = irp->AssociatedIrp.SystemBuffer;
if (gddr.desc_type != USB_DT_CONFIG && gddr.desc_type != USB_DT_DEVICE)
{
EXIT_DISPATCH(STATUS_INVALID_DEVICE_REQUEST, irp);
}
if (usb_query_and_lock_dev(dev_mgr, gddr.dev_handle, &pdev) != STATUS_SUCCESS)
{
EXIT_DISPATCH(STATUS_IO_DEVICE_ERROR, irp);
}
lock_dev(pdev, FALSE);
if (dev_state(pdev) == USB_DEV_STATE_ZOMB)
{
status = STATUS_INVALID_DEVICE_STATE;
goto ERROR_OUT;
}
if (dev_state(pdev) != USB_DEV_STATE_ADDRESSED &&
dev_state(pdev) != USB_DEV_STATE_CONFIGURED)
{
status = STATUS_DEVICE_NOT_READY;
goto ERROR_OUT;
}
if (pdev->pusb_dev_desc == NULL)
{
status = STATUS_DEVICE_NOT_READY;
goto ERROR_OUT;
}
if (gddr.desc_type == USB_DT_DEVICE)
{
RtlCopyMemory(pusb_desc_header,
pdev->pusb_dev_desc,
buf_size > sizeof(USB_DEVICE_DESC)
? sizeof(USB_DEVICE_DESC) : buf_size);
irp->IoStatus.Information =
buf_size >= sizeof(USB_DEVICE_DESC) ? sizeof(USB_DEVICE_DESC) : buf_size;
}
else if (gddr.desc_type == USB_DT_CONFIG)
{
PUSB_CONFIGURATION_DESC pusb_config_desc;
if (pdev->pusb_dev_desc->bNumConfigurations <= gddr.desc_idx)
{
status = STATUS_INVALID_PARAMETER;
goto ERROR_OUT;
}
pusb_config_desc = usb_find_config_desc_by_idx((PUCHAR) & pdev->pusb_dev_desc[1],
gddr.desc_idx,
pdev->pusb_dev_desc->
bNumConfigurations);
if (pusb_config_desc == NULL)
{
status = STATUS_DEVICE_NOT_READY;
goto ERROR_OUT;
}
RtlCopyMemory(pusb_desc_header,
pusb_config_desc,
buf_size >= pusb_config_desc->wTotalLength
? pusb_config_desc->wTotalLength : buf_size);
irp->IoStatus.Information =
buf_size >= pusb_config_desc->wTotalLength
? pusb_config_desc->wTotalLength : buf_size;
}
ERROR_OUT:
unlock_dev(pdev, FALSE);
usb_unlock_dev(pdev);
EXIT_DISPATCH(status, irp);
}
case IOCTL_SUBMIT_URB_RD:
case IOCTL_SUBMIT_URB_WR:
case IOCTL_SUBMIT_URB_NOIO:
{
PURB purb;
ULONG endp_idx, if_idx, user_buffer_length = 0;
PUCHAR user_buffer = NULL;
PUSB_DEV pdev;
DEV_HANDLE endp_handle;
PUSB_ENDPOINT pendp;
if (irp_stack->Parameters.DeviceIoControl.InputBufferLength < sizeof(URB))
{
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
}
purb = (PURB) irp->AssociatedIrp.SystemBuffer;
endp_handle = purb->endp_handle;
if (ctrl_code == IOCTL_SUBMIT_URB_RD || ctrl_code == IOCTL_SUBMIT_URB_WR)
{
if (irp_stack->MajorFunction == IRP_MJ_DEVICE_CONTROL)
{
user_buffer_length = irp_stack->Parameters.DeviceIoControl.OutputBufferLength;
if (user_buffer_length == 0)
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
user_buffer = MmGetSystemAddressForMdl(irp->MdlAddress);
}
else
{
if (purb->data_buffer == NULL || purb->data_length == 0)
EXIT_DISPATCH(STATUS_INVALID_PARAMETER, irp);
user_buffer_length = purb->data_length;
user_buffer = purb->data_buffer;
}
}
if (usb_query_and_lock_dev(dev_mgr, endp_handle & ~0xffff, &pdev) != STATUS_SUCCESS)
{
EXIT_DISPATCH(STATUS_IO_DEVICE_ERROR, irp);
}
lock_dev(pdev, FALSE);
if (dev_state(pdev) == USB_DEV_STATE_ZOMB || (dev_state(pdev) < USB_DEV_STATE_ADDRESSED))
{
status = STATUS_INVALID_DEVICE_STATE;
goto ERROR_OUT1;
}
if (dev_state(pdev) == USB_DEV_STATE_ADDRESSED && !default_endp_handle(endp_handle))
{
status = STATUS_DEVICE_NOT_READY;
goto ERROR_OUT1;
}
if_idx = if_idx_from_handle(endp_handle);
endp_idx = endp_idx_from_handle(endp_handle);
//if_idx exceeds the upper limit
if (pdev->usb_config)
{
if (if_idx >= pdev->usb_config->if_count
|| endp_idx >= pdev->usb_config->interf[if_idx].endp_count)
{
if (!default_endp_handle(endp_handle))
{
status = STATUS_INVALID_DEVICE_STATE;
goto ERROR_OUT1;
}
}
}
endp_from_handle(pdev, endp_handle, pendp);
// FIXME: don't know what evil will let loose
if (endp_type(pendp) != USB_ENDPOINT_XFER_CONTROL)
{
if (user_buffer_length > 0x100000)
{
status = STATUS_INVALID_PARAMETER;
goto ERROR_OUT1;
}
}
purb->pirp = irp;
purb->context = dev_mgr;
purb->reference = ctrl_code;
if (ctrl_code == IOCTL_SUBMIT_URB_RD || ctrl_code == IOCTL_SUBMIT_URB_WR)
{
if (ctrl_code == IOCTL_SUBMIT_URB_RD)
KeFlushIoBuffers(irp->MdlAddress, TRUE, TRUE);
else
KeFlushIoBuffers(irp->MdlAddress, FALSE, TRUE);
purb->data_buffer = user_buffer;
purb->data_length = user_buffer_length;
purb->completion = disp_urb_completion;
}
else
{
purb->completion = disp_noio_urb_completion;
}
unlock_dev(pdev, FALSE);
// we have to mark irp before the urb is scheduled to
// avoid race condition
IoMarkIrpPending(irp);
ASSERT(dev_mgr_register_irp(dev_mgr, irp, purb));
status = usb_submit_urb(dev_mgr, purb);
if (status != STATUS_PENDING)
{
IoGetCurrentIrpStackLocation((irp))->Control &= ~SL_PENDING_RETURNED;
dev_mgr_remove_irp(dev_mgr, irp);
}
usb_unlock_dev(pdev);
if (status != STATUS_PENDING)
{
irp->IoStatus.Status = status;
IoCompleteRequest(irp, IO_NO_INCREMENT);
}
return status;
ERROR_OUT1:
unlock_dev(pdev, FALSE);
usb_unlock_dev(pdev);
irp->IoStatus.Information = 0;
EXIT_DISPATCH(status, irp);
}
default:
{
irp->IoStatus.Information = 0;
EXIT_DISPATCH(STATUS_NOT_IMPLEMENTED, irp);
}
}
}
default:
{
irp->IoStatus.Information = 0;
break;
}
}
EXIT_DISPATCH(STATUS_INVALID_DEVICE_REQUEST, irp);
}
