linux_dsm_epyc7002/drivers/usb/core/message.c

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/*
* message.c - synchronous message handling
*/
#include <linux/pci.h> /* for scatterlist macros */
#include <linux/usb.h>
#include <linux/module.h>
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/mm.h>
#include <linux/timer.h>
#include <linux/ctype.h>
#include <linux/nls.h>
#include <linux/device.h>
#include <linux/scatterlist.h>
#include <linux/usb/quirks.h>
#include <linux/usb/hcd.h> /* for usbcore internals */
#include <asm/byteorder.h>
#include "usb.h"
static void cancel_async_set_config(struct usb_device *udev);
struct api_context {
struct completion done;
int status;
};
IRQ: Maintain regs pointer globally rather than passing to IRQ handlers Maintain a per-CPU global "struct pt_regs *" variable which can be used instead of passing regs around manually through all ~1800 interrupt handlers in the Linux kernel. The regs pointer is used in few places, but it potentially costs both stack space and code to pass it around. On the FRV arch, removing the regs parameter from all the genirq function results in a 20% speed up of the IRQ exit path (ie: from leaving timer_interrupt() to leaving do_IRQ()). Where appropriate, an arch may override the generic storage facility and do something different with the variable. On FRV, for instance, the address is maintained in GR28 at all times inside the kernel as part of general exception handling. Having looked over the code, it appears that the parameter may be handed down through up to twenty or so layers of functions. Consider a USB character device attached to a USB hub, attached to a USB controller that posts its interrupts through a cascaded auxiliary interrupt controller. A character device driver may want to pass regs to the sysrq handler through the input layer which adds another few layers of parameter passing. I've build this code with allyesconfig for x86_64 and i386. I've runtested the main part of the code on FRV and i386, though I can't test most of the drivers. I've also done partial conversion for powerpc and MIPS - these at least compile with minimal configurations. This will affect all archs. Mostly the changes should be relatively easy. Take do_IRQ(), store the regs pointer at the beginning, saving the old one: struct pt_regs *old_regs = set_irq_regs(regs); And put the old one back at the end: set_irq_regs(old_regs); Don't pass regs through to generic_handle_irq() or __do_IRQ(). In timer_interrupt(), this sort of change will be necessary: - update_process_times(user_mode(regs)); - profile_tick(CPU_PROFILING, regs); + update_process_times(user_mode(get_irq_regs())); + profile_tick(CPU_PROFILING); I'd like to move update_process_times()'s use of get_irq_regs() into itself, except that i386, alone of the archs, uses something other than user_mode(). Some notes on the interrupt handling in the drivers: (*) input_dev() is now gone entirely. The regs pointer is no longer stored in the input_dev struct. (*) finish_unlinks() in drivers/usb/host/ohci-q.c needs checking. It does something different depending on whether it's been supplied with a regs pointer or not. (*) Various IRQ handler function pointers have been moved to type irq_handler_t. Signed-Off-By: David Howells <dhowells@redhat.com> (cherry picked from 1b16e7ac850969f38b375e511e3fa2f474a33867 commit)
2006-10-05 20:55:46 +07:00
static void usb_api_blocking_completion(struct urb *urb)
{
struct api_context *ctx = urb->context;
ctx->status = urb->status;
complete(&ctx->done);
}
/*
* Starts urb and waits for completion or timeout. Note that this call
* is NOT interruptible. Many device driver i/o requests should be
* interruptible and therefore these drivers should implement their
* own interruptible routines.
*/
static int usb_start_wait_urb(struct urb *urb, int timeout, int *actual_length)
{
struct api_context ctx;
unsigned long expire;
int retval;
init_completion(&ctx.done);
urb->context = &ctx;
urb->actual_length = 0;
retval = usb_submit_urb(urb, GFP_NOIO);
if (unlikely(retval))
goto out;
expire = timeout ? msecs_to_jiffies(timeout) : MAX_SCHEDULE_TIMEOUT;
if (!wait_for_completion_timeout(&ctx.done, expire)) {
usb_kill_urb(urb);
retval = (ctx.status == -ENOENT ? -ETIMEDOUT : ctx.status);
dev_dbg(&urb->dev->dev,
"%s timed out on ep%d%s len=%u/%u\n",
current->comm,
usb_endpoint_num(&urb->ep->desc),
usb_urb_dir_in(urb) ? "in" : "out",
urb->actual_length,
urb->transfer_buffer_length);
} else
retval = ctx.status;
out:
if (actual_length)
*actual_length = urb->actual_length;
usb_free_urb(urb);
return retval;
}
/*-------------------------------------------------------------------*/
/* returns status (negative) or length (positive) */
static int usb_internal_control_msg(struct usb_device *usb_dev,
unsigned int pipe,
struct usb_ctrlrequest *cmd,
void *data, int len, int timeout)
{
struct urb *urb;
int retv;
int length;
urb = usb_alloc_urb(0, GFP_NOIO);
if (!urb)
return -ENOMEM;
usb_fill_control_urb(urb, usb_dev, pipe, (unsigned char *)cmd, data,
len, usb_api_blocking_completion, NULL);
retv = usb_start_wait_urb(urb, timeout, &length);
if (retv < 0)
return retv;
else
return length;
}
/**
* usb_control_msg - Builds a control urb, sends it off and waits for completion
* @dev: pointer to the usb device to send the message to
* @pipe: endpoint "pipe" to send the message to
* @request: USB message request value
* @requesttype: USB message request type value
* @value: USB message value
* @index: USB message index value
* @data: pointer to the data to send
* @size: length in bytes of the data to send
* @timeout: time in msecs to wait for the message to complete before timing
* out (if 0 the wait is forever)
*
* Context: !in_interrupt ()
*
* This function sends a simple control message to a specified endpoint and
* waits for the message to complete, or timeout.
*
* If successful, it returns the number of bytes transferred, otherwise a
* negative error number.
*
* Don't use this function from within an interrupt context, like a bottom half
* handler. If you need an asynchronous message, or need to send a message
* from within interrupt context, use usb_submit_urb().
* If a thread in your driver uses this call, make sure your disconnect()
* method can wait for it to complete. Since you don't have a handle on the
* URB used, you can't cancel the request.
*/
int usb_control_msg(struct usb_device *dev, unsigned int pipe, __u8 request,
__u8 requesttype, __u16 value, __u16 index, void *data,
__u16 size, int timeout)
{
struct usb_ctrlrequest *dr;
int ret;
dr = kmalloc(sizeof(struct usb_ctrlrequest), GFP_NOIO);
if (!dr)
return -ENOMEM;
dr->bRequestType = requesttype;
dr->bRequest = request;
dr->wValue = cpu_to_le16(value);
dr->wIndex = cpu_to_le16(index);
dr->wLength = cpu_to_le16(size);
ret = usb_internal_control_msg(dev, pipe, dr, data, size, timeout);
kfree(dr);
return ret;
}
EXPORT_SYMBOL_GPL(usb_control_msg);
/**
* usb_interrupt_msg - Builds an interrupt urb, sends it off and waits for completion
* @usb_dev: pointer to the usb device to send the message to
* @pipe: endpoint "pipe" to send the message to
* @data: pointer to the data to send
* @len: length in bytes of the data to send
* @actual_length: pointer to a location to put the actual length transferred
* in bytes
* @timeout: time in msecs to wait for the message to complete before
* timing out (if 0 the wait is forever)
*
* Context: !in_interrupt ()
*
* This function sends a simple interrupt message to a specified endpoint and
* waits for the message to complete, or timeout.
*
* If successful, it returns 0, otherwise a negative error number. The number
* of actual bytes transferred will be stored in the actual_length paramater.
*
* Don't use this function from within an interrupt context, like a bottom half
* handler. If you need an asynchronous message, or need to send a message
* from within interrupt context, use usb_submit_urb() If a thread in your
* driver uses this call, make sure your disconnect() method can wait for it to
* complete. Since you don't have a handle on the URB used, you can't cancel
* the request.
*/
int usb_interrupt_msg(struct usb_device *usb_dev, unsigned int pipe,
void *data, int len, int *actual_length, int timeout)
{
return usb_bulk_msg(usb_dev, pipe, data, len, actual_length, timeout);
}
EXPORT_SYMBOL_GPL(usb_interrupt_msg);
/**
* usb_bulk_msg - Builds a bulk urb, sends it off and waits for completion
* @usb_dev: pointer to the usb device to send the message to
* @pipe: endpoint "pipe" to send the message to
* @data: pointer to the data to send
* @len: length in bytes of the data to send
* @actual_length: pointer to a location to put the actual length transferred
* in bytes
* @timeout: time in msecs to wait for the message to complete before
* timing out (if 0 the wait is forever)
*
* Context: !in_interrupt ()
*
* This function sends a simple bulk message to a specified endpoint
* and waits for the message to complete, or timeout.
*
* If successful, it returns 0, otherwise a negative error number. The number
* of actual bytes transferred will be stored in the actual_length paramater.
*
* Don't use this function from within an interrupt context, like a bottom half
* handler. If you need an asynchronous message, or need to send a message
* from within interrupt context, use usb_submit_urb() If a thread in your
* driver uses this call, make sure your disconnect() method can wait for it to
* complete. Since you don't have a handle on the URB used, you can't cancel
* the request.
*
* Because there is no usb_interrupt_msg() and no USBDEVFS_INTERRUPT ioctl,
* users are forced to abuse this routine by using it to submit URBs for
* interrupt endpoints. We will take the liberty of creating an interrupt URB
* (with the default interval) if the target is an interrupt endpoint.
*/
int usb_bulk_msg(struct usb_device *usb_dev, unsigned int pipe,
void *data, int len, int *actual_length, int timeout)
{
struct urb *urb;
struct usb_host_endpoint *ep;
ep = usb_pipe_endpoint(usb_dev, pipe);
if (!ep || len < 0)
return -EINVAL;
urb = usb_alloc_urb(0, GFP_KERNEL);
if (!urb)
return -ENOMEM;
if ((ep->desc.bmAttributes & USB_ENDPOINT_XFERTYPE_MASK) ==
USB_ENDPOINT_XFER_INT) {
pipe = (pipe & ~(3 << 30)) | (PIPE_INTERRUPT << 30);
usb_fill_int_urb(urb, usb_dev, pipe, data, len,
usb_api_blocking_completion, NULL,
ep->desc.bInterval);
} else
usb_fill_bulk_urb(urb, usb_dev, pipe, data, len,
usb_api_blocking_completion, NULL);
return usb_start_wait_urb(urb, timeout, actual_length);
}
EXPORT_SYMBOL_GPL(usb_bulk_msg);
/*-------------------------------------------------------------------*/
static void sg_clean(struct usb_sg_request *io)
{
if (io->urbs) {
while (io->entries--)
usb_free_urb(io->urbs [io->entries]);
kfree(io->urbs);
io->urbs = NULL;
}
io->dev = NULL;
}
static void sg_complete(struct urb *urb)
{
struct usb_sg_request *io = urb->context;
int status = urb->status;
spin_lock(&io->lock);
/* In 2.5 we require hcds' endpoint queues not to progress after fault
* reports, until the completion callback (this!) returns. That lets
* device driver code (like this routine) unlink queued urbs first,
* if it needs to, since the HC won't work on them at all. So it's
* not possible for page N+1 to overwrite page N, and so on.
*
* That's only for "hard" faults; "soft" faults (unlinks) sometimes
* complete before the HCD can get requests away from hardware,
* though never during cleanup after a hard fault.
*/
if (io->status
&& (io->status != -ECONNRESET
|| status != -ECONNRESET)
&& urb->actual_length) {
dev_err(io->dev->bus->controller,
"dev %s ep%d%s scatterlist error %d/%d\n",
io->dev->devpath,
usb_endpoint_num(&urb->ep->desc),
usb_urb_dir_in(urb) ? "in" : "out",
status, io->status);
/* BUG (); */
}
if (io->status == 0 && status && status != -ECONNRESET) {
int i, found, retval;
io->status = status;
/* the previous urbs, and this one, completed already.
* unlink pending urbs so they won't rx/tx bad data.
* careful: unlink can sometimes be synchronous...
*/
spin_unlock(&io->lock);
for (i = 0, found = 0; i < io->entries; i++) {
if (!io->urbs [i] || !io->urbs [i]->dev)
continue;
if (found) {
retval = usb_unlink_urb(io->urbs [i]);
if (retval != -EINPROGRESS &&
retval != -ENODEV &&
retval != -EBUSY &&
retval != -EIDRM)
dev_err(&io->dev->dev,
"%s, unlink --> %d\n",
__func__, retval);
} else if (urb == io->urbs [i])
found = 1;
}
spin_lock(&io->lock);
}
/* on the last completion, signal usb_sg_wait() */
io->bytes += urb->actual_length;
io->count--;
if (!io->count)
complete(&io->complete);
spin_unlock(&io->lock);
}
/**
* usb_sg_init - initializes scatterlist-based bulk/interrupt I/O request
* @io: request block being initialized. until usb_sg_wait() returns,
* treat this as a pointer to an opaque block of memory,
* @dev: the usb device that will send or receive the data
* @pipe: endpoint "pipe" used to transfer the data
* @period: polling rate for interrupt endpoints, in frames or
* (for high speed endpoints) microframes; ignored for bulk
* @sg: scatterlist entries
* @nents: how many entries in the scatterlist
* @length: how many bytes to send from the scatterlist, or zero to
* send every byte identified in the list.
* @mem_flags: SLAB_* flags affecting memory allocations in this call
*
* Returns zero for success, else a negative errno value. This initializes a
* scatter/gather request, allocating resources such as I/O mappings and urb
* memory (except maybe memory used by USB controller drivers).
*
* The request must be issued using usb_sg_wait(), which waits for the I/O to
* complete (or to be canceled) and then cleans up all resources allocated by
* usb_sg_init().
*
* The request may be canceled with usb_sg_cancel(), either before or after
* usb_sg_wait() is called.
*/
int usb_sg_init(struct usb_sg_request *io, struct usb_device *dev,
unsigned pipe, unsigned period, struct scatterlist *sg,
int nents, size_t length, gfp_t mem_flags)
{
int i;
int urb_flags;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
int use_sg;
if (!io || !dev || !sg
|| usb_pipecontrol(pipe)
|| usb_pipeisoc(pipe)
|| nents <= 0)
return -EINVAL;
spin_lock_init(&io->lock);
io->dev = dev;
io->pipe = pipe;
if (dev->bus->sg_tablesize > 0) {
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
use_sg = true;
io->entries = 1;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
} else {
use_sg = false;
io->entries = nents;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
}
/* initialize all the urbs we'll use */
io->urbs = kmalloc(io->entries * sizeof *io->urbs, mem_flags);
if (!io->urbs)
goto nomem;
urb_flags = URB_NO_INTERRUPT;
if (usb_pipein(pipe))
urb_flags |= URB_SHORT_NOT_OK;
for_each_sg(sg, sg, io->entries, i) {
struct urb *urb;
unsigned len;
2010-04-03 00:27:28 +07:00
urb = usb_alloc_urb(0, mem_flags);
if (!urb) {
io->entries = i;
goto nomem;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
}
io->urbs[i] = urb;
urb->dev = NULL;
urb->pipe = pipe;
urb->interval = period;
urb->transfer_flags = urb_flags;
urb->complete = sg_complete;
urb->context = io;
urb->sg = sg;
if (use_sg) {
/* There is no single transfer buffer */
urb->transfer_buffer = NULL;
urb->num_sgs = nents;
/* A length of zero means transfer the whole sg list */
len = length;
if (len == 0) {
struct scatterlist *sg2;
int j;
for_each_sg(sg, sg2, nents, j)
len += sg2->length;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
}
} else {
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
/*
2010-04-03 00:27:28 +07:00
* Some systems can't use DMA; they use PIO instead.
* For their sakes, transfer_buffer is set whenever
* possible.
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
*/
2010-04-03 00:27:28 +07:00
if (!PageHighMem(sg_page(sg)))
urb->transfer_buffer = sg_virt(sg);
else
urb->transfer_buffer = NULL;
2010-04-03 00:27:28 +07:00
len = sg->length;
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
if (length) {
len = min_t(size_t, len, length);
USB: Push scatter gather lists down to host controller drivers. This is the original patch I created before David Vrabel posted a better patch (http://marc.info/?l=linux-usb&m=123377477209109&w=2) that does basically the same thing. This patch will get replaced with his (modified) patch later. Allow USB device drivers that use usb_sg_init() and usb_sg_wait() to push bulk endpoint scatter gather lists down to the host controller drivers. This allows host controller drivers to more efficiently enqueue these transfers, and allows the xHCI host controller to better take advantage of USB 3.0 "bursts" for bulk endpoints. This patch currently only enables scatter gather lists for bulk endpoints. Other endpoint types that use the usb_sg_* functions will not have their scatter gather lists pushed down to the host controller. For periodic endpoints, we want each scatterlist entry to be a separate transfer. Eventually, HCDs could parse these scatter-gather lists for periodic endpoints also. For now, we use the old code and call usb_submit_urb() for each scatterlist entry. The caller of usb_sg_init() can request that all bytes in the scatter gather list be transferred by passing in a length of zero. Handle that request for a bulk endpoint under xHCI by walking the scatter gather list and calculating the length. We could let the HCD handle a zero length in this case, but I'm not sure if the core layers in between will get confused by this. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:59:01 +07:00
length -= len;
if (length == 0)
io->entries = i + 1;
}
}
urb->transfer_buffer_length = len;
}
io->urbs[--i]->transfer_flags &= ~URB_NO_INTERRUPT;
/* transaction state */
io->count = io->entries;
io->status = 0;
io->bytes = 0;
init_completion(&io->complete);
return 0;
nomem:
sg_clean(io);
return -ENOMEM;
}
EXPORT_SYMBOL_GPL(usb_sg_init);
/**
* usb_sg_wait - synchronously execute scatter/gather request
* @io: request block handle, as initialized with usb_sg_init().
* some fields become accessible when this call returns.
* Context: !in_interrupt ()
*
* This function blocks until the specified I/O operation completes. It
* leverages the grouping of the related I/O requests to get good transfer
* rates, by queueing the requests. At higher speeds, such queuing can
* significantly improve USB throughput.
*
* There are three kinds of completion for this function.
* (1) success, where io->status is zero. The number of io->bytes
* transferred is as requested.
* (2) error, where io->status is a negative errno value. The number
* of io->bytes transferred before the error is usually less
* than requested, and can be nonzero.
* (3) cancellation, a type of error with status -ECONNRESET that
* is initiated by usb_sg_cancel().
*
* When this function returns, all memory allocated through usb_sg_init() or
* this call will have been freed. The request block parameter may still be
* passed to usb_sg_cancel(), or it may be freed. It could also be
* reinitialized and then reused.
*
* Data Transfer Rates:
*
* Bulk transfers are valid for full or high speed endpoints.
* The best full speed data rate is 19 packets of 64 bytes each
* per frame, or 1216 bytes per millisecond.
* The best high speed data rate is 13 packets of 512 bytes each
* per microframe, or 52 KBytes per millisecond.
*
* The reason to use interrupt transfers through this API would most likely
* be to reserve high speed bandwidth, where up to 24 KBytes per millisecond
* could be transferred. That capability is less useful for low or full
* speed interrupt endpoints, which allow at most one packet per millisecond,
* of at most 8 or 64 bytes (respectively).
USB: Support for bandwidth allocation. Originally, the USB core had no support for allocating bandwidth when a particular configuration or alternate setting for an interface was selected. Instead, the device driver's URB submission would fail if there was not enough bandwidth for a periodic endpoint. Drivers could work around this, by using the scatter-gather list API to guarantee bandwidth. This patch adds host controller API to allow the USB core to allocate or deallocate bandwidth for an endpoint. Endpoints are added to or dropped from a copy of the current schedule by calling add_endpoint() or drop_endpoint(), and then the schedule is atomically evaluated with a call to check_bandwidth(). This allows all the endpoints for a new configuration or alternate setting to be added at the same time that the endpoints from the old configuration or alt setting are dropped. Endpoints must be added to the schedule before any URBs are submitted to them. The HCD must be allowed to reject a new configuration or alt setting before the control transfer is sent to the device requesting the change. It may reject the change because there is not enough bandwidth, not enough internal resources (such as memory on an embedded host controller), or perhaps even for security reasons in a virtualized environment. If the call to check_bandwidth() fails, the USB core must call reset_bandwidth(). This causes the schedule to be reverted back to the state it was in just after the last successful check_bandwidth() call. If the call succeeds, the host controller driver (and hardware) will have changed its internal state to match the new configuration or alternate setting. The USB core can then issue a control transfer to the device to change the configuration or alt setting. This allows the core to test new configurations or alternate settings before unbinding drivers bound to interfaces in the old configuration. WIP: The USB core must add endpoints from all interfaces in a configuration to the schedule, because a driver may claim that interface at any time. A slight optimization might be to add the endpoints to the schedule once a driver claims that interface. FIXME This patch does not cover changing alternate settings, but it does handle a configuration change or de-configuration. FIXME The code for managing the schedule is currently HCD specific. A generic scheduling algorithm could be added for host controllers without built-in scheduling support. For now, if a host controller does not define the check_bandwidth() function, the call to usb_hcd_check_bandwidth() will always succeed. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:58:26 +07:00
*
* It is not necessary to call this function to reserve bandwidth for devices
* under an xHCI host controller, as the bandwidth is reserved when the
* configuration or interface alt setting is selected.
*/
void usb_sg_wait(struct usb_sg_request *io)
{
int i;
int entries = io->entries;
/* queue the urbs. */
spin_lock_irq(&io->lock);
i = 0;
while (i < entries && !io->status) {
int retval;
io->urbs[i]->dev = io->dev;
retval = usb_submit_urb(io->urbs [i], GFP_ATOMIC);
/* after we submit, let completions or cancelations fire;
* we handshake using io->status.
*/
spin_unlock_irq(&io->lock);
switch (retval) {
/* maybe we retrying will recover */
case -ENXIO: /* hc didn't queue this one */
case -EAGAIN:
case -ENOMEM:
retval = 0;
yield();
break;
/* no error? continue immediately.
*
* NOTE: to work better with UHCI (4K I/O buffer may
* need 3K of TDs) it may be good to limit how many
* URBs are queued at once; N milliseconds?
*/
case 0:
++i;
cpu_relax();
break;
/* fail any uncompleted urbs */
default:
io->urbs[i]->status = retval;
dev_dbg(&io->dev->dev, "%s, submit --> %d\n",
__func__, retval);
usb_sg_cancel(io);
}
spin_lock_irq(&io->lock);
if (retval && (io->status == 0 || io->status == -ECONNRESET))
io->status = retval;
}
io->count -= entries - i;
if (io->count == 0)
complete(&io->complete);
spin_unlock_irq(&io->lock);
/* OK, yes, this could be packaged as non-blocking.
* So could the submit loop above ... but it's easier to
* solve neither problem than to solve both!
*/
wait_for_completion(&io->complete);
sg_clean(io);
}
EXPORT_SYMBOL_GPL(usb_sg_wait);
/**
* usb_sg_cancel - stop scatter/gather i/o issued by usb_sg_wait()
* @io: request block, initialized with usb_sg_init()
*
* This stops a request after it has been started by usb_sg_wait().
* It can also prevents one initialized by usb_sg_init() from starting,
* so that call just frees resources allocated to the request.
*/
void usb_sg_cancel(struct usb_sg_request *io)
{
unsigned long flags;
spin_lock_irqsave(&io->lock, flags);
/* shut everything down, if it didn't already */
if (!io->status) {
int i;
io->status = -ECONNRESET;
spin_unlock(&io->lock);
for (i = 0; i < io->entries; i++) {
int retval;
if (!io->urbs [i]->dev)
continue;
retval = usb_unlink_urb(io->urbs [i]);
if (retval != -EINPROGRESS
&& retval != -ENODEV
&& retval != -EBUSY
&& retval != -EIDRM)
dev_warn(&io->dev->dev, "%s, unlink --> %d\n",
__func__, retval);
}
spin_lock(&io->lock);
}
spin_unlock_irqrestore(&io->lock, flags);
}
EXPORT_SYMBOL_GPL(usb_sg_cancel);
/*-------------------------------------------------------------------*/
/**
* usb_get_descriptor - issues a generic GET_DESCRIPTOR request
* @dev: the device whose descriptor is being retrieved
* @type: the descriptor type (USB_DT_*)
* @index: the number of the descriptor
* @buf: where to put the descriptor
* @size: how big is "buf"?
* Context: !in_interrupt ()
*
* Gets a USB descriptor. Convenience functions exist to simplify
* getting some types of descriptors. Use
* usb_get_string() or usb_string() for USB_DT_STRING.
* Device (USB_DT_DEVICE) and configuration descriptors (USB_DT_CONFIG)
* are part of the device structure.
* In addition to a number of USB-standard descriptors, some
* devices also use class-specific or vendor-specific descriptors.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns the number of bytes received on success, or else the status code
* returned by the underlying usb_control_msg() call.
*/
int usb_get_descriptor(struct usb_device *dev, unsigned char type,
unsigned char index, void *buf, int size)
{
int i;
int result;
memset(buf, 0, size); /* Make sure we parse really received data */
for (i = 0; i < 3; ++i) {
/* retry on length 0 or error; some devices are flakey */
result = usb_control_msg(dev, usb_rcvctrlpipe(dev, 0),
USB_REQ_GET_DESCRIPTOR, USB_DIR_IN,
(type << 8) + index, 0, buf, size,
USB_CTRL_GET_TIMEOUT);
if (result <= 0 && result != -ETIMEDOUT)
continue;
if (result > 1 && ((u8 *)buf)[1] != type) {
result = -ENODATA;
continue;
}
break;
}
return result;
}
EXPORT_SYMBOL_GPL(usb_get_descriptor);
/**
* usb_get_string - gets a string descriptor
* @dev: the device whose string descriptor is being retrieved
* @langid: code for language chosen (from string descriptor zero)
* @index: the number of the descriptor
* @buf: where to put the string
* @size: how big is "buf"?
* Context: !in_interrupt ()
*
* Retrieves a string, encoded using UTF-16LE (Unicode, 16 bits per character,
* in little-endian byte order).
* The usb_string() function will often be a convenient way to turn
* these strings into kernel-printable form.
*
* Strings may be referenced in device, configuration, interface, or other
* descriptors, and could also be used in vendor-specific ways.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns the number of bytes received on success, or else the status code
* returned by the underlying usb_control_msg() call.
*/
static int usb_get_string(struct usb_device *dev, unsigned short langid,
unsigned char index, void *buf, int size)
{
int i;
int result;
for (i = 0; i < 3; ++i) {
/* retry on length 0 or stall; some devices are flakey */
result = usb_control_msg(dev, usb_rcvctrlpipe(dev, 0),
USB_REQ_GET_DESCRIPTOR, USB_DIR_IN,
(USB_DT_STRING << 8) + index, langid, buf, size,
USB_CTRL_GET_TIMEOUT);
if (result == 0 || result == -EPIPE)
continue;
if (result > 1 && ((u8 *) buf)[1] != USB_DT_STRING) {
result = -ENODATA;
continue;
}
break;
}
return result;
}
static void usb_try_string_workarounds(unsigned char *buf, int *length)
{
int newlength, oldlength = *length;
for (newlength = 2; newlength + 1 < oldlength; newlength += 2)
if (!isprint(buf[newlength]) || buf[newlength + 1])
break;
if (newlength > 2) {
buf[0] = newlength;
*length = newlength;
}
}
static int usb_string_sub(struct usb_device *dev, unsigned int langid,
unsigned int index, unsigned char *buf)
{
int rc;
/* Try to read the string descriptor by asking for the maximum
* possible number of bytes */
if (dev->quirks & USB_QUIRK_STRING_FETCH_255)
rc = -EIO;
else
rc = usb_get_string(dev, langid, index, buf, 255);
/* If that failed try to read the descriptor length, then
* ask for just that many bytes */
if (rc < 2) {
rc = usb_get_string(dev, langid, index, buf, 2);
if (rc == 2)
rc = usb_get_string(dev, langid, index, buf, buf[0]);
}
if (rc >= 2) {
if (!buf[0] && !buf[1])
usb_try_string_workarounds(buf, &rc);
/* There might be extra junk at the end of the descriptor */
if (buf[0] < rc)
rc = buf[0];
rc = rc - (rc & 1); /* force a multiple of two */
}
if (rc < 2)
rc = (rc < 0 ? rc : -EINVAL);
return rc;
}
static int usb_get_langid(struct usb_device *dev, unsigned char *tbuf)
{
int err;
if (dev->have_langid)
return 0;
if (dev->string_langid < 0)
return -EPIPE;
err = usb_string_sub(dev, 0, 0, tbuf);
/* If the string was reported but is malformed, default to english
* (0x0409) */
if (err == -ENODATA || (err > 0 && err < 4)) {
dev->string_langid = 0x0409;
dev->have_langid = 1;
dev_err(&dev->dev,
"string descriptor 0 malformed (err = %d), "
"defaulting to 0x%04x\n",
err, dev->string_langid);
return 0;
}
/* In case of all other errors, we assume the device is not able to
* deal with strings at all. Set string_langid to -1 in order to
* prevent any string to be retrieved from the device */
if (err < 0) {
dev_err(&dev->dev, "string descriptor 0 read error: %d\n",
err);
dev->string_langid = -1;
return -EPIPE;
}
/* always use the first langid listed */
dev->string_langid = tbuf[2] | (tbuf[3] << 8);
dev->have_langid = 1;
dev_dbg(&dev->dev, "default language 0x%04x\n",
dev->string_langid);
return 0;
}
/**
* usb_string - returns UTF-8 version of a string descriptor
* @dev: the device whose string descriptor is being retrieved
* @index: the number of the descriptor
* @buf: where to put the string
* @size: how big is "buf"?
* Context: !in_interrupt ()
*
* This converts the UTF-16LE encoded strings returned by devices, from
* usb_get_string_descriptor(), to null-terminated UTF-8 encoded ones
* that are more usable in most kernel contexts. Note that this function
* chooses strings in the first language supported by the device.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns length of the string (>= 0) or usb_control_msg status (< 0).
*/
int usb_string(struct usb_device *dev, int index, char *buf, size_t size)
{
unsigned char *tbuf;
int err;
if (dev->state == USB_STATE_SUSPENDED)
return -EHOSTUNREACH;
if (size <= 0 || !buf || !index)
return -EINVAL;
buf[0] = 0;
tbuf = kmalloc(256, GFP_NOIO);
if (!tbuf)
return -ENOMEM;
err = usb_get_langid(dev, tbuf);
if (err < 0)
goto errout;
err = usb_string_sub(dev, dev->string_langid, index, tbuf);
if (err < 0)
goto errout;
size--; /* leave room for trailing NULL char in output buffer */
err = utf16s_to_utf8s((wchar_t *) &tbuf[2], (err - 2) / 2,
UTF16_LITTLE_ENDIAN, buf, size);
buf[err] = 0;
if (tbuf[1] != USB_DT_STRING)
dev_dbg(&dev->dev,
"wrong descriptor type %02x for string %d (\"%s\")\n",
tbuf[1], index, buf);
errout:
kfree(tbuf);
return err;
}
EXPORT_SYMBOL_GPL(usb_string);
/* one UTF-8-encoded 16-bit character has at most three bytes */
#define MAX_USB_STRING_SIZE (127 * 3 + 1)
/**
* usb_cache_string - read a string descriptor and cache it for later use
* @udev: the device whose string descriptor is being read
* @index: the descriptor index
*
* Returns a pointer to a kmalloc'ed buffer containing the descriptor string,
* or NULL if the index is 0 or the string could not be read.
*/
char *usb_cache_string(struct usb_device *udev, int index)
{
char *buf;
char *smallbuf = NULL;
int len;
if (index <= 0)
return NULL;
buf = kmalloc(MAX_USB_STRING_SIZE, GFP_NOIO);
if (buf) {
len = usb_string(udev, index, buf, MAX_USB_STRING_SIZE);
if (len > 0) {
smallbuf = kmalloc(++len, GFP_NOIO);
if (!smallbuf)
return buf;
memcpy(smallbuf, buf, len);
}
kfree(buf);
}
return smallbuf;
}
/*
* usb_get_device_descriptor - (re)reads the device descriptor (usbcore)
* @dev: the device whose device descriptor is being updated
* @size: how much of the descriptor to read
* Context: !in_interrupt ()
*
* Updates the copy of the device descriptor stored in the device structure,
* which dedicates space for this purpose.
*
* Not exported, only for use by the core. If drivers really want to read
* the device descriptor directly, they can call usb_get_descriptor() with
* type = USB_DT_DEVICE and index = 0.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns the number of bytes received on success, or else the status code
* returned by the underlying usb_control_msg() call.
*/
int usb_get_device_descriptor(struct usb_device *dev, unsigned int size)
{
struct usb_device_descriptor *desc;
int ret;
if (size > sizeof(*desc))
return -EINVAL;
desc = kmalloc(sizeof(*desc), GFP_NOIO);
if (!desc)
return -ENOMEM;
ret = usb_get_descriptor(dev, USB_DT_DEVICE, 0, desc, size);
if (ret >= 0)
memcpy(&dev->descriptor, desc, size);
kfree(desc);
return ret;
}
/**
* usb_get_status - issues a GET_STATUS call
* @dev: the device whose status is being checked
* @type: USB_RECIP_*; for device, interface, or endpoint
* @target: zero (for device), else interface or endpoint number
* @data: pointer to two bytes of bitmap data
* Context: !in_interrupt ()
*
* Returns device, interface, or endpoint status. Normally only of
* interest to see if the device is self powered, or has enabled the
* remote wakeup facility; or whether a bulk or interrupt endpoint
* is halted ("stalled").
*
* Bits in these status bitmaps are set using the SET_FEATURE request,
* and cleared using the CLEAR_FEATURE request. The usb_clear_halt()
* function should be used to clear halt ("stall") status.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns the number of bytes received on success, or else the status code
* returned by the underlying usb_control_msg() call.
*/
int usb_get_status(struct usb_device *dev, int type, int target, void *data)
{
int ret;
u16 *status = kmalloc(sizeof(*status), GFP_KERNEL);
if (!status)
return -ENOMEM;
ret = usb_control_msg(dev, usb_rcvctrlpipe(dev, 0),
USB_REQ_GET_STATUS, USB_DIR_IN | type, 0, target, status,
sizeof(*status), USB_CTRL_GET_TIMEOUT);
*(u16 *)data = *status;
kfree(status);
return ret;
}
EXPORT_SYMBOL_GPL(usb_get_status);
/**
* usb_clear_halt - tells device to clear endpoint halt/stall condition
* @dev: device whose endpoint is halted
* @pipe: endpoint "pipe" being cleared
* Context: !in_interrupt ()
*
* This is used to clear halt conditions for bulk and interrupt endpoints,
* as reported by URB completion status. Endpoints that are halted are
* sometimes referred to as being "stalled". Such endpoints are unable
* to transmit or receive data until the halt status is cleared. Any URBs
* queued for such an endpoint should normally be unlinked by the driver
* before clearing the halt condition, as described in sections 5.7.5
* and 5.8.5 of the USB 2.0 spec.
*
* Note that control and isochronous endpoints don't halt, although control
* endpoints report "protocol stall" (for unsupported requests) using the
* same status code used to report a true stall.
*
* This call is synchronous, and may not be used in an interrupt context.
*
* Returns zero on success, or else the status code returned by the
* underlying usb_control_msg() call.
*/
int usb_clear_halt(struct usb_device *dev, int pipe)
{
int result;
int endp = usb_pipeendpoint(pipe);
if (usb_pipein(pipe))
endp |= USB_DIR_IN;
/* we don't care if it wasn't halted first. in fact some devices
* (like some ibmcam model 1 units) seem to expect hosts to make
* this request for iso endpoints, which can't halt!
*/
result = usb_control_msg(dev, usb_sndctrlpipe(dev, 0),
USB_REQ_CLEAR_FEATURE, USB_RECIP_ENDPOINT,
USB_ENDPOINT_HALT, endp, NULL, 0,
USB_CTRL_SET_TIMEOUT);
/* don't un-halt or force to DATA0 except on success */
if (result < 0)
return result;
/* NOTE: seems like Microsoft and Apple don't bother verifying
* the clear "took", so some devices could lock up if you check...
* such as the Hagiwara FlashGate DUAL. So we won't bother.
*
* NOTE: make sure the logic here doesn't diverge much from
* the copy in usb-storage, for as long as we need two copies.
*/
usb_reset_endpoint(dev, endp);
return 0;
}
EXPORT_SYMBOL_GPL(usb_clear_halt);
static int create_intf_ep_devs(struct usb_interface *intf)
{
struct usb_device *udev = interface_to_usbdev(intf);
struct usb_host_interface *alt = intf->cur_altsetting;
int i;
if (intf->ep_devs_created || intf->unregistering)
return 0;
for (i = 0; i < alt->desc.bNumEndpoints; ++i)
(void) usb_create_ep_devs(&intf->dev, &alt->endpoint[i], udev);
intf->ep_devs_created = 1;
return 0;
}
static void remove_intf_ep_devs(struct usb_interface *intf)
{
struct usb_host_interface *alt = intf->cur_altsetting;
int i;
if (!intf->ep_devs_created)
return;
for (i = 0; i < alt->desc.bNumEndpoints; ++i)
usb_remove_ep_devs(&alt->endpoint[i]);
intf->ep_devs_created = 0;
}
/**
* usb_disable_endpoint -- Disable an endpoint by address
* @dev: the device whose endpoint is being disabled
* @epaddr: the endpoint's address. Endpoint number for output,
* endpoint number + USB_DIR_IN for input
* @reset_hardware: flag to erase any endpoint state stored in the
* controller hardware
*
* Disables the endpoint for URB submission and nukes all pending URBs.
* If @reset_hardware is set then also deallocates hcd/hardware state
* for the endpoint.
*/
void usb_disable_endpoint(struct usb_device *dev, unsigned int epaddr,
bool reset_hardware)
{
unsigned int epnum = epaddr & USB_ENDPOINT_NUMBER_MASK;
struct usb_host_endpoint *ep;
if (!dev)
return;
if (usb_endpoint_out(epaddr)) {
ep = dev->ep_out[epnum];
if (reset_hardware)
dev->ep_out[epnum] = NULL;
} else {
ep = dev->ep_in[epnum];
if (reset_hardware)
dev->ep_in[epnum] = NULL;
}
if (ep) {
ep->enabled = 0;
usb_hcd_flush_endpoint(dev, ep);
if (reset_hardware)
usb_hcd_disable_endpoint(dev, ep);
}
}
/**
* usb_reset_endpoint - Reset an endpoint's state.
* @dev: the device whose endpoint is to be reset
* @epaddr: the endpoint's address. Endpoint number for output,
* endpoint number + USB_DIR_IN for input
*
* Resets any host-side endpoint state such as the toggle bit,
* sequence number or current window.
*/
void usb_reset_endpoint(struct usb_device *dev, unsigned int epaddr)
{
unsigned int epnum = epaddr & USB_ENDPOINT_NUMBER_MASK;
struct usb_host_endpoint *ep;
if (usb_endpoint_out(epaddr))
ep = dev->ep_out[epnum];
else
ep = dev->ep_in[epnum];
if (ep)
usb_hcd_reset_endpoint(dev, ep);
}
EXPORT_SYMBOL_GPL(usb_reset_endpoint);
/**
* usb_disable_interface -- Disable all endpoints for an interface
* @dev: the device whose interface is being disabled
* @intf: pointer to the interface descriptor
* @reset_hardware: flag to erase any endpoint state stored in the
* controller hardware
*
* Disables all the endpoints for the interface's current altsetting.
*/
void usb_disable_interface(struct usb_device *dev, struct usb_interface *intf,
bool reset_hardware)
{
struct usb_host_interface *alt = intf->cur_altsetting;
int i;
for (i = 0; i < alt->desc.bNumEndpoints; ++i) {
usb_disable_endpoint(dev,
alt->endpoint[i].desc.bEndpointAddress,
reset_hardware);
}
}
/**
* usb_disable_device - Disable all the endpoints for a USB device
* @dev: the device whose endpoints are being disabled
* @skip_ep0: 0 to disable endpoint 0, 1 to skip it.
*
* Disables all the device's endpoints, potentially including endpoint 0.
* Deallocates hcd/hardware state for the endpoints (nuking all or most
* pending urbs) and usbcore state for the interfaces, so that usbcore
* must usb_set_configuration() before any interfaces could be used.
*/
void usb_disable_device(struct usb_device *dev, int skip_ep0)
{
int i;
USB: Free bandwidth when usb_disable_device is called. Tanya ran into an issue when trying to switch a UAS device from the BOT configuration to the UAS configuration via the bConfigurationValue sysfs file. Before installing the UAS configuration, set_bConfigurationValue() calls usb_disable_device(). That function is supposed to remove all host controller resources associated with that device, but it leaves some state in the xHCI host controller. Commit 0791971ba8fbc44e4f476079f856335ed45e6324 usb: allow drivers to use allocated bandwidth until unbound added a call to usb_disable_device() in usb_set_configuration(), before the xHCI bandwidth functions were invoked. That commit fixed a bug, but also introduced a bug that is triggered when a configured device is switched to a new configuration. usb_disable_device() goes through all the motions of unbinding the drivers attached to active interfaces and removing the USB core structures associated with those interfaces, but it doesn't actually remove the endpoints from the internal xHCI host controller bandwidth structures. When usb_disable_device() calls usb_disable_endpoint() with reset_hardware set to true, the entries in udev->ep_out and udev->ep_in will be set to NULL. Usually, when the USB core installs a new configuration, usb_hcd_alloc_bandwidth() will drop all non-NULL endpoints in udev->ep_out and udev->ep_in before adding any new endpoints. However, when the new UAS configuration was added, all those entries were null, so none of the old endpoints in the BOT configuration were dropped. The xHCI driver blindly added the UAS configuration endpoints, and some of the endpoint addresses overlapped with the old BOT configuration endpoints. This caused the xHCI host to reject the Configure Endpoint command. Now that the xHCI driver code is cleaned up to reject a double-add of active endpoints, we need to fix the USB core to properly drop old endpoints in usb_disable_device(). If the host controller driver needs bandwidth checking support, make usb_disable_device() call usb_disable_endpoint() with reset_hardware set to false, drop the endpoints from the xHCI host controller, and then call usb_disable_endpoint() again with reset_hardware set to true. The first call to usb_disable_endpoint() will cancel any pending URBs and wait on them to be freed in usb_hcd_disable_endpoint(), but will keep the pointers in udev->ep_out and udev->ep in intact. Then usb_hcd_alloc_bandwidth() will use those pointers to know which endpoints to drop. The final call to usb_disable_endpoint() will do two things: 1. It will call usb_hcd_disable_endpoint() again, which should be harmless since the ep->urb_list should be empty after the first call to usb_disable_endpoint() returns. 2. It will set the entries in udev->ep_out and udev->ep in to NULL, and call usb_hcd_disable_endpoint(). That call will have no effect, since the xHCI driver doesn't set the endpoint_disable function pointer. Note that usb_disable_device() will now need to be called with hcd->bandwidth_mutex held. This should be backported to kernels as old as 2.6.32. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Reported-by: Tanya Brokhman <tlinder@codeaurora.org> Cc: ablay@codeaurora.org Cc: Alan Stern <stern@rowland.harvard.edu> Cc: stable@kernel.org
2011-06-06 13:22:22 +07:00
struct usb_hcd *hcd = bus_to_hcd(dev->bus);
/* getting rid of interfaces will disconnect
* any drivers bound to them (a key side effect)
*/
if (dev->actconfig) {
/*
* FIXME: In order to avoid self-deadlock involving the
* bandwidth_mutex, we have to mark all the interfaces
* before unregistering any of them.
*/
for (i = 0; i < dev->actconfig->desc.bNumInterfaces; i++)
dev->actconfig->interface[i]->unregistering = 1;
for (i = 0; i < dev->actconfig->desc.bNumInterfaces; i++) {
struct usb_interface *interface;
/* remove this interface if it has been registered */
interface = dev->actconfig->interface[i];
if (!device_is_registered(&interface->dev))
continue;
dev_dbg(&dev->dev, "unregistering interface %s\n",
dev_name(&interface->dev));
remove_intf_ep_devs(interface);
device_del(&interface->dev);
}
/* Now that the interfaces are unbound, nobody should
* try to access them.
*/
for (i = 0; i < dev->actconfig->desc.bNumInterfaces; i++) {
put_device(&dev->actconfig->interface[i]->dev);
dev->actconfig->interface[i] = NULL;
}
usb_unlocked_disable_lpm(dev);
USB: Enable Latency Tolerance Messaging (LTM). USB 3.0 devices may optionally support a new feature called Latency Tolerance Messaging. If both the xHCI host controller and the device support LTM, it should be turned on in order to give the system hardware a better clue about the latency tolerance values of its PCI devices. Once a Set Feature request to enable LTM is received, the USB 3.0 device will begin to send LTM updates as its buffers fill or empty, and it can tolerate more or less latency. The USB 3.0 spec, section C.4.2 says that LTM should be disabled just before the device is placed into suspend. Then the device will send an updated LTM notification, so that the system doesn't think it should remain in an active state in order to satisfy the latency requirements of the suspended device. The Set and Clear Feature LTM enable command can only be sent to a configured device. The device will respond with an error if that command is sent while it is in the Default or Addressed state. Make sure to check udev->actconfig in usb_enable_ltm() and usb_disable_ltm(), and don't send those commands when the device is unconfigured. LTM should be enabled once a new configuration is installed in usb_set_configuration(). If we end up sending duplicate Set Feature LTM Enable commands on a switch from one installed configuration to another configuration, that should be harmless. Make sure that LTM is disabled before the device is unconfigured in usb_disable_device(). If no drivers are bound to the device, it doesn't make sense to allow the device to control the latency tolerance of the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-06-26 02:08:08 +07:00
usb_disable_ltm(dev);
dev->actconfig = NULL;
if (dev->state == USB_STATE_CONFIGURED)
usb_set_device_state(dev, USB_STATE_ADDRESS);
}
dev_dbg(&dev->dev, "%s nuking %s URBs\n", __func__,
skip_ep0 ? "non-ep0" : "all");
USB: Free bandwidth when usb_disable_device is called. Tanya ran into an issue when trying to switch a UAS device from the BOT configuration to the UAS configuration via the bConfigurationValue sysfs file. Before installing the UAS configuration, set_bConfigurationValue() calls usb_disable_device(). That function is supposed to remove all host controller resources associated with that device, but it leaves some state in the xHCI host controller. Commit 0791971ba8fbc44e4f476079f856335ed45e6324 usb: allow drivers to use allocated bandwidth until unbound added a call to usb_disable_device() in usb_set_configuration(), before the xHCI bandwidth functions were invoked. That commit fixed a bug, but also introduced a bug that is triggered when a configured device is switched to a new configuration. usb_disable_device() goes through all the motions of unbinding the drivers attached to active interfaces and removing the USB core structures associated with those interfaces, but it doesn't actually remove the endpoints from the internal xHCI host controller bandwidth structures. When usb_disable_device() calls usb_disable_endpoint() with reset_hardware set to true, the entries in udev->ep_out and udev->ep_in will be set to NULL. Usually, when the USB core installs a new configuration, usb_hcd_alloc_bandwidth() will drop all non-NULL endpoints in udev->ep_out and udev->ep_in before adding any new endpoints. However, when the new UAS configuration was added, all those entries were null, so none of the old endpoints in the BOT configuration were dropped. The xHCI driver blindly added the UAS configuration endpoints, and some of the endpoint addresses overlapped with the old BOT configuration endpoints. This caused the xHCI host to reject the Configure Endpoint command. Now that the xHCI driver code is cleaned up to reject a double-add of active endpoints, we need to fix the USB core to properly drop old endpoints in usb_disable_device(). If the host controller driver needs bandwidth checking support, make usb_disable_device() call usb_disable_endpoint() with reset_hardware set to false, drop the endpoints from the xHCI host controller, and then call usb_disable_endpoint() again with reset_hardware set to true. The first call to usb_disable_endpoint() will cancel any pending URBs and wait on them to be freed in usb_hcd_disable_endpoint(), but will keep the pointers in udev->ep_out and udev->ep in intact. Then usb_hcd_alloc_bandwidth() will use those pointers to know which endpoints to drop. The final call to usb_disable_endpoint() will do two things: 1. It will call usb_hcd_disable_endpoint() again, which should be harmless since the ep->urb_list should be empty after the first call to usb_disable_endpoint() returns. 2. It will set the entries in udev->ep_out and udev->ep in to NULL, and call usb_hcd_disable_endpoint(). That call will have no effect, since the xHCI driver doesn't set the endpoint_disable function pointer. Note that usb_disable_device() will now need to be called with hcd->bandwidth_mutex held. This should be backported to kernels as old as 2.6.32. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Reported-by: Tanya Brokhman <tlinder@codeaurora.org> Cc: ablay@codeaurora.org Cc: Alan Stern <stern@rowland.harvard.edu> Cc: stable@kernel.org
2011-06-06 13:22:22 +07:00
if (hcd->driver->check_bandwidth) {
/* First pass: Cancel URBs, leave endpoint pointers intact. */
for (i = skip_ep0; i < 16; ++i) {
usb_disable_endpoint(dev, i, false);
usb_disable_endpoint(dev, i + USB_DIR_IN, false);
}
/* Remove endpoints from the host controller internal state */
USB: fix deadlock in bConfigurationValue attribute method This patch (as154) fixes a self-deadlock that occurs when userspace writes to the bConfigurationValue sysfs attribute for a hub with children. The task tries to lock the bandwidth_mutex at a time when it already owns the lock: The attribute's method calls usb_set_configuration(), which calls usb_disable_device() with the bandwidth_mutex held. usb_disable_device() unregisters the existing interfaces, which causes the hub driver to be unbound. The hub_disconnect() routine calls hub_quiesce(), which calls usb_disconnect() for each of the hub's children. usb_disconnect() attempts to acquire the bandwidth_mutex around a call to usb_disable_device(). The solution is to make usb_disable_device() acquire the mutex for itself instead of requiring the caller to hold it. Then the mutex can cover only the bandwidth deallocation operation and not the region where the interfaces are unregistered. This has the potential to change system behavior slightly when a config change races with another config or altsetting change. Some of the bandwidth released from the old config might get claimed by the other config or altsetting, make it impossible to restore the old config in case of a failure. But since we don't try to recover from config-change failures anyway, this doesn't matter. [This should be marked for stable kernels that contain the commit fccf4e86200b8f5edd9a65da26f150e32ba79808 "USB: Free bandwidth when usb_disable_device is called." That commit was marked for stable kernels as old as 2.6.32.] Signed-off-by: Alan Stern <stern@rowland.harvard.edu> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@vger.kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-04-18 02:22:39 +07:00
mutex_lock(hcd->bandwidth_mutex);
USB: Free bandwidth when usb_disable_device is called. Tanya ran into an issue when trying to switch a UAS device from the BOT configuration to the UAS configuration via the bConfigurationValue sysfs file. Before installing the UAS configuration, set_bConfigurationValue() calls usb_disable_device(). That function is supposed to remove all host controller resources associated with that device, but it leaves some state in the xHCI host controller. Commit 0791971ba8fbc44e4f476079f856335ed45e6324 usb: allow drivers to use allocated bandwidth until unbound added a call to usb_disable_device() in usb_set_configuration(), before the xHCI bandwidth functions were invoked. That commit fixed a bug, but also introduced a bug that is triggered when a configured device is switched to a new configuration. usb_disable_device() goes through all the motions of unbinding the drivers attached to active interfaces and removing the USB core structures associated with those interfaces, but it doesn't actually remove the endpoints from the internal xHCI host controller bandwidth structures. When usb_disable_device() calls usb_disable_endpoint() with reset_hardware set to true, the entries in udev->ep_out and udev->ep_in will be set to NULL. Usually, when the USB core installs a new configuration, usb_hcd_alloc_bandwidth() will drop all non-NULL endpoints in udev->ep_out and udev->ep_in before adding any new endpoints. However, when the new UAS configuration was added, all those entries were null, so none of the old endpoints in the BOT configuration were dropped. The xHCI driver blindly added the UAS configuration endpoints, and some of the endpoint addresses overlapped with the old BOT configuration endpoints. This caused the xHCI host to reject the Configure Endpoint command. Now that the xHCI driver code is cleaned up to reject a double-add of active endpoints, we need to fix the USB core to properly drop old endpoints in usb_disable_device(). If the host controller driver needs bandwidth checking support, make usb_disable_device() call usb_disable_endpoint() with reset_hardware set to false, drop the endpoints from the xHCI host controller, and then call usb_disable_endpoint() again with reset_hardware set to true. The first call to usb_disable_endpoint() will cancel any pending URBs and wait on them to be freed in usb_hcd_disable_endpoint(), but will keep the pointers in udev->ep_out and udev->ep in intact. Then usb_hcd_alloc_bandwidth() will use those pointers to know which endpoints to drop. The final call to usb_disable_endpoint() will do two things: 1. It will call usb_hcd_disable_endpoint() again, which should be harmless since the ep->urb_list should be empty after the first call to usb_disable_endpoint() returns. 2. It will set the entries in udev->ep_out and udev->ep in to NULL, and call usb_hcd_disable_endpoint(). That call will have no effect, since the xHCI driver doesn't set the endpoint_disable function pointer. Note that usb_disable_device() will now need to be called with hcd->bandwidth_mutex held. This should be backported to kernels as old as 2.6.32. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Reported-by: Tanya Brokhman <tlinder@codeaurora.org> Cc: ablay@codeaurora.org Cc: Alan Stern <stern@rowland.harvard.edu> Cc: stable@kernel.org
2011-06-06 13:22:22 +07:00
usb_hcd_alloc_bandwidth(dev, NULL, NULL, NULL);
USB: fix deadlock in bConfigurationValue attribute method This patch (as154) fixes a self-deadlock that occurs when userspace writes to the bConfigurationValue sysfs attribute for a hub with children. The task tries to lock the bandwidth_mutex at a time when it already owns the lock: The attribute's method calls usb_set_configuration(), which calls usb_disable_device() with the bandwidth_mutex held. usb_disable_device() unregisters the existing interfaces, which causes the hub driver to be unbound. The hub_disconnect() routine calls hub_quiesce(), which calls usb_disconnect() for each of the hub's children. usb_disconnect() attempts to acquire the bandwidth_mutex around a call to usb_disable_device(). The solution is to make usb_disable_device() acquire the mutex for itself instead of requiring the caller to hold it. Then the mutex can cover only the bandwidth deallocation operation and not the region where the interfaces are unregistered. This has the potential to change system behavior slightly when a config change races with another config or altsetting change. Some of the bandwidth released from the old config might get claimed by the other config or altsetting, make it impossible to restore the old config in case of a failure. But since we don't try to recover from config-change failures anyway, this doesn't matter. [This should be marked for stable kernels that contain the commit fccf4e86200b8f5edd9a65da26f150e32ba79808 "USB: Free bandwidth when usb_disable_device is called." That commit was marked for stable kernels as old as 2.6.32.] Signed-off-by: Alan Stern <stern@rowland.harvard.edu> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@vger.kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-04-18 02:22:39 +07:00
mutex_unlock(hcd->bandwidth_mutex);
USB: Free bandwidth when usb_disable_device is called. Tanya ran into an issue when trying to switch a UAS device from the BOT configuration to the UAS configuration via the bConfigurationValue sysfs file. Before installing the UAS configuration, set_bConfigurationValue() calls usb_disable_device(). That function is supposed to remove all host controller resources associated with that device, but it leaves some state in the xHCI host controller. Commit 0791971ba8fbc44e4f476079f856335ed45e6324 usb: allow drivers to use allocated bandwidth until unbound added a call to usb_disable_device() in usb_set_configuration(), before the xHCI bandwidth functions were invoked. That commit fixed a bug, but also introduced a bug that is triggered when a configured device is switched to a new configuration. usb_disable_device() goes through all the motions of unbinding the drivers attached to active interfaces and removing the USB core structures associated with those interfaces, but it doesn't actually remove the endpoints from the internal xHCI host controller bandwidth structures. When usb_disable_device() calls usb_disable_endpoint() with reset_hardware set to true, the entries in udev->ep_out and udev->ep_in will be set to NULL. Usually, when the USB core installs a new configuration, usb_hcd_alloc_bandwidth() will drop all non-NULL endpoints in udev->ep_out and udev->ep_in before adding any new endpoints. However, when the new UAS configuration was added, all those entries were null, so none of the old endpoints in the BOT configuration were dropped. The xHCI driver blindly added the UAS configuration endpoints, and some of the endpoint addresses overlapped with the old BOT configuration endpoints. This caused the xHCI host to reject the Configure Endpoint command. Now that the xHCI driver code is cleaned up to reject a double-add of active endpoints, we need to fix the USB core to properly drop old endpoints in usb_disable_device(). If the host controller driver needs bandwidth checking support, make usb_disable_device() call usb_disable_endpoint() with reset_hardware set to false, drop the endpoints from the xHCI host controller, and then call usb_disable_endpoint() again with reset_hardware set to true. The first call to usb_disable_endpoint() will cancel any pending URBs and wait on them to be freed in usb_hcd_disable_endpoint(), but will keep the pointers in udev->ep_out and udev->ep in intact. Then usb_hcd_alloc_bandwidth() will use those pointers to know which endpoints to drop. The final call to usb_disable_endpoint() will do two things: 1. It will call usb_hcd_disable_endpoint() again, which should be harmless since the ep->urb_list should be empty after the first call to usb_disable_endpoint() returns. 2. It will set the entries in udev->ep_out and udev->ep in to NULL, and call usb_hcd_disable_endpoint(). That call will have no effect, since the xHCI driver doesn't set the endpoint_disable function pointer. Note that usb_disable_device() will now need to be called with hcd->bandwidth_mutex held. This should be backported to kernels as old as 2.6.32. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Reported-by: Tanya Brokhman <tlinder@codeaurora.org> Cc: ablay@codeaurora.org Cc: Alan Stern <stern@rowland.harvard.edu> Cc: stable@kernel.org
2011-06-06 13:22:22 +07:00
/* Second pass: remove endpoint pointers */
}
for (i = skip_ep0; i < 16; ++i) {
usb_disable_endpoint(dev, i, true);
usb_disable_endpoint(dev, i + USB_DIR_IN, true);
}
}
/**
* usb_enable_endpoint - Enable an endpoint for USB communications
* @dev: the device whose interface is being enabled
* @ep: the endpoint
* @reset_ep: flag to reset the endpoint state
*
* Resets the endpoint state if asked, and sets dev->ep_{in,out} pointers.
* For control endpoints, both the input and output sides are handled.
*/
void usb_enable_endpoint(struct usb_device *dev, struct usb_host_endpoint *ep,
bool reset_ep)
{
int epnum = usb_endpoint_num(&ep->desc);
int is_out = usb_endpoint_dir_out(&ep->desc);
int is_control = usb_endpoint_xfer_control(&ep->desc);
if (reset_ep)
usb_hcd_reset_endpoint(dev, ep);
if (is_out || is_control)
dev->ep_out[epnum] = ep;
if (!is_out || is_control)
dev->ep_in[epnum] = ep;
ep->enabled = 1;
}
/**
* usb_enable_interface - Enable all the endpoints for an interface
* @dev: the device whose interface is being enabled
* @intf: pointer to the interface descriptor
* @reset_eps: flag to reset the endpoints' state
*
* Enables all the endpoints for the interface's current altsetting.
*/
void usb_enable_interface(struct usb_device *dev,
struct usb_interface *intf, bool reset_eps)
{
struct usb_host_interface *alt = intf->cur_altsetting;
int i;
for (i = 0; i < alt->desc.bNumEndpoints; ++i)
usb_enable_endpoint(dev, &alt->endpoint[i], reset_eps);
}
/**
* usb_set_interface - Makes a particular alternate setting be current
* @dev: the device whose interface is being updated
* @interface: the interface being updated
* @alternate: the setting being chosen.
* Context: !in_interrupt ()
*
* This is used to enable data transfers on interfaces that may not
* be enabled by default. Not all devices support such configurability.
* Only the driver bound to an interface may change its setting.
*
* Within any given configuration, each interface may have several
* alternative settings. These are often used to control levels of
* bandwidth consumption. For example, the default setting for a high
* speed interrupt endpoint may not send more than 64 bytes per microframe,
* while interrupt transfers of up to 3KBytes per microframe are legal.
* Also, isochronous endpoints may never be part of an
* interface's default setting. To access such bandwidth, alternate
* interface settings must be made current.
*
* Note that in the Linux USB subsystem, bandwidth associated with
* an endpoint in a given alternate setting is not reserved until an URB
* is submitted that needs that bandwidth. Some other operating systems
* allocate bandwidth early, when a configuration is chosen.
*
* This call is synchronous, and may not be used in an interrupt context.
* Also, drivers must not change altsettings while urbs are scheduled for
* endpoints in that interface; all such urbs must first be completed
* (perhaps forced by unlinking).
*
* Returns zero on success, or else the status code returned by the
* underlying usb_control_msg() call.
*/
int usb_set_interface(struct usb_device *dev, int interface, int alternate)
{
struct usb_interface *iface;
struct usb_host_interface *alt;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
struct usb_hcd *hcd = bus_to_hcd(dev->bus);
int ret;
int manual = 0;
unsigned int epaddr;
unsigned int pipe;
if (dev->state == USB_STATE_SUSPENDED)
return -EHOSTUNREACH;
iface = usb_ifnum_to_if(dev, interface);
if (!iface) {
dev_dbg(&dev->dev, "selecting invalid interface %d\n",
interface);
return -EINVAL;
}
if (iface->unregistering)
return -ENODEV;
alt = usb_altnum_to_altsetting(iface, alternate);
if (!alt) {
dev_warn(&dev->dev, "selecting invalid altsetting %d\n",
alternate);
return -EINVAL;
}
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
/* Make sure we have enough bandwidth for this alternate interface.
* Remove the current alt setting and add the new alt setting.
*/
mutex_lock(hcd->bandwidth_mutex);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Disable LPM, and re-enable it once the new alt setting is installed,
* so that the xHCI driver can recalculate the U1/U2 timeouts.
*/
if (usb_disable_lpm(dev)) {
dev_err(&iface->dev, "%s Failed to disable LPM\n.", __func__);
mutex_unlock(hcd->bandwidth_mutex);
return -ENOMEM;
}
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
ret = usb_hcd_alloc_bandwidth(dev, NULL, iface->cur_altsetting, alt);
if (ret < 0) {
dev_info(&dev->dev, "Not enough bandwidth for altsetting %d\n",
alternate);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
usb_enable_lpm(dev);
mutex_unlock(hcd->bandwidth_mutex);
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
return ret;
}
if (dev->quirks & USB_QUIRK_NO_SET_INTF)
ret = -EPIPE;
else
ret = usb_control_msg(dev, usb_sndctrlpipe(dev, 0),
USB_REQ_SET_INTERFACE, USB_RECIP_INTERFACE,
alternate, interface, NULL, 0, 5000);
/* 9.4.10 says devices don't need this and are free to STALL the
* request if the interface only has one alternate setting.
*/
if (ret == -EPIPE && iface->num_altsetting == 1) {
dev_dbg(&dev->dev,
"manual set_interface for iface %d, alt %d\n",
interface, alternate);
manual = 1;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
} else if (ret < 0) {
/* Re-instate the old alt setting */
usb_hcd_alloc_bandwidth(dev, NULL, alt, iface->cur_altsetting);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
usb_enable_lpm(dev);
mutex_unlock(hcd->bandwidth_mutex);
return ret;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
}
mutex_unlock(hcd->bandwidth_mutex);
/* FIXME drivers shouldn't need to replicate/bugfix the logic here
* when they implement async or easily-killable versions of this or
* other "should-be-internal" functions (like clear_halt).
* should hcd+usbcore postprocess control requests?
*/
/* prevent submissions using previous endpoint settings */
if (iface->cur_altsetting != alt) {
remove_intf_ep_devs(iface);
usb_remove_sysfs_intf_files(iface);
}
usb_disable_interface(dev, iface, true);
iface->cur_altsetting = alt;
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Now that the interface is installed, re-enable LPM. */
usb_unlocked_enable_lpm(dev);
/* If the interface only has one altsetting and the device didn't
* accept the request, we attempt to carry out the equivalent action
* by manually clearing the HALT feature for each endpoint in the
* new altsetting.
*/
if (manual) {
int i;
for (i = 0; i < alt->desc.bNumEndpoints; i++) {
epaddr = alt->endpoint[i].desc.bEndpointAddress;
pipe = __create_pipe(dev,
USB_ENDPOINT_NUMBER_MASK & epaddr) |
(usb_endpoint_out(epaddr) ?
USB_DIR_OUT : USB_DIR_IN);
usb_clear_halt(dev, pipe);
}
}
/* 9.1.1.5: reset toggles for all endpoints in the new altsetting
*
* Note:
* Despite EP0 is always present in all interfaces/AS, the list of
* endpoints from the descriptor does not contain EP0. Due to its
* omnipresence one might expect EP0 being considered "affected" by
* any SetInterface request and hence assume toggles need to be reset.
* However, EP0 toggles are re-synced for every individual transfer
* during the SETUP stage - hence EP0 toggles are "don't care" here.
* (Likewise, EP0 never "halts" on well designed devices.)
*/
usb_enable_interface(dev, iface, true);
if (device_is_registered(&iface->dev)) {
usb_create_sysfs_intf_files(iface);
create_intf_ep_devs(iface);
}
return 0;
}
EXPORT_SYMBOL_GPL(usb_set_interface);
/**
* usb_reset_configuration - lightweight device reset
* @dev: the device whose configuration is being reset
*
* This issues a standard SET_CONFIGURATION request to the device using
* the current configuration. The effect is to reset most USB-related
* state in the device, including interface altsettings (reset to zero),
* endpoint halts (cleared), and endpoint state (only for bulk and interrupt
* endpoints). Other usbcore state is unchanged, including bindings of
* usb device drivers to interfaces.
*
* Because this affects multiple interfaces, avoid using this with composite
* (multi-interface) devices. Instead, the driver for each interface may
* use usb_set_interface() on the interfaces it claims. Be careful though;
* some devices don't support the SET_INTERFACE request, and others won't
* reset all the interface state (notably endpoint state). Resetting the whole
* configuration would affect other drivers' interfaces.
*
* The caller must own the device lock.
*
* Returns zero on success, else a negative error code.
*/
int usb_reset_configuration(struct usb_device *dev)
{
int i, retval;
struct usb_host_config *config;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
struct usb_hcd *hcd = bus_to_hcd(dev->bus);
if (dev->state == USB_STATE_SUSPENDED)
return -EHOSTUNREACH;
/* caller must have locked the device and must own
* the usb bus readlock (so driver bindings are stable);
* calls during probe() are fine
*/
for (i = 1; i < 16; ++i) {
usb_disable_endpoint(dev, i, true);
usb_disable_endpoint(dev, i + USB_DIR_IN, true);
}
config = dev->actconfig;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
retval = 0;
mutex_lock(hcd->bandwidth_mutex);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Disable LPM, and re-enable it once the configuration is reset, so
* that the xHCI driver can recalculate the U1/U2 timeouts.
*/
if (usb_disable_lpm(dev)) {
dev_err(&dev->dev, "%s Failed to disable LPM\n.", __func__);
mutex_unlock(hcd->bandwidth_mutex);
return -ENOMEM;
}
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
/* Make sure we have enough bandwidth for each alternate setting 0 */
for (i = 0; i < config->desc.bNumInterfaces; i++) {
struct usb_interface *intf = config->interface[i];
struct usb_host_interface *alt;
alt = usb_altnum_to_altsetting(intf, 0);
if (!alt)
alt = &intf->altsetting[0];
if (alt != intf->cur_altsetting)
retval = usb_hcd_alloc_bandwidth(dev, NULL,
intf->cur_altsetting, alt);
if (retval < 0)
break;
}
/* If not, reinstate the old alternate settings */
if (retval < 0) {
reset_old_alts:
for (i--; i >= 0; i--) {
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
struct usb_interface *intf = config->interface[i];
struct usb_host_interface *alt;
alt = usb_altnum_to_altsetting(intf, 0);
if (!alt)
alt = &intf->altsetting[0];
if (alt != intf->cur_altsetting)
usb_hcd_alloc_bandwidth(dev, NULL,
alt, intf->cur_altsetting);
}
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
usb_enable_lpm(dev);
mutex_unlock(hcd->bandwidth_mutex);
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
return retval;
}
retval = usb_control_msg(dev, usb_sndctrlpipe(dev, 0),
USB_REQ_SET_CONFIGURATION, 0,
config->desc.bConfigurationValue, 0,
NULL, 0, USB_CTRL_SET_TIMEOUT);
if (retval < 0)
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
goto reset_old_alts;
mutex_unlock(hcd->bandwidth_mutex);
/* re-init hc/hcd interface/endpoint state */
for (i = 0; i < config->desc.bNumInterfaces; i++) {
struct usb_interface *intf = config->interface[i];
struct usb_host_interface *alt;
alt = usb_altnum_to_altsetting(intf, 0);
/* No altsetting 0? We'll assume the first altsetting.
* We could use a GetInterface call, but if a device is
* so non-compliant that it doesn't have altsetting 0
* then I wouldn't trust its reply anyway.
*/
if (!alt)
alt = &intf->altsetting[0];
if (alt != intf->cur_altsetting) {
remove_intf_ep_devs(intf);
usb_remove_sysfs_intf_files(intf);
}
intf->cur_altsetting = alt;
usb_enable_interface(dev, intf, true);
if (device_is_registered(&intf->dev)) {
usb_create_sysfs_intf_files(intf);
create_intf_ep_devs(intf);
}
}
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Now that the interfaces are installed, re-enable LPM. */
usb_unlocked_enable_lpm(dev);
return 0;
}
EXPORT_SYMBOL_GPL(usb_reset_configuration);
static void usb_release_interface(struct device *dev)
{
struct usb_interface *intf = to_usb_interface(dev);
struct usb_interface_cache *intfc =
altsetting_to_usb_interface_cache(intf->altsetting);
kref_put(&intfc->ref, usb_release_interface_cache);
kfree(intf);
}
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
#ifdef CONFIG_HOTPLUG
static int usb_if_uevent(struct device *dev, struct kobj_uevent_env *env)
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
{
struct usb_device *usb_dev;
struct usb_interface *intf;
struct usb_host_interface *alt;
intf = to_usb_interface(dev);
usb_dev = interface_to_usbdev(intf);
alt = intf->cur_altsetting;
if (add_uevent_var(env, "INTERFACE=%d/%d/%d",
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
alt->desc.bInterfaceClass,
alt->desc.bInterfaceSubClass,
alt->desc.bInterfaceProtocol))
return -ENOMEM;
if (add_uevent_var(env,
"MODALIAS=usb:"
"v%04Xp%04Xd%04Xdc%02Xdsc%02Xdp%02Xic%02Xisc%02Xip%02Xin%02X",
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
le16_to_cpu(usb_dev->descriptor.idVendor),
le16_to_cpu(usb_dev->descriptor.idProduct),
le16_to_cpu(usb_dev->descriptor.bcdDevice),
usb_dev->descriptor.bDeviceClass,
usb_dev->descriptor.bDeviceSubClass,
usb_dev->descriptor.bDeviceProtocol,
alt->desc.bInterfaceClass,
alt->desc.bInterfaceSubClass,
alt->desc.bInterfaceProtocol,
alt->desc.bInterfaceNumber))
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
return -ENOMEM;
return 0;
}
#else
static int usb_if_uevent(struct device *dev, struct kobj_uevent_env *env)
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
{
return -ENODEV;
}
#endif /* CONFIG_HOTPLUG */
struct device_type usb_if_device_type = {
.name = "usb_interface",
.release = usb_release_interface,
.uevent = usb_if_uevent,
};
static struct usb_interface_assoc_descriptor *find_iad(struct usb_device *dev,
struct usb_host_config *config,
u8 inum)
{
struct usb_interface_assoc_descriptor *retval = NULL;
struct usb_interface_assoc_descriptor *intf_assoc;
int first_intf;
int last_intf;
int i;
for (i = 0; (i < USB_MAXIADS && config->intf_assoc[i]); i++) {
intf_assoc = config->intf_assoc[i];
if (intf_assoc->bInterfaceCount == 0)
continue;
first_intf = intf_assoc->bFirstInterface;
last_intf = first_intf + (intf_assoc->bInterfaceCount - 1);
if (inum >= first_intf && inum <= last_intf) {
if (!retval)
retval = intf_assoc;
else
dev_err(&dev->dev, "Interface #%d referenced"
" by multiple IADs\n", inum);
}
}
return retval;
}
/*
* Internal function to queue a device reset
*
* This is initialized into the workstruct in 'struct
* usb_device->reset_ws' that is launched by
* message.c:usb_set_configuration() when initializing each 'struct
* usb_interface'.
*
* It is safe to get the USB device without reference counts because
* the life cycle of @iface is bound to the life cycle of @udev. Then,
* this function will be ran only if @iface is alive (and before
* freeing it any scheduled instances of it will have been cancelled).
*
* We need to set a flag (usb_dev->reset_running) because when we call
* the reset, the interfaces might be unbound. The current interface
* cannot try to remove the queued work as it would cause a deadlock
* (you cannot remove your work from within your executing
* workqueue). This flag lets it know, so that
* usb_cancel_queued_reset() doesn't try to do it.
*
* See usb_queue_reset_device() for more details
*/
static void __usb_queue_reset_device(struct work_struct *ws)
{
int rc;
struct usb_interface *iface =
container_of(ws, struct usb_interface, reset_ws);
struct usb_device *udev = interface_to_usbdev(iface);
rc = usb_lock_device_for_reset(udev, iface);
if (rc >= 0) {
iface->reset_running = 1;
usb_reset_device(udev);
iface->reset_running = 0;
usb_unlock_device(udev);
}
}
/*
* usb_set_configuration - Makes a particular device setting be current
* @dev: the device whose configuration is being updated
* @configuration: the configuration being chosen.
* Context: !in_interrupt(), caller owns the device lock
*
* This is used to enable non-default device modes. Not all devices
* use this kind of configurability; many devices only have one
* configuration.
*
* @configuration is the value of the configuration to be installed.
* According to the USB spec (e.g. section 9.1.1.5), configuration values
* must be non-zero; a value of zero indicates that the device in
* unconfigured. However some devices erroneously use 0 as one of their
* configuration values. To help manage such devices, this routine will
* accept @configuration = -1 as indicating the device should be put in
* an unconfigured state.
*
* USB device configurations may affect Linux interoperability,
* power consumption and the functionality available. For example,
* the default configuration is limited to using 100mA of bus power,
* so that when certain device functionality requires more power,
* and the device is bus powered, that functionality should be in some
* non-default device configuration. Other device modes may also be
* reflected as configuration options, such as whether two ISDN
* channels are available independently; and choosing between open
* standard device protocols (like CDC) or proprietary ones.
*
* Note that a non-authorized device (dev->authorized == 0) will only
* be put in unconfigured mode.
*
* Note that USB has an additional level of device configurability,
* associated with interfaces. That configurability is accessed using
* usb_set_interface().
*
* This call is synchronous. The calling context must be able to sleep,
* must own the device lock, and must not hold the driver model's USB
* bus mutex; usb interface driver probe() methods cannot use this routine.
*
* Returns zero on success, or else the status code returned by the
* underlying call that failed. On successful completion, each interface
* in the original device configuration has been destroyed, and each one
* in the new configuration has been probed by all relevant usb device
* drivers currently known to the kernel.
*/
int usb_set_configuration(struct usb_device *dev, int configuration)
{
int i, ret;
struct usb_host_config *cp = NULL;
struct usb_interface **new_interfaces = NULL;
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
struct usb_hcd *hcd = bus_to_hcd(dev->bus);
int n, nintf;
if (dev->authorized == 0 || configuration == -1)
configuration = 0;
else {
for (i = 0; i < dev->descriptor.bNumConfigurations; i++) {
if (dev->config[i].desc.bConfigurationValue ==
configuration) {
cp = &dev->config[i];
break;
}
}
}
if ((!cp && configuration != 0))
return -EINVAL;
/* The USB spec says configuration 0 means unconfigured.
* But if a device includes a configuration numbered 0,
* we will accept it as a correctly configured state.
* Use -1 if you really want to unconfigure the device.
*/
if (cp && configuration == 0)
dev_warn(&dev->dev, "config 0 descriptor??\n");
/* Allocate memory for new interfaces before doing anything else,
* so that if we run out then nothing will have changed. */
n = nintf = 0;
if (cp) {
nintf = cp->desc.bNumInterfaces;
new_interfaces = kmalloc(nintf * sizeof(*new_interfaces),
GFP_NOIO);
if (!new_interfaces) {
dev_err(&dev->dev, "Out of memory\n");
return -ENOMEM;
}
for (; n < nintf; ++n) {
new_interfaces[n] = kzalloc(
sizeof(struct usb_interface),
GFP_NOIO);
if (!new_interfaces[n]) {
dev_err(&dev->dev, "Out of memory\n");
ret = -ENOMEM;
free_interfaces:
while (--n >= 0)
kfree(new_interfaces[n]);
kfree(new_interfaces);
return ret;
}
}
i = dev->bus_mA - cp->desc.bMaxPower * 2;
if (i < 0)
dev_warn(&dev->dev, "new config #%d exceeds power "
"limit by %dmA\n",
configuration, -i);
}
[PATCH] USB: Consider power budget when choosing configuration This patch (as609) changes the way we keep track of power budgeting for USB hubs and devices, and it updates the choose_configuration routine to take this information into account. (This is something we should have been doing all along.) A new field in struct usb_device holds the amount of bus current available from the upstream port, and the usb_hub structure keeps track of the current available for each downstream port. Two new rules for configuration selection are added: Don't select a self-powered configuration when only bus power is available. Don't select a configuration requiring more bus power than is available. However the first rule is #if-ed out, because I found that the internal hub in my HP USB keyboard claims that its only configuration is self-powered. The rule would prevent the configuration from being chosen, leaving the hub & keyboard unconfigured. Since similar descriptor errors may turn out to be fairly common, it seemed wise not to include a rule that would break automatic configuration unnecessarily for such devices. The second rule may also trigger unnecessarily, although this should be less common. More likely it will annoy people by sometimes failing to accept configurations that should never have been chosen in the first place. The patch also changes usbcore's reaction when no configuration is suitable. Instead of raising an error and rejecting the device, now the core will simply leave the device unconfigured. People can always work around such problems by installing configurations manually through sysfs. Signed-off-by: Alan Stern <stern@rowland.harvard.edu> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2005-11-24 00:03:12 +07:00
/* Wake up the device so we can send it the Set-Config request */
ret = usb_autoresume_device(dev);
if (ret)
goto free_interfaces;
/* if it's already configured, clear out old state first.
* getting rid of old interfaces means unbinding their drivers.
*/
if (dev->state != USB_STATE_ADDRESS)
usb_disable_device(dev, 1); /* Skip ep0 */
/* Get rid of pending async Set-Config requests for this device */
cancel_async_set_config(dev);
USB: Support for bandwidth allocation. Originally, the USB core had no support for allocating bandwidth when a particular configuration or alternate setting for an interface was selected. Instead, the device driver's URB submission would fail if there was not enough bandwidth for a periodic endpoint. Drivers could work around this, by using the scatter-gather list API to guarantee bandwidth. This patch adds host controller API to allow the USB core to allocate or deallocate bandwidth for an endpoint. Endpoints are added to or dropped from a copy of the current schedule by calling add_endpoint() or drop_endpoint(), and then the schedule is atomically evaluated with a call to check_bandwidth(). This allows all the endpoints for a new configuration or alternate setting to be added at the same time that the endpoints from the old configuration or alt setting are dropped. Endpoints must be added to the schedule before any URBs are submitted to them. The HCD must be allowed to reject a new configuration or alt setting before the control transfer is sent to the device requesting the change. It may reject the change because there is not enough bandwidth, not enough internal resources (such as memory on an embedded host controller), or perhaps even for security reasons in a virtualized environment. If the call to check_bandwidth() fails, the USB core must call reset_bandwidth(). This causes the schedule to be reverted back to the state it was in just after the last successful check_bandwidth() call. If the call succeeds, the host controller driver (and hardware) will have changed its internal state to match the new configuration or alternate setting. The USB core can then issue a control transfer to the device to change the configuration or alt setting. This allows the core to test new configurations or alternate settings before unbinding drivers bound to interfaces in the old configuration. WIP: The USB core must add endpoints from all interfaces in a configuration to the schedule, because a driver may claim that interface at any time. A slight optimization might be to add the endpoints to the schedule once a driver claims that interface. FIXME This patch does not cover changing alternate settings, but it does handle a configuration change or de-configuration. FIXME The code for managing the schedule is currently HCD specific. A generic scheduling algorithm could be added for host controllers without built-in scheduling support. For now, if a host controller does not define the check_bandwidth() function, the call to usb_hcd_check_bandwidth() will always succeed. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:58:26 +07:00
/* Make sure we have bandwidth (and available HCD resources) for this
* configuration. Remove endpoints from the schedule if we're dropping
* this configuration to set configuration 0. After this point, the
* host controller will not allow submissions to dropped endpoints. If
* this call fails, the device state is unchanged.
*/
USB: fix deadlock in bConfigurationValue attribute method This patch (as154) fixes a self-deadlock that occurs when userspace writes to the bConfigurationValue sysfs attribute for a hub with children. The task tries to lock the bandwidth_mutex at a time when it already owns the lock: The attribute's method calls usb_set_configuration(), which calls usb_disable_device() with the bandwidth_mutex held. usb_disable_device() unregisters the existing interfaces, which causes the hub driver to be unbound. The hub_disconnect() routine calls hub_quiesce(), which calls usb_disconnect() for each of the hub's children. usb_disconnect() attempts to acquire the bandwidth_mutex around a call to usb_disable_device(). The solution is to make usb_disable_device() acquire the mutex for itself instead of requiring the caller to hold it. Then the mutex can cover only the bandwidth deallocation operation and not the region where the interfaces are unregistered. This has the potential to change system behavior slightly when a config change races with another config or altsetting change. Some of the bandwidth released from the old config might get claimed by the other config or altsetting, make it impossible to restore the old config in case of a failure. But since we don't try to recover from config-change failures anyway, this doesn't matter. [This should be marked for stable kernels that contain the commit fccf4e86200b8f5edd9a65da26f150e32ba79808 "USB: Free bandwidth when usb_disable_device is called." That commit was marked for stable kernels as old as 2.6.32.] Signed-off-by: Alan Stern <stern@rowland.harvard.edu> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@vger.kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-04-18 02:22:39 +07:00
mutex_lock(hcd->bandwidth_mutex);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Disable LPM, and re-enable it once the new configuration is
* installed, so that the xHCI driver can recalculate the U1/U2
* timeouts.
*/
if (dev->actconfig && usb_disable_lpm(dev)) {
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
dev_err(&dev->dev, "%s Failed to disable LPM\n.", __func__);
mutex_unlock(hcd->bandwidth_mutex);
return -ENOMEM;
}
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
ret = usb_hcd_alloc_bandwidth(dev, cp, NULL, NULL);
USB: Support for bandwidth allocation. Originally, the USB core had no support for allocating bandwidth when a particular configuration or alternate setting for an interface was selected. Instead, the device driver's URB submission would fail if there was not enough bandwidth for a periodic endpoint. Drivers could work around this, by using the scatter-gather list API to guarantee bandwidth. This patch adds host controller API to allow the USB core to allocate or deallocate bandwidth for an endpoint. Endpoints are added to or dropped from a copy of the current schedule by calling add_endpoint() or drop_endpoint(), and then the schedule is atomically evaluated with a call to check_bandwidth(). This allows all the endpoints for a new configuration or alternate setting to be added at the same time that the endpoints from the old configuration or alt setting are dropped. Endpoints must be added to the schedule before any URBs are submitted to them. The HCD must be allowed to reject a new configuration or alt setting before the control transfer is sent to the device requesting the change. It may reject the change because there is not enough bandwidth, not enough internal resources (such as memory on an embedded host controller), or perhaps even for security reasons in a virtualized environment. If the call to check_bandwidth() fails, the USB core must call reset_bandwidth(). This causes the schedule to be reverted back to the state it was in just after the last successful check_bandwidth() call. If the call succeeds, the host controller driver (and hardware) will have changed its internal state to match the new configuration or alternate setting. The USB core can then issue a control transfer to the device to change the configuration or alt setting. This allows the core to test new configurations or alternate settings before unbinding drivers bound to interfaces in the old configuration. WIP: The USB core must add endpoints from all interfaces in a configuration to the schedule, because a driver may claim that interface at any time. A slight optimization might be to add the endpoints to the schedule once a driver claims that interface. FIXME This patch does not cover changing alternate settings, but it does handle a configuration change or de-configuration. FIXME The code for managing the schedule is currently HCD specific. A generic scheduling algorithm could be added for host controllers without built-in scheduling support. For now, if a host controller does not define the check_bandwidth() function, the call to usb_hcd_check_bandwidth() will always succeed. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:58:26 +07:00
if (ret < 0) {
if (dev->actconfig)
usb_enable_lpm(dev);
mutex_unlock(hcd->bandwidth_mutex);
usb_autosuspend_device(dev);
USB: Support for bandwidth allocation. Originally, the USB core had no support for allocating bandwidth when a particular configuration or alternate setting for an interface was selected. Instead, the device driver's URB submission would fail if there was not enough bandwidth for a periodic endpoint. Drivers could work around this, by using the scatter-gather list API to guarantee bandwidth. This patch adds host controller API to allow the USB core to allocate or deallocate bandwidth for an endpoint. Endpoints are added to or dropped from a copy of the current schedule by calling add_endpoint() or drop_endpoint(), and then the schedule is atomically evaluated with a call to check_bandwidth(). This allows all the endpoints for a new configuration or alternate setting to be added at the same time that the endpoints from the old configuration or alt setting are dropped. Endpoints must be added to the schedule before any URBs are submitted to them. The HCD must be allowed to reject a new configuration or alt setting before the control transfer is sent to the device requesting the change. It may reject the change because there is not enough bandwidth, not enough internal resources (such as memory on an embedded host controller), or perhaps even for security reasons in a virtualized environment. If the call to check_bandwidth() fails, the USB core must call reset_bandwidth(). This causes the schedule to be reverted back to the state it was in just after the last successful check_bandwidth() call. If the call succeeds, the host controller driver (and hardware) will have changed its internal state to match the new configuration or alternate setting. The USB core can then issue a control transfer to the device to change the configuration or alt setting. This allows the core to test new configurations or alternate settings before unbinding drivers bound to interfaces in the old configuration. WIP: The USB core must add endpoints from all interfaces in a configuration to the schedule, because a driver may claim that interface at any time. A slight optimization might be to add the endpoints to the schedule once a driver claims that interface. FIXME This patch does not cover changing alternate settings, but it does handle a configuration change or de-configuration. FIXME The code for managing the schedule is currently HCD specific. A generic scheduling algorithm could be added for host controllers without built-in scheduling support. For now, if a host controller does not define the check_bandwidth() function, the call to usb_hcd_check_bandwidth() will always succeed. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 09:58:26 +07:00
goto free_interfaces;
}
ret = usb_control_msg(dev, usb_sndctrlpipe(dev, 0),
USB_REQ_SET_CONFIGURATION, 0, configuration, 0,
NULL, 0, USB_CTRL_SET_TIMEOUT);
if (ret < 0) {
/* All the old state is gone, so what else can we do?
* The device is probably useless now anyway.
*/
cp = NULL;
}
dev->actconfig = cp;
if (!cp) {
usb_set_device_state(dev, USB_STATE_ADDRESS);
USB: Check bandwidth when switching alt settings. Make the USB core check the bandwidth when switching from one interface alternate setting to another. Also check the bandwidth when resetting a configuration (so that alt setting 0 is used). If this check fails, the device's state is unchanged. If the device refuses the new alt setting, re-instate the old alt setting in the host controller hardware. If a USB device doesn't have an alternate interface setting 0, install the first alt setting in its descriptors when a new configuration is requested, or the device is reset. Add a mutex per root hub to protect bandwidth operations: adding/reseting/changing configurations, and changing alternate interface settings. We want to ensure that the xHCI host controller and the USB device are set up for the same configurations and alternate settings. There are two (possibly three) steps to do this: 1. The host controller needs to check that bandwidth is available for a different setting, by issuing and waiting for a configure endpoint command. 2. Once that returns successfully, a control message is sent to the device. 3. If that fails, the host controller must be notified through another configure endpoint command. The mutex is used to make these three operations seem atomic, to prevent another driver from using more bandwidth for a different device while we're in the middle of these operations. While we're touching the bandwidth code, rename usb_hcd_check_bandwidth() to usb_hcd_alloc_bandwidth(). This function does more than just check that the bandwidth change won't exceed the bus bandwidth; it actually changes the bandwidth configuration in the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-12-04 00:44:36 +07:00
usb_hcd_alloc_bandwidth(dev, NULL, NULL, NULL);
/* Leave LPM disabled while the device is unconfigured. */
mutex_unlock(hcd->bandwidth_mutex);
usb_autosuspend_device(dev);
goto free_interfaces;
}
mutex_unlock(hcd->bandwidth_mutex);
usb_set_device_state(dev, USB_STATE_CONFIGURED);
/* Initialize the new interface structures and the
* hc/hcd/usbcore interface/endpoint state.
*/
for (i = 0; i < nintf; ++i) {
struct usb_interface_cache *intfc;
struct usb_interface *intf;
struct usb_host_interface *alt;
cp->interface[i] = intf = new_interfaces[i];
intfc = cp->intf_cache[i];
intf->altsetting = intfc->altsetting;
intf->num_altsetting = intfc->num_altsetting;
kref_get(&intfc->ref);
alt = usb_altnum_to_altsetting(intf, 0);
/* No altsetting 0? We'll assume the first altsetting.
* We could use a GetInterface call, but if a device is
* so non-compliant that it doesn't have altsetting 0
* then I wouldn't trust its reply anyway.
*/
if (!alt)
alt = &intf->altsetting[0];
USB: fix gathering of interface associations TEAC's UD-H01 (and probably other devices) have a gap in the interface number allocation of their descriptors: Configuration Descriptor: bLength 9 bDescriptorType 2 wTotalLength 220 bNumInterfaces 3 [...] Interface Descriptor: bLength 9 bDescriptorType 4 bInterfaceNumber 0 bAlternateSetting 0 [...] Interface Association: bLength 8 bDescriptorType 11 bFirstInterface 2 bInterfaceCount 2 bFunctionClass 1 Audio bFunctionSubClass 0 bFunctionProtocol 32 iFunction 4 Interface Descriptor: bLength 9 bDescriptorType 4 bInterfaceNumber 2 bAlternateSetting 0 [...] Once a configuration is selected, usb_set_configuration() walks the known interfaces of a given configuration and calls find_iad() on each of them to set the interface association pointer the interface is included in. The problem here is that the loop variable is taken for the interface number in the comparison logic that gathers the association. Which is fine as long as the descriptors are sane. In the case above, however, the logic gets out of sync and the interface association fields of all interfaces beyond the interface number gap are wrong. Fix this by passing the interface's bInterfaceNumber to find_iad() instead. Signed-off-by: Daniel Mack <zonque@gmail.com> Reported-by: bEN <ml_all@circa.be> Reported-by: Ivan Perrone <ivanperrone@hotmail.com> Tested-by: ivan perrone <ivanperrone@hotmail.com> Cc: stable <stable@vger.kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2012-06-13 01:23:52 +07:00
intf->intf_assoc =
find_iad(dev, cp, alt->desc.bInterfaceNumber);
intf->cur_altsetting = alt;
usb_enable_interface(dev, intf, true);
intf->dev.parent = &dev->dev;
intf->dev.driver = NULL;
intf->dev.bus = &usb_bus_type;
USB: make usbdevices export their device nodes instead of using a separate class o The "real" usb-devices export now a device node which can populate /dev/bus/usb. o The usb_device class is optional now and can be disabled in the kernel config. Major/minor of the "real" devices and class devices are the same. o The environment of the usb-device event contains DEVNUM and BUSNUM to help udev and get rid of the ugly udev rule we need for the class devices. o The usb-devices and usb-interfaces share the same bus, so I used the new "struct device_type" to let these devices identify themselves. This also removes the current logic of using a magic platform-pointer. The name of the device_type is also added to the environment which makes it easier to distinguish the different kinds of devices on the same subsystem. It looks like this: add@/devices/pci0000:00/0000:00:1d.1/usb2/2-1 ACTION=add DEVPATH=/devices/pci0000:00/0000:00:1d.1/usb2/2-1 SUBSYSTEM=usb SEQNUM=1533 MAJOR=189 MINOR=131 DEVTYPE=usb_device PRODUCT=46d/c03e/2000 TYPE=0/0/0 BUSNUM=002 DEVNUM=004 This udev rule works as a replacement for usb_device class devices: SUBSYSTEM=="usb", ACTION=="add", ENV{DEVTYPE}=="usb_device", \ NAME="bus/usb/$env{BUSNUM}/$env{DEVNUM}", MODE="0644" Updated patch, which needs the device_type patches in Greg's tree. I also got a bugzilla assigned for this. :) https://bugzilla.novell.com/show_bug.cgi?id=250659 Signed-off-by: Kay Sievers <kay.sievers@vrfy.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2007-03-13 21:59:31 +07:00
intf->dev.type = &usb_if_device_type;
intf->dev.groups = usb_interface_groups;
intf->dev.dma_mask = dev->dev.dma_mask;
INIT_WORK(&intf->reset_ws, __usb_queue_reset_device);
intf->minor = -1;
device_initialize(&intf->dev);
pm_runtime_no_callbacks(&intf->dev);
dev_set_name(&intf->dev, "%d-%s:%d.%d",
dev->bus->busnum, dev->devpath,
configuration, alt->desc.bInterfaceNumber);
}
kfree(new_interfaces);
if (cp->string == NULL &&
!(dev->quirks & USB_QUIRK_CONFIG_INTF_STRINGS))
cp->string = usb_cache_string(dev, cp->desc.iConfiguration);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Now that the interfaces are installed, re-enable LPM. */
usb_unlocked_enable_lpm(dev);
USB: Enable Latency Tolerance Messaging (LTM). USB 3.0 devices may optionally support a new feature called Latency Tolerance Messaging. If both the xHCI host controller and the device support LTM, it should be turned on in order to give the system hardware a better clue about the latency tolerance values of its PCI devices. Once a Set Feature request to enable LTM is received, the USB 3.0 device will begin to send LTM updates as its buffers fill or empty, and it can tolerate more or less latency. The USB 3.0 spec, section C.4.2 says that LTM should be disabled just before the device is placed into suspend. Then the device will send an updated LTM notification, so that the system doesn't think it should remain in an active state in order to satisfy the latency requirements of the suspended device. The Set and Clear Feature LTM enable command can only be sent to a configured device. The device will respond with an error if that command is sent while it is in the Default or Addressed state. Make sure to check udev->actconfig in usb_enable_ltm() and usb_disable_ltm(), and don't send those commands when the device is unconfigured. LTM should be enabled once a new configuration is installed in usb_set_configuration(). If we end up sending duplicate Set Feature LTM Enable commands on a switch from one installed configuration to another configuration, that should be harmless. Make sure that LTM is disabled before the device is unconfigured in usb_disable_device(). If no drivers are bound to the device, it doesn't make sense to allow the device to control the latency tolerance of the xHCI host controller. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-06-26 02:08:08 +07:00
/* Enable LTM if it was turned off by usb_disable_device. */
usb_enable_ltm(dev);
USB: Disable USB 3.0 LPM in critical sections. There are several places where the USB core needs to disable USB 3.0 Link PM: - usb_bind_interface - usb_unbind_interface - usb_driver_claim_interface - usb_port_suspend/usb_port_resume - usb_reset_and_verify_device - usb_set_interface - usb_reset_configuration - usb_set_configuration Use the new LPM disable/enable functions to temporarily disable LPM around these critical sections. We need to protect the critical section around binding and unbinding USB interface drivers. USB drivers may want to disable hub-initiated USB 3.0 LPM, which will change the value of the U1/U2 timeouts that the xHCI driver will install. We need to disable LPM completely until the driver is bound to the interface, and the driver has a chance to enable whatever alternate interface setting it needs in its probe routine. Then re-enable USB3 LPM, and recalculate the U1/U2 timeout values. We also need to disable LPM in usb_driver_claim_interface, because drivers like usbfs can bind to an interface through that function. Note, there is no way currently for userspace drivers to disable hub-initiated USB 3.0 LPM. Revisit this later. When a driver is unbound, the U1/U2 timeouts may change because we are unbinding the last driver that needed hub-initiated USB 3.0 LPM to be disabled. USB LPM must be disabled when a USB device is going to be suspended. The USB 3.0 spec does not define a state transition from U1 or U2 into U3, so we need to bring the device into U0 by disabling LPM before we can place it into U3. Therefore, call usb_unlocked_disable_lpm() in usb_port_suspend(), and call usb_unlocked_enable_lpm() in usb_port_resume(). If the port suspend fails, make sure to re-enable LPM by calling usb_unlocked_enable_lpm(), since usb_port_resume() will not be called on a failed port suspend. USB 3.0 devices lose their USB 3.0 LPM settings (including whether USB device-initiated LPM is enabled) across device suspend. Therefore, disable LPM before the device will be reset in usb_reset_and_verify_device(), and re-enable LPM after the reset is complete and the configuration/alt settings are re-installed. The calculated U1/U2 timeout values are heavily dependent on what USB device endpoints are currently enabled. When any of the enabled endpoints on the device might change, due to a new configuration, or new alternate interface setting, we need to first disable USB 3.0 LPM, add or delete endpoints from the xHCI schedule, install the new interfaces and alt settings, and then re-enable LPM. Do this in usb_set_interface, usb_reset_configuration, and usb_set_configuration. Basically, there is a call to disable and then enable LPM in all functions that lock the bandwidth_mutex. One exception is usb_disable_device, because the device is disconnecting or otherwise going away, and we should not care about whether USB 3.0 LPM is enabled. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2012-05-03 04:25:52 +07:00
/* Now that all the interfaces are set up, register them
* to trigger binding of drivers to interfaces. probe()
* routines may install different altsettings and may
* claim() any interfaces not yet bound. Many class drivers
* need that: CDC, audio, video, etc.
*/
for (i = 0; i < nintf; ++i) {
struct usb_interface *intf = cp->interface[i];
dev_dbg(&dev->dev,
"adding %s (config #%d, interface %d)\n",
dev_name(&intf->dev), configuration,
intf->cur_altsetting->desc.bInterfaceNumber);
device_enable_async_suspend(&intf->dev);
ret = device_add(&intf->dev);
if (ret != 0) {
dev_err(&dev->dev, "device_add(%s) --> %d\n",
dev_name(&intf->dev), ret);
continue;
}
create_intf_ep_devs(intf);
}
usb_autosuspend_device(dev);
return 0;
}
static LIST_HEAD(set_config_list);
static DEFINE_SPINLOCK(set_config_lock);
struct set_config_request {
struct usb_device *udev;
int config;
struct work_struct work;
struct list_head node;
};
/* Worker routine for usb_driver_set_configuration() */
static void driver_set_config_work(struct work_struct *work)
{
struct set_config_request *req =
container_of(work, struct set_config_request, work);
struct usb_device *udev = req->udev;
usb_lock_device(udev);
spin_lock(&set_config_lock);
list_del(&req->node);
spin_unlock(&set_config_lock);
if (req->config >= -1) /* Is req still valid? */
usb_set_configuration(udev, req->config);
usb_unlock_device(udev);
usb_put_dev(udev);
kfree(req);
}
/* Cancel pending Set-Config requests for a device whose configuration
* was just changed
*/
static void cancel_async_set_config(struct usb_device *udev)
{
struct set_config_request *req;
spin_lock(&set_config_lock);
list_for_each_entry(req, &set_config_list, node) {
if (req->udev == udev)
req->config = -999; /* Mark as cancelled */
}
spin_unlock(&set_config_lock);
}
/**
* usb_driver_set_configuration - Provide a way for drivers to change device configurations
* @udev: the device whose configuration is being updated
* @config: the configuration being chosen.
* Context: In process context, must be able to sleep
*
* Device interface drivers are not allowed to change device configurations.
* This is because changing configurations will destroy the interface the
* driver is bound to and create new ones; it would be like a floppy-disk
* driver telling the computer to replace the floppy-disk drive with a
* tape drive!
*
* Still, in certain specialized circumstances the need may arise. This
* routine gets around the normal restrictions by using a work thread to
* submit the change-config request.
*
* Returns 0 if the request was successfully queued, error code otherwise.
* The caller has no way to know whether the queued request will eventually
* succeed.
*/
int usb_driver_set_configuration(struct usb_device *udev, int config)
{
struct set_config_request *req;
req = kmalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return -ENOMEM;
req->udev = udev;
req->config = config;
INIT_WORK(&req->work, driver_set_config_work);
spin_lock(&set_config_lock);
list_add(&req->node, &set_config_list);
spin_unlock(&set_config_lock);
usb_get_dev(udev);
schedule_work(&req->work);
return 0;
}
EXPORT_SYMBOL_GPL(usb_driver_set_configuration);