linux_old1/drivers/usb/host/xhci-mem.c

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/*
* xHCI host controller driver
*
* Copyright (C) 2008 Intel Corp.
*
* Author: Sarah Sharp
* Some code borrowed from the Linux EHCI driver.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <linux/usb.h>
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
#include <linux/pci.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 16:04:11 +08:00
#include <linux/slab.h>
#include <linux/dmapool.h>
#include <linux/dma-mapping.h>
#include "xhci.h"
#include "xhci-trace.h"
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/*
* Allocates a generic ring segment from the ring pool, sets the dma address,
* initializes the segment to zero, and sets the private next pointer to NULL.
*
* Section 4.11.1.1:
* "All components of all Command and Transfer TRBs shall be initialized to '0'"
*/
static struct xhci_segment *xhci_segment_alloc(struct xhci_hcd *xhci,
unsigned int cycle_state, gfp_t flags)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
{
struct xhci_segment *seg;
dma_addr_t dma;
int i;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
seg = kzalloc(sizeof *seg, flags);
if (!seg)
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
return NULL;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
seg->trbs = dma_pool_alloc(xhci->segment_pool, flags, &dma);
if (!seg->trbs) {
kfree(seg);
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
return NULL;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
}
memset(seg->trbs, 0, TRB_SEGMENT_SIZE);
/* If the cycle state is 0, set the cycle bit to 1 for all the TRBs */
if (cycle_state == 0) {
for (i = 0; i < TRBS_PER_SEGMENT; i++)
seg->trbs[i].link.control |= cpu_to_le32(TRB_CYCLE);
}
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
seg->dma = dma;
seg->next = NULL;
return seg;
}
static void xhci_segment_free(struct xhci_hcd *xhci, struct xhci_segment *seg)
{
if (seg->trbs) {
dma_pool_free(xhci->segment_pool, seg->trbs, seg->dma);
seg->trbs = NULL;
}
kfree(seg);
}
static void xhci_free_segments_for_ring(struct xhci_hcd *xhci,
struct xhci_segment *first)
{
struct xhci_segment *seg;
seg = first->next;
while (seg != first) {
struct xhci_segment *next = seg->next;
xhci_segment_free(xhci, seg);
seg = next;
}
xhci_segment_free(xhci, first);
}
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/*
* Make the prev segment point to the next segment.
*
* Change the last TRB in the prev segment to be a Link TRB which points to the
* DMA address of the next segment. The caller needs to set any Link TRB
* related flags, such as End TRB, Toggle Cycle, and no snoop.
*/
static void xhci_link_segments(struct xhci_hcd *xhci, struct xhci_segment *prev,
struct xhci_segment *next, enum xhci_ring_type type)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
{
u32 val;
if (!prev || !next)
return;
prev->next = next;
if (type != TYPE_EVENT) {
prev->trbs[TRBS_PER_SEGMENT-1].link.segment_ptr =
cpu_to_le64(next->dma);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* Set the last TRB in the segment to have a TRB type ID of Link TRB */
val = le32_to_cpu(prev->trbs[TRBS_PER_SEGMENT-1].link.control);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
val &= ~TRB_TYPE_BITMASK;
val |= TRB_TYPE(TRB_LINK);
USB: xhci: Work around for chain bit in link TRBs. Different sections of the xHCI 0.95 specification had opposing requirements for the chain bit in a link transaction request buffer (TRB). The chain bit is used to designate that adjacent TRBs are all part of the same scatter gather list that should be sent to the device. Link TRBs can be in the middle, or at the beginning or end of these chained TRBs. Sections 4.11.5.1 and 6.4.4.1 both stated the link TRB "shall have the chain bit set to 1", meaning it is always chained to the next TRB. However, section 4.6.9 on the stop endpoint command has specific cases for what the hardware must do for a link TRB with the chain bit set to 0. The 0.96 specification errata later cleared up this issue by fixing the 4.11.5.1 and 6.4.4.1 sections to state that a link TRB can have the chain bit set to 1 or 0. The problem is that the xHCI cancellation code depends on the chain bit of the link TRB being cleared when it's at the end of a TD, and some 0.95 xHCI hardware simply stops processing the ring when it encounters a link TRB with the chain bit cleared. Allow users who are testing 0.95 xHCI prototypes to set a module parameter (link_quirk) to turn on this link TRB work around. Cancellation may not work if the ring is stopped exactly on a link TRB with chain bit set, but cancellation should be a relatively uncommon case. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-08-08 05:04:36 +08:00
/* Always set the chain bit with 0.95 hardware */
/* Set chain bit for isoc rings on AMD 0.96 host */
if (xhci_link_trb_quirk(xhci) ||
(type == TYPE_ISOC &&
(xhci->quirks & XHCI_AMD_0x96_HOST)))
USB: xhci: Work around for chain bit in link TRBs. Different sections of the xHCI 0.95 specification had opposing requirements for the chain bit in a link transaction request buffer (TRB). The chain bit is used to designate that adjacent TRBs are all part of the same scatter gather list that should be sent to the device. Link TRBs can be in the middle, or at the beginning or end of these chained TRBs. Sections 4.11.5.1 and 6.4.4.1 both stated the link TRB "shall have the chain bit set to 1", meaning it is always chained to the next TRB. However, section 4.6.9 on the stop endpoint command has specific cases for what the hardware must do for a link TRB with the chain bit set to 0. The 0.96 specification errata later cleared up this issue by fixing the 4.11.5.1 and 6.4.4.1 sections to state that a link TRB can have the chain bit set to 1 or 0. The problem is that the xHCI cancellation code depends on the chain bit of the link TRB being cleared when it's at the end of a TD, and some 0.95 xHCI hardware simply stops processing the ring when it encounters a link TRB with the chain bit cleared. Allow users who are testing 0.95 xHCI prototypes to set a module parameter (link_quirk) to turn on this link TRB work around. Cancellation may not work if the ring is stopped exactly on a link TRB with chain bit set, but cancellation should be a relatively uncommon case. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-08-08 05:04:36 +08:00
val |= TRB_CHAIN;
prev->trbs[TRBS_PER_SEGMENT-1].link.control = cpu_to_le32(val);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
}
}
/*
* Link the ring to the new segments.
* Set Toggle Cycle for the new ring if needed.
*/
static void xhci_link_rings(struct xhci_hcd *xhci, struct xhci_ring *ring,
struct xhci_segment *first, struct xhci_segment *last,
unsigned int num_segs)
{
struct xhci_segment *next;
if (!ring || !first || !last)
return;
next = ring->enq_seg->next;
xhci_link_segments(xhci, ring->enq_seg, first, ring->type);
xhci_link_segments(xhci, last, next, ring->type);
ring->num_segs += num_segs;
ring->num_trbs_free += (TRBS_PER_SEGMENT - 1) * num_segs;
if (ring->type != TYPE_EVENT && ring->enq_seg == ring->last_seg) {
ring->last_seg->trbs[TRBS_PER_SEGMENT-1].link.control
&= ~cpu_to_le32(LINK_TOGGLE);
last->trbs[TRBS_PER_SEGMENT-1].link.control
|= cpu_to_le32(LINK_TOGGLE);
ring->last_seg = last;
}
}
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* XXX: Do we need the hcd structure in all these functions? */
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
void xhci_ring_free(struct xhci_hcd *xhci, struct xhci_ring *ring)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
{
if (!ring)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
return;
if (ring->first_seg)
xhci_free_segments_for_ring(xhci, ring->first_seg);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
kfree(ring);
}
static void xhci_initialize_ring_info(struct xhci_ring *ring,
unsigned int cycle_state)
{
/* The ring is empty, so the enqueue pointer == dequeue pointer */
ring->enqueue = ring->first_seg->trbs;
ring->enq_seg = ring->first_seg;
ring->dequeue = ring->enqueue;
ring->deq_seg = ring->first_seg;
/* The ring is initialized to 0. The producer must write 1 to the cycle
* bit to handover ownership of the TRB, so PCS = 1. The consumer must
* compare CCS to the cycle bit to check ownership, so CCS = 1.
*
* New rings are initialized with cycle state equal to 1; if we are
* handling ring expansion, set the cycle state equal to the old ring.
*/
ring->cycle_state = cycle_state;
/* Not necessary for new rings, but needed for re-initialized rings */
ring->enq_updates = 0;
ring->deq_updates = 0;
/*
* Each segment has a link TRB, and leave an extra TRB for SW
* accounting purpose
*/
ring->num_trbs_free = ring->num_segs * (TRBS_PER_SEGMENT - 1) - 1;
}
/* Allocate segments and link them for a ring */
static int xhci_alloc_segments_for_ring(struct xhci_hcd *xhci,
struct xhci_segment **first, struct xhci_segment **last,
unsigned int num_segs, unsigned int cycle_state,
enum xhci_ring_type type, gfp_t flags)
{
struct xhci_segment *prev;
prev = xhci_segment_alloc(xhci, cycle_state, flags);
if (!prev)
return -ENOMEM;
num_segs--;
*first = prev;
while (num_segs > 0) {
struct xhci_segment *next;
next = xhci_segment_alloc(xhci, cycle_state, flags);
if (!next) {
prev = *first;
while (prev) {
next = prev->next;
xhci_segment_free(xhci, prev);
prev = next;
}
return -ENOMEM;
}
xhci_link_segments(xhci, prev, next, type);
prev = next;
num_segs--;
}
xhci_link_segments(xhci, prev, *first, type);
*last = prev;
return 0;
}
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/**
* Create a new ring with zero or more segments.
*
* Link each segment together into a ring.
* Set the end flag and the cycle toggle bit on the last segment.
* See section 4.9.1 and figures 15 and 16.
*/
static struct xhci_ring *xhci_ring_alloc(struct xhci_hcd *xhci,
unsigned int num_segs, unsigned int cycle_state,
enum xhci_ring_type type, gfp_t flags)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
{
struct xhci_ring *ring;
int ret;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
ring = kzalloc(sizeof *(ring), flags);
if (!ring)
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
return NULL;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
ring->num_segs = num_segs;
INIT_LIST_HEAD(&ring->td_list);
ring->type = type;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (num_segs == 0)
return ring;
ret = xhci_alloc_segments_for_ring(xhci, &ring->first_seg,
&ring->last_seg, num_segs, cycle_state, type, flags);
if (ret)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
goto fail;
/* Only event ring does not use link TRB */
if (type != TYPE_EVENT) {
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* See section 4.9.2.1 and 6.4.4.1 */
ring->last_seg->trbs[TRBS_PER_SEGMENT - 1].link.control |=
cpu_to_le32(LINK_TOGGLE);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
}
xhci_initialize_ring_info(ring, cycle_state);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
return ring;
fail:
kfree(ring);
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
return NULL;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
}
void xhci_free_or_cache_endpoint_ring(struct xhci_hcd *xhci,
struct xhci_virt_device *virt_dev,
unsigned int ep_index)
{
int rings_cached;
rings_cached = virt_dev->num_rings_cached;
if (rings_cached < XHCI_MAX_RINGS_CACHED) {
virt_dev->ring_cache[rings_cached] =
virt_dev->eps[ep_index].ring;
virt_dev->num_rings_cached++;
xhci_dbg(xhci, "Cached old ring, "
"%d ring%s cached\n",
virt_dev->num_rings_cached,
(virt_dev->num_rings_cached > 1) ? "s" : "");
} else {
xhci_ring_free(xhci, virt_dev->eps[ep_index].ring);
xhci_dbg(xhci, "Ring cache full (%d rings), "
"freeing ring\n",
virt_dev->num_rings_cached);
}
virt_dev->eps[ep_index].ring = NULL;
}
/* Zero an endpoint ring (except for link TRBs) and move the enqueue and dequeue
* pointers to the beginning of the ring.
*/
static void xhci_reinit_cached_ring(struct xhci_hcd *xhci,
struct xhci_ring *ring, unsigned int cycle_state,
enum xhci_ring_type type)
{
struct xhci_segment *seg = ring->first_seg;
int i;
do {
memset(seg->trbs, 0,
sizeof(union xhci_trb)*TRBS_PER_SEGMENT);
if (cycle_state == 0) {
for (i = 0; i < TRBS_PER_SEGMENT; i++)
seg->trbs[i].link.control |=
cpu_to_le32(TRB_CYCLE);
}
/* All endpoint rings have link TRBs */
xhci_link_segments(xhci, seg, seg->next, type);
seg = seg->next;
} while (seg != ring->first_seg);
ring->type = type;
xhci_initialize_ring_info(ring, cycle_state);
/* td list should be empty since all URBs have been cancelled,
* but just in case...
*/
INIT_LIST_HEAD(&ring->td_list);
}
/*
* Expand an existing ring.
* Look for a cached ring or allocate a new ring which has same segment numbers
* and link the two rings.
*/
int xhci_ring_expansion(struct xhci_hcd *xhci, struct xhci_ring *ring,
unsigned int num_trbs, gfp_t flags)
{
struct xhci_segment *first;
struct xhci_segment *last;
unsigned int num_segs;
unsigned int num_segs_needed;
int ret;
num_segs_needed = (num_trbs + (TRBS_PER_SEGMENT - 1) - 1) /
(TRBS_PER_SEGMENT - 1);
/* Allocate number of segments we needed, or double the ring size */
num_segs = ring->num_segs > num_segs_needed ?
ring->num_segs : num_segs_needed;
ret = xhci_alloc_segments_for_ring(xhci, &first, &last,
num_segs, ring->cycle_state, ring->type, flags);
if (ret)
return -ENOMEM;
xhci_link_rings(xhci, ring, first, last, num_segs);
xhci_dbg_trace(xhci, trace_xhci_dbg_ring_expansion,
"ring expansion succeed, now has %d segments",
ring->num_segs);
return 0;
}
#define CTX_SIZE(_hcc) (HCC_64BYTE_CONTEXT(_hcc) ? 64 : 32)
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
static struct xhci_container_ctx *xhci_alloc_container_ctx(struct xhci_hcd *xhci,
int type, gfp_t flags)
{
struct xhci_container_ctx *ctx;
if ((type != XHCI_CTX_TYPE_DEVICE) && (type != XHCI_CTX_TYPE_INPUT))
return NULL;
ctx = kzalloc(sizeof(*ctx), flags);
if (!ctx)
return NULL;
ctx->type = type;
ctx->size = HCC_64BYTE_CONTEXT(xhci->hcc_params) ? 2048 : 1024;
if (type == XHCI_CTX_TYPE_INPUT)
ctx->size += CTX_SIZE(xhci->hcc_params);
ctx->bytes = dma_pool_alloc(xhci->device_pool, flags, &ctx->dma);
if (!ctx->bytes) {
kfree(ctx);
return NULL;
}
memset(ctx->bytes, 0, ctx->size);
return ctx;
}
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
static void xhci_free_container_ctx(struct xhci_hcd *xhci,
struct xhci_container_ctx *ctx)
{
if (!ctx)
return;
dma_pool_free(xhci->device_pool, ctx->bytes, ctx->dma);
kfree(ctx);
}
struct xhci_input_control_ctx *xhci_get_input_control_ctx(struct xhci_hcd *xhci,
struct xhci_container_ctx *ctx)
{
if (ctx->type != XHCI_CTX_TYPE_INPUT)
return NULL;
return (struct xhci_input_control_ctx *)ctx->bytes;
}
struct xhci_slot_ctx *xhci_get_slot_ctx(struct xhci_hcd *xhci,
struct xhci_container_ctx *ctx)
{
if (ctx->type == XHCI_CTX_TYPE_DEVICE)
return (struct xhci_slot_ctx *)ctx->bytes;
return (struct xhci_slot_ctx *)
(ctx->bytes + CTX_SIZE(xhci->hcc_params));
}
struct xhci_ep_ctx *xhci_get_ep_ctx(struct xhci_hcd *xhci,
struct xhci_container_ctx *ctx,
unsigned int ep_index)
{
/* increment ep index by offset of start of ep ctx array */
ep_index++;
if (ctx->type == XHCI_CTX_TYPE_INPUT)
ep_index++;
return (struct xhci_ep_ctx *)
(ctx->bytes + (ep_index * CTX_SIZE(xhci->hcc_params)));
}
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
/***************** Streams structures manipulation *************************/
static void xhci_free_stream_ctx(struct xhci_hcd *xhci,
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
unsigned int num_stream_ctxs,
struct xhci_stream_ctx *stream_ctx, dma_addr_t dma)
{
struct device *dev = xhci_to_hcd(xhci)->self.controller;
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (num_stream_ctxs > MEDIUM_STREAM_ARRAY_SIZE)
dma_free_coherent(dev,
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
sizeof(struct xhci_stream_ctx)*num_stream_ctxs,
stream_ctx, dma);
else if (num_stream_ctxs <= SMALL_STREAM_ARRAY_SIZE)
return dma_pool_free(xhci->small_streams_pool,
stream_ctx, dma);
else
return dma_pool_free(xhci->medium_streams_pool,
stream_ctx, dma);
}
/*
* The stream context array for each endpoint with bulk streams enabled can
* vary in size, based on:
* - how many streams the endpoint supports,
* - the maximum primary stream array size the host controller supports,
* - and how many streams the device driver asks for.
*
* The stream context array must be a power of 2, and can be as small as
* 64 bytes or as large as 1MB.
*/
static struct xhci_stream_ctx *xhci_alloc_stream_ctx(struct xhci_hcd *xhci,
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
unsigned int num_stream_ctxs, dma_addr_t *dma,
gfp_t mem_flags)
{
struct device *dev = xhci_to_hcd(xhci)->self.controller;
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (num_stream_ctxs > MEDIUM_STREAM_ARRAY_SIZE)
return dma_alloc_coherent(dev,
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
sizeof(struct xhci_stream_ctx)*num_stream_ctxs,
dma, mem_flags);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
else if (num_stream_ctxs <= SMALL_STREAM_ARRAY_SIZE)
return dma_pool_alloc(xhci->small_streams_pool,
mem_flags, dma);
else
return dma_pool_alloc(xhci->medium_streams_pool,
mem_flags, dma);
}
USB: xhci: Correct assumptions about number of rings per endpoint. Much of the xHCI driver code assumes that endpoints only have one ring. Now an endpoint can have one ring per enabled stream ID, so correct that assumption. Use functions that translate the stream_id field in the URB or the DMA address of a TRB into the correct stream ring. Correct the polling loop to print out all enabled stream rings. Make the URB cancellation routine find the correct stream ring if the URB has stream_id set. Make sure the URB enqueueing routine does the same. Also correct the code that handles stalled/halted endpoints. Check that commands and registers that can take stream IDs handle them properly. That includes ringing an endpoint doorbell, resetting a stalled/halted endpoint, and setting a transfer ring dequeue pointer (since that command can set the dequeue pointer in a stream context or an endpoint context). Correct the transfer event handler to translate a TRB DMA address into the stream ring it was enqueued to. Make the code to allocate and prepare TD structures adds the TD to the right td_list for the stream ring. Make sure the code to give the first TRB in a TD to the hardware manipulates the correct stream ring. When an endpoint stalls, store the stream ID of the stream ring that stalled in the xhci_virt_ep structure. Use that instead of the stream ID in the URB, since an URB may be re-used after it is given back after a non-control endpoint stall. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:43 +08:00
struct xhci_ring *xhci_dma_to_transfer_ring(
struct xhci_virt_ep *ep,
u64 address)
{
if (ep->ep_state & EP_HAS_STREAMS)
return radix_tree_lookup(&ep->stream_info->trb_address_map,
address >> TRB_SEGMENT_SHIFT);
USB: xhci: Correct assumptions about number of rings per endpoint. Much of the xHCI driver code assumes that endpoints only have one ring. Now an endpoint can have one ring per enabled stream ID, so correct that assumption. Use functions that translate the stream_id field in the URB or the DMA address of a TRB into the correct stream ring. Correct the polling loop to print out all enabled stream rings. Make the URB cancellation routine find the correct stream ring if the URB has stream_id set. Make sure the URB enqueueing routine does the same. Also correct the code that handles stalled/halted endpoints. Check that commands and registers that can take stream IDs handle them properly. That includes ringing an endpoint doorbell, resetting a stalled/halted endpoint, and setting a transfer ring dequeue pointer (since that command can set the dequeue pointer in a stream context or an endpoint context). Correct the transfer event handler to translate a TRB DMA address into the stream ring it was enqueued to. Make the code to allocate and prepare TD structures adds the TD to the right td_list for the stream ring. Make sure the code to give the first TRB in a TD to the hardware manipulates the correct stream ring. When an endpoint stalls, store the stream ID of the stream ring that stalled in the xhci_virt_ep structure. Use that instead of the stream ID in the URB, since an URB may be re-used after it is given back after a non-control endpoint stall. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:43 +08:00
return ep->ring;
}
struct xhci_ring *xhci_stream_id_to_ring(
struct xhci_virt_device *dev,
unsigned int ep_index,
unsigned int stream_id)
{
struct xhci_virt_ep *ep = &dev->eps[ep_index];
if (stream_id == 0)
return ep->ring;
if (!ep->stream_info)
return NULL;
if (stream_id > ep->stream_info->num_streams)
return NULL;
return ep->stream_info->stream_rings[stream_id];
}
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
/*
* Change an endpoint's internal structure so it supports stream IDs. The
* number of requested streams includes stream 0, which cannot be used by device
* drivers.
*
* The number of stream contexts in the stream context array may be bigger than
* the number of streams the driver wants to use. This is because the number of
* stream context array entries must be a power of two.
*
* We need a radix tree for mapping physical addresses of TRBs to which stream
* ID they belong to. We need to do this because the host controller won't tell
* us which stream ring the TRB came from. We could store the stream ID in an
* event data TRB, but that doesn't help us for the cancellation case, since the
* endpoint may stop before it reaches that event data TRB.
*
* The radix tree maps the upper portion of the TRB DMA address to a ring
* segment that has the same upper portion of DMA addresses. For example, say I
* have segments of size 1KB, that are always 64-byte aligned. A segment may
* start at 0x10c91000 and end at 0x10c913f0. If I use the upper 10 bits, the
* key to the stream ID is 0x43244. I can use the DMA address of the TRB to
* pass the radix tree a key to get the right stream ID:
*
* 0x10c90fff >> 10 = 0x43243
* 0x10c912c0 >> 10 = 0x43244
* 0x10c91400 >> 10 = 0x43245
*
* Obviously, only those TRBs with DMA addresses that are within the segment
* will make the radix tree return the stream ID for that ring.
*
* Caveats for the radix tree:
*
* The radix tree uses an unsigned long as a key pair. On 32-bit systems, an
* unsigned long will be 32-bits; on a 64-bit system an unsigned long will be
* 64-bits. Since we only request 32-bit DMA addresses, we can use that as the
* key on 32-bit or 64-bit systems (it would also be fine if we asked for 64-bit
* PCI DMA addresses on a 64-bit system). There might be a problem on 32-bit
* extended systems (where the DMA address can be bigger than 32-bits),
* if we allow the PCI dma mask to be bigger than 32-bits. So don't do that.
*/
struct xhci_stream_info *xhci_alloc_stream_info(struct xhci_hcd *xhci,
unsigned int num_stream_ctxs,
unsigned int num_streams, gfp_t mem_flags)
{
struct xhci_stream_info *stream_info;
u32 cur_stream;
struct xhci_ring *cur_ring;
unsigned long key;
u64 addr;
int ret;
xhci_dbg(xhci, "Allocating %u streams and %u "
"stream context array entries.\n",
num_streams, num_stream_ctxs);
if (xhci->cmd_ring_reserved_trbs == MAX_RSVD_CMD_TRBS) {
xhci_dbg(xhci, "Command ring has no reserved TRBs available\n");
return NULL;
}
xhci->cmd_ring_reserved_trbs++;
stream_info = kzalloc(sizeof(struct xhci_stream_info), mem_flags);
if (!stream_info)
goto cleanup_trbs;
stream_info->num_streams = num_streams;
stream_info->num_stream_ctxs = num_stream_ctxs;
/* Initialize the array of virtual pointers to stream rings. */
stream_info->stream_rings = kzalloc(
sizeof(struct xhci_ring *)*num_streams,
mem_flags);
if (!stream_info->stream_rings)
goto cleanup_info;
/* Initialize the array of DMA addresses for stream rings for the HW. */
stream_info->stream_ctx_array = xhci_alloc_stream_ctx(xhci,
num_stream_ctxs, &stream_info->ctx_array_dma,
mem_flags);
if (!stream_info->stream_ctx_array)
goto cleanup_ctx;
memset(stream_info->stream_ctx_array, 0,
sizeof(struct xhci_stream_ctx)*num_stream_ctxs);
/* Allocate everything needed to free the stream rings later */
stream_info->free_streams_command =
xhci_alloc_command(xhci, true, true, mem_flags);
if (!stream_info->free_streams_command)
goto cleanup_ctx;
INIT_RADIX_TREE(&stream_info->trb_address_map, GFP_ATOMIC);
/* Allocate rings for all the streams that the driver will use,
* and add their segment DMA addresses to the radix tree.
* Stream 0 is reserved.
*/
for (cur_stream = 1; cur_stream < num_streams; cur_stream++) {
stream_info->stream_rings[cur_stream] =
xhci_ring_alloc(xhci, 2, 1, TYPE_STREAM, mem_flags);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
cur_ring = stream_info->stream_rings[cur_stream];
if (!cur_ring)
goto cleanup_rings;
USB: xhci: Correct assumptions about number of rings per endpoint. Much of the xHCI driver code assumes that endpoints only have one ring. Now an endpoint can have one ring per enabled stream ID, so correct that assumption. Use functions that translate the stream_id field in the URB or the DMA address of a TRB into the correct stream ring. Correct the polling loop to print out all enabled stream rings. Make the URB cancellation routine find the correct stream ring if the URB has stream_id set. Make sure the URB enqueueing routine does the same. Also correct the code that handles stalled/halted endpoints. Check that commands and registers that can take stream IDs handle them properly. That includes ringing an endpoint doorbell, resetting a stalled/halted endpoint, and setting a transfer ring dequeue pointer (since that command can set the dequeue pointer in a stream context or an endpoint context). Correct the transfer event handler to translate a TRB DMA address into the stream ring it was enqueued to. Make the code to allocate and prepare TD structures adds the TD to the right td_list for the stream ring. Make sure the code to give the first TRB in a TD to the hardware manipulates the correct stream ring. When an endpoint stalls, store the stream ID of the stream ring that stalled in the xhci_virt_ep structure. Use that instead of the stream ID in the URB, since an URB may be re-used after it is given back after a non-control endpoint stall. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:43 +08:00
cur_ring->stream_id = cur_stream;
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
/* Set deq ptr, cycle bit, and stream context type */
addr = cur_ring->first_seg->dma |
SCT_FOR_CTX(SCT_PRI_TR) |
cur_ring->cycle_state;
stream_info->stream_ctx_array[cur_stream].stream_ring =
cpu_to_le64(addr);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
xhci_dbg(xhci, "Setting stream %d ring ptr to 0x%08llx\n",
cur_stream, (unsigned long long) addr);
key = (unsigned long)
(cur_ring->first_seg->dma >> TRB_SEGMENT_SHIFT);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
ret = radix_tree_insert(&stream_info->trb_address_map,
key, cur_ring);
if (ret) {
xhci_ring_free(xhci, cur_ring);
stream_info->stream_rings[cur_stream] = NULL;
goto cleanup_rings;
}
}
/* Leave the other unused stream ring pointers in the stream context
* array initialized to zero. This will cause the xHC to give us an
* error if the device asks for a stream ID we don't have setup (if it
* was any other way, the host controller would assume the ring is
* "empty" and wait forever for data to be queued to that stream ID).
*/
return stream_info;
cleanup_rings:
for (cur_stream = 1; cur_stream < num_streams; cur_stream++) {
cur_ring = stream_info->stream_rings[cur_stream];
if (cur_ring) {
addr = cur_ring->first_seg->dma;
radix_tree_delete(&stream_info->trb_address_map,
addr >> TRB_SEGMENT_SHIFT);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
xhci_ring_free(xhci, cur_ring);
stream_info->stream_rings[cur_stream] = NULL;
}
}
xhci_free_command(xhci, stream_info->free_streams_command);
cleanup_ctx:
kfree(stream_info->stream_rings);
cleanup_info:
kfree(stream_info);
cleanup_trbs:
xhci->cmd_ring_reserved_trbs--;
return NULL;
}
/*
* Sets the MaxPStreams field and the Linear Stream Array field.
* Sets the dequeue pointer to the stream context array.
*/
void xhci_setup_streams_ep_input_ctx(struct xhci_hcd *xhci,
struct xhci_ep_ctx *ep_ctx,
struct xhci_stream_info *stream_info)
{
u32 max_primary_streams;
/* MaxPStreams is the number of stream context array entries, not the
* number we're actually using. Must be in 2^(MaxPstreams + 1) format.
* fls(0) = 0, fls(0x1) = 1, fls(0x10) = 2, fls(0x100) = 3, etc.
*/
max_primary_streams = fls(stream_info->num_stream_ctxs) - 2;
xhci_dbg_trace(xhci, trace_xhci_dbg_context_change,
"Setting number of stream ctx array entries to %u",
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
1 << (max_primary_streams + 1));
ep_ctx->ep_info &= cpu_to_le32(~EP_MAXPSTREAMS_MASK);
ep_ctx->ep_info |= cpu_to_le32(EP_MAXPSTREAMS(max_primary_streams)
| EP_HAS_LSA);
ep_ctx->deq = cpu_to_le64(stream_info->ctx_array_dma);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
}
/*
* Sets the MaxPStreams field and the Linear Stream Array field to 0.
* Reinstalls the "normal" endpoint ring (at its previous dequeue mark,
* not at the beginning of the ring).
*/
void xhci_setup_no_streams_ep_input_ctx(struct xhci_hcd *xhci,
struct xhci_ep_ctx *ep_ctx,
struct xhci_virt_ep *ep)
{
dma_addr_t addr;
ep_ctx->ep_info &= cpu_to_le32(~(EP_MAXPSTREAMS_MASK | EP_HAS_LSA));
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
addr = xhci_trb_virt_to_dma(ep->ring->deq_seg, ep->ring->dequeue);
ep_ctx->deq = cpu_to_le64(addr | ep->ring->cycle_state);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
}
/* Frees all stream contexts associated with the endpoint,
*
* Caller should fix the endpoint context streams fields.
*/
void xhci_free_stream_info(struct xhci_hcd *xhci,
struct xhci_stream_info *stream_info)
{
int cur_stream;
struct xhci_ring *cur_ring;
dma_addr_t addr;
if (!stream_info)
return;
for (cur_stream = 1; cur_stream < stream_info->num_streams;
cur_stream++) {
cur_ring = stream_info->stream_rings[cur_stream];
if (cur_ring) {
addr = cur_ring->first_seg->dma;
radix_tree_delete(&stream_info->trb_address_map,
addr >> TRB_SEGMENT_SHIFT);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
xhci_ring_free(xhci, cur_ring);
stream_info->stream_rings[cur_stream] = NULL;
}
}
xhci_free_command(xhci, stream_info->free_streams_command);
xhci->cmd_ring_reserved_trbs--;
if (stream_info->stream_ctx_array)
xhci_free_stream_ctx(xhci,
stream_info->num_stream_ctxs,
stream_info->stream_ctx_array,
stream_info->ctx_array_dma);
kfree(stream_info->stream_rings);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
kfree(stream_info);
}
/***************** Device context manipulation *************************/
USB: xhci: Add watchdog timer for URB cancellation. In order to giveback a canceled URB, we must ensure that the xHCI hardware will not access the buffer in an URB. We can't modify the buffer pointers on endpoint rings without issuing and waiting for a stop endpoint command. Since URBs can be canceled in interrupt context, we can't wait on that command. The old code trusted that the host controller would respond to the command, and would giveback the URBs in the event handler. If the hardware never responds to the stop endpoint command, the URBs will never be completed, and we might hang the USB subsystem. Implement a watchdog timer that is spawned whenever a stop endpoint command is queued. If a stop endpoint command event is found on the event ring during an interrupt, we need to stop the watchdog timer with del_timer(). Since del_timer() can fail if the timer is running and waiting on the xHCI lock, we need a way to signal to the timer that everything is fine and it should exit. If we simply clear EP_HALT_PENDING, a new stop endpoint command could sneak in and set it before the watchdog timer can grab the lock. Instead we use a combination of the EP_HALT_PENDING flag and a counter for the number of pending stop endpoint commands (xhci_virt_ep->stop_cmds_pending). If we need to cancel the watchdog timer and del_timer() succeeds, we decrement the number of pending stop endpoint commands. If del_timer() fails, we leave the number of pending stop endpoint commands alone. In either case, we clear the EP_HALT_PENDING flag. The timer will decrement the number of pending stop endpoint commands once it obtains the lock. If the timer is the tail end of the last stop endpoint command (xhci_virt_ep->stop_cmds_pending == 0), and the endpoint's command is still pending (EP_HALT_PENDING is set), we assume the host is dying. The watchdog timer will set XHCI_STATE_DYING, try to halt the xHCI host, and give back all pending URBs. Various other places in the driver need to check whether the xHCI host is dying. If the interrupt handler ever notices, it should immediately stop processing events. The URB enqueue function should also return -ESHUTDOWN. The URB dequeue function should simply return the value of usb_hcd_check_unlink_urb() and the watchdog timer will take care of giving the URB back. When a device is disconnected, the xHCI hardware structures should be freed without issuing a disable slot command (since the hardware probably won't respond to it anyway). The debugging polling loop should stop polling if the host is dying. When a device is disconnected, any pending watchdog timers are killed with del_timer_sync(). It must be synchronous so that the watchdog timer doesn't attempt to access the freed endpoint structures. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-10-28 01:57:01 +08:00
static void xhci_init_endpoint_timer(struct xhci_hcd *xhci,
struct xhci_virt_ep *ep)
{
init_timer(&ep->stop_cmd_timer);
ep->stop_cmd_timer.data = (unsigned long) ep;
ep->stop_cmd_timer.function = xhci_stop_endpoint_command_watchdog;
ep->xhci = xhci;
}
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
static void xhci_free_tt_info(struct xhci_hcd *xhci,
struct xhci_virt_device *virt_dev,
int slot_id)
{
struct list_head *tt_list_head;
struct xhci_tt_bw_info *tt_info, *next;
bool slot_found = false;
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
/* If the device never made it past the Set Address stage,
* it may not have the real_port set correctly.
*/
if (virt_dev->real_port == 0 ||
virt_dev->real_port > HCS_MAX_PORTS(xhci->hcs_params1)) {
xhci_dbg(xhci, "Bad real port.\n");
return;
}
tt_list_head = &(xhci->rh_bw[virt_dev->real_port - 1].tts);
list_for_each_entry_safe(tt_info, next, tt_list_head, tt_list) {
/* Multi-TT hubs will have more than one entry */
if (tt_info->slot_id == slot_id) {
slot_found = true;
list_del(&tt_info->tt_list);
kfree(tt_info);
} else if (slot_found) {
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
break;
}
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
}
}
int xhci_alloc_tt_info(struct xhci_hcd *xhci,
struct xhci_virt_device *virt_dev,
struct usb_device *hdev,
struct usb_tt *tt, gfp_t mem_flags)
{
struct xhci_tt_bw_info *tt_info;
unsigned int num_ports;
int i, j;
if (!tt->multi)
num_ports = 1;
else
num_ports = hdev->maxchild;
for (i = 0; i < num_ports; i++, tt_info++) {
struct xhci_interval_bw_table *bw_table;
tt_info = kzalloc(sizeof(*tt_info), mem_flags);
if (!tt_info)
goto free_tts;
INIT_LIST_HEAD(&tt_info->tt_list);
list_add(&tt_info->tt_list,
&xhci->rh_bw[virt_dev->real_port - 1].tts);
tt_info->slot_id = virt_dev->udev->slot_id;
if (tt->multi)
tt_info->ttport = i+1;
bw_table = &tt_info->bw_table;
for (j = 0; j < XHCI_MAX_INTERVAL; j++)
INIT_LIST_HEAD(&bw_table->interval_bw[j].endpoints);
}
return 0;
free_tts:
xhci_free_tt_info(xhci, virt_dev, virt_dev->udev->slot_id);
return -ENOMEM;
}
/* All the xhci_tds in the ring's TD list should be freed at this point.
* Should be called with xhci->lock held if there is any chance the TT lists
* will be manipulated by the configure endpoint, allocate device, or update
* hub functions while this function is removing the TT entries from the list.
*/
void xhci_free_virt_device(struct xhci_hcd *xhci, int slot_id)
{
struct xhci_virt_device *dev;
int i;
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
int old_active_eps = 0;
/* Slot ID 0 is reserved */
if (slot_id == 0 || !xhci->devs[slot_id])
return;
dev = xhci->devs[slot_id];
xhci->dcbaa->dev_context_ptrs[slot_id] = 0;
if (!dev)
return;
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
if (dev->tt_info)
old_active_eps = dev->tt_info->active_eps;
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
for (i = 0; i < 31; ++i) {
if (dev->eps[i].ring)
xhci_ring_free(xhci, dev->eps[i].ring);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (dev->eps[i].stream_info)
xhci_free_stream_info(xhci,
dev->eps[i].stream_info);
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
/* Endpoints on the TT/root port lists should have been removed
* when usb_disable_device() was called for the device.
* We can't drop them anyway, because the udev might have gone
* away by this point, and we can't tell what speed it was.
*/
if (!list_empty(&dev->eps[i].bw_endpoint_list))
xhci_warn(xhci, "Slot %u endpoint %u "
"not removed from BW list!\n",
slot_id, i);
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
}
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
/* If this is a hub, free the TT(s) from the TT list */
xhci_free_tt_info(xhci, dev, slot_id);
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
/* If necessary, update the number of active TTs on this root port */
xhci_update_tt_active_eps(xhci, dev, old_active_eps);
if (dev->ring_cache) {
for (i = 0; i < dev->num_rings_cached; i++)
xhci_ring_free(xhci, dev->ring_cache[i]);
kfree(dev->ring_cache);
}
if (dev->in_ctx)
xhci_free_container_ctx(xhci, dev->in_ctx);
if (dev->out_ctx)
xhci_free_container_ctx(xhci, dev->out_ctx);
kfree(xhci->devs[slot_id]);
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
xhci->devs[slot_id] = NULL;
}
int xhci_alloc_virt_device(struct xhci_hcd *xhci, int slot_id,
struct usb_device *udev, gfp_t flags)
{
struct xhci_virt_device *dev;
int i;
/* Slot ID 0 is reserved */
if (slot_id == 0 || xhci->devs[slot_id]) {
xhci_warn(xhci, "Bad Slot ID %d\n", slot_id);
return 0;
}
xhci->devs[slot_id] = kzalloc(sizeof(*xhci->devs[slot_id]), flags);
if (!xhci->devs[slot_id])
return 0;
dev = xhci->devs[slot_id];
/* Allocate the (output) device context that will be used in the HC. */
dev->out_ctx = xhci_alloc_container_ctx(xhci, XHCI_CTX_TYPE_DEVICE, flags);
if (!dev->out_ctx)
goto fail;
xhci_dbg(xhci, "Slot %d output ctx = 0x%llx (dma)\n", slot_id,
(unsigned long long)dev->out_ctx->dma);
/* Allocate the (input) device context for address device command */
dev->in_ctx = xhci_alloc_container_ctx(xhci, XHCI_CTX_TYPE_INPUT, flags);
if (!dev->in_ctx)
goto fail;
xhci_dbg(xhci, "Slot %d input ctx = 0x%llx (dma)\n", slot_id,
(unsigned long long)dev->in_ctx->dma);
USB: xhci: Add watchdog timer for URB cancellation. In order to giveback a canceled URB, we must ensure that the xHCI hardware will not access the buffer in an URB. We can't modify the buffer pointers on endpoint rings without issuing and waiting for a stop endpoint command. Since URBs can be canceled in interrupt context, we can't wait on that command. The old code trusted that the host controller would respond to the command, and would giveback the URBs in the event handler. If the hardware never responds to the stop endpoint command, the URBs will never be completed, and we might hang the USB subsystem. Implement a watchdog timer that is spawned whenever a stop endpoint command is queued. If a stop endpoint command event is found on the event ring during an interrupt, we need to stop the watchdog timer with del_timer(). Since del_timer() can fail if the timer is running and waiting on the xHCI lock, we need a way to signal to the timer that everything is fine and it should exit. If we simply clear EP_HALT_PENDING, a new stop endpoint command could sneak in and set it before the watchdog timer can grab the lock. Instead we use a combination of the EP_HALT_PENDING flag and a counter for the number of pending stop endpoint commands (xhci_virt_ep->stop_cmds_pending). If we need to cancel the watchdog timer and del_timer() succeeds, we decrement the number of pending stop endpoint commands. If del_timer() fails, we leave the number of pending stop endpoint commands alone. In either case, we clear the EP_HALT_PENDING flag. The timer will decrement the number of pending stop endpoint commands once it obtains the lock. If the timer is the tail end of the last stop endpoint command (xhci_virt_ep->stop_cmds_pending == 0), and the endpoint's command is still pending (EP_HALT_PENDING is set), we assume the host is dying. The watchdog timer will set XHCI_STATE_DYING, try to halt the xHCI host, and give back all pending URBs. Various other places in the driver need to check whether the xHCI host is dying. If the interrupt handler ever notices, it should immediately stop processing events. The URB enqueue function should also return -ESHUTDOWN. The URB dequeue function should simply return the value of usb_hcd_check_unlink_urb() and the watchdog timer will take care of giving the URB back. When a device is disconnected, the xHCI hardware structures should be freed without issuing a disable slot command (since the hardware probably won't respond to it anyway). The debugging polling loop should stop polling if the host is dying. When a device is disconnected, any pending watchdog timers are killed with del_timer_sync(). It must be synchronous so that the watchdog timer doesn't attempt to access the freed endpoint structures. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-10-28 01:57:01 +08:00
/* Initialize the cancellation list and watchdog timers for each ep */
for (i = 0; i < 31; i++) {
xhci_init_endpoint_timer(xhci, &dev->eps[i]);
INIT_LIST_HEAD(&dev->eps[i].cancelled_td_list);
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
INIT_LIST_HEAD(&dev->eps[i].bw_endpoint_list);
USB: xhci: Add watchdog timer for URB cancellation. In order to giveback a canceled URB, we must ensure that the xHCI hardware will not access the buffer in an URB. We can't modify the buffer pointers on endpoint rings without issuing and waiting for a stop endpoint command. Since URBs can be canceled in interrupt context, we can't wait on that command. The old code trusted that the host controller would respond to the command, and would giveback the URBs in the event handler. If the hardware never responds to the stop endpoint command, the URBs will never be completed, and we might hang the USB subsystem. Implement a watchdog timer that is spawned whenever a stop endpoint command is queued. If a stop endpoint command event is found on the event ring during an interrupt, we need to stop the watchdog timer with del_timer(). Since del_timer() can fail if the timer is running and waiting on the xHCI lock, we need a way to signal to the timer that everything is fine and it should exit. If we simply clear EP_HALT_PENDING, a new stop endpoint command could sneak in and set it before the watchdog timer can grab the lock. Instead we use a combination of the EP_HALT_PENDING flag and a counter for the number of pending stop endpoint commands (xhci_virt_ep->stop_cmds_pending). If we need to cancel the watchdog timer and del_timer() succeeds, we decrement the number of pending stop endpoint commands. If del_timer() fails, we leave the number of pending stop endpoint commands alone. In either case, we clear the EP_HALT_PENDING flag. The timer will decrement the number of pending stop endpoint commands once it obtains the lock. If the timer is the tail end of the last stop endpoint command (xhci_virt_ep->stop_cmds_pending == 0), and the endpoint's command is still pending (EP_HALT_PENDING is set), we assume the host is dying. The watchdog timer will set XHCI_STATE_DYING, try to halt the xHCI host, and give back all pending URBs. Various other places in the driver need to check whether the xHCI host is dying. If the interrupt handler ever notices, it should immediately stop processing events. The URB enqueue function should also return -ESHUTDOWN. The URB dequeue function should simply return the value of usb_hcd_check_unlink_urb() and the watchdog timer will take care of giving the URB back. When a device is disconnected, the xHCI hardware structures should be freed without issuing a disable slot command (since the hardware probably won't respond to it anyway). The debugging polling loop should stop polling if the host is dying. When a device is disconnected, any pending watchdog timers are killed with del_timer_sync(). It must be synchronous so that the watchdog timer doesn't attempt to access the freed endpoint structures. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-10-28 01:57:01 +08:00
}
/* Allocate endpoint 0 ring */
dev->eps[0].ring = xhci_ring_alloc(xhci, 2, 1, TYPE_CTRL, flags);
if (!dev->eps[0].ring)
goto fail;
/* Allocate pointers to the ring cache */
dev->ring_cache = kzalloc(
sizeof(struct xhci_ring *)*XHCI_MAX_RINGS_CACHED,
flags);
if (!dev->ring_cache)
goto fail;
dev->num_rings_cached = 0;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
init_completion(&dev->cmd_completion);
INIT_LIST_HEAD(&dev->cmd_list);
dev->udev = udev;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* Point to output device context in dcbaa. */
xhci->dcbaa->dev_context_ptrs[slot_id] = cpu_to_le64(dev->out_ctx->dma);
xhci_dbg(xhci, "Set slot id %d dcbaa entry %p to 0x%llx\n",
slot_id,
&xhci->dcbaa->dev_context_ptrs[slot_id],
le64_to_cpu(xhci->dcbaa->dev_context_ptrs[slot_id]));
return 1;
fail:
xhci_free_virt_device(xhci, slot_id);
return 0;
}
void xhci_copy_ep0_dequeue_into_input_ctx(struct xhci_hcd *xhci,
struct usb_device *udev)
{
struct xhci_virt_device *virt_dev;
struct xhci_ep_ctx *ep0_ctx;
struct xhci_ring *ep_ring;
virt_dev = xhci->devs[udev->slot_id];
ep0_ctx = xhci_get_ep_ctx(xhci, virt_dev->in_ctx, 0);
ep_ring = virt_dev->eps[0].ring;
/*
* FIXME we don't keep track of the dequeue pointer very well after a
* Set TR dequeue pointer, so we're setting the dequeue pointer of the
* host to our enqueue pointer. This should only be called after a
* configured device has reset, so all control transfers should have
* been completed or cancelled before the reset.
*/
ep0_ctx->deq = cpu_to_le64(xhci_trb_virt_to_dma(ep_ring->enq_seg,
ep_ring->enqueue)
| ep_ring->cycle_state);
}
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
/*
* The xHCI roothub may have ports of differing speeds in any order in the port
* status registers. xhci->port_array provides an array of the port speed for
* each offset into the port status registers.
*
* The xHCI hardware wants to know the roothub port number that the USB device
* is attached to (or the roothub port its ancestor hub is attached to). All we
* know is the index of that port under either the USB 2.0 or the USB 3.0
* roothub, but that doesn't give us the real index into the HW port status
* registers. Call xhci_find_raw_port_number() to get real index.
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
*/
static u32 xhci_find_real_port_number(struct xhci_hcd *xhci,
struct usb_device *udev)
{
struct usb_device *top_dev;
struct usb_hcd *hcd;
if (udev->speed == USB_SPEED_SUPER)
hcd = xhci->shared_hcd;
else
hcd = xhci->main_hcd;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
for (top_dev = udev; top_dev->parent && top_dev->parent->parent;
top_dev = top_dev->parent)
/* Found device below root hub */;
return xhci_find_raw_port_number(hcd, top_dev->portnum);
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
}
/* Setup an xHCI virtual device for a Set Address command */
int xhci_setup_addressable_virt_dev(struct xhci_hcd *xhci, struct usb_device *udev)
{
struct xhci_virt_device *dev;
struct xhci_ep_ctx *ep0_ctx;
struct xhci_slot_ctx *slot_ctx;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
u32 port_num;
u32 max_packets;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
struct usb_device *top_dev;
dev = xhci->devs[udev->slot_id];
/* Slot ID 0 is reserved */
if (udev->slot_id == 0 || !dev) {
xhci_warn(xhci, "Slot ID %d is not assigned to this device\n",
udev->slot_id);
return -EINVAL;
}
ep0_ctx = xhci_get_ep_ctx(xhci, dev->in_ctx, 0);
slot_ctx = xhci_get_slot_ctx(xhci, dev->in_ctx);
/* 3) Only the control endpoint is valid - one endpoint context */
slot_ctx->dev_info |= cpu_to_le32(LAST_CTX(1) | udev->route);
switch (udev->speed) {
case USB_SPEED_SUPER:
slot_ctx->dev_info |= cpu_to_le32(SLOT_SPEED_SS);
max_packets = MAX_PACKET(512);
break;
case USB_SPEED_HIGH:
slot_ctx->dev_info |= cpu_to_le32(SLOT_SPEED_HS);
max_packets = MAX_PACKET(64);
break;
/* USB core guesses at a 64-byte max packet first for FS devices */
case USB_SPEED_FULL:
slot_ctx->dev_info |= cpu_to_le32(SLOT_SPEED_FS);
max_packets = MAX_PACKET(64);
break;
case USB_SPEED_LOW:
slot_ctx->dev_info |= cpu_to_le32(SLOT_SPEED_LS);
max_packets = MAX_PACKET(8);
break;
case USB_SPEED_WIRELESS:
xhci_dbg(xhci, "FIXME xHCI doesn't support wireless speeds\n");
return -EINVAL;
break;
default:
/* Speed was set earlier, this shouldn't happen. */
return -EINVAL;
}
/* Find the root hub port this device is under */
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
port_num = xhci_find_real_port_number(xhci, udev);
if (!port_num)
return -EINVAL;
slot_ctx->dev_info2 |= cpu_to_le32(ROOT_HUB_PORT(port_num));
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
/* Set the port number in the virtual_device to the faked port number */
for (top_dev = udev; top_dev->parent && top_dev->parent->parent;
top_dev = top_dev->parent)
/* Found device below root hub */;
dev->fake_port = top_dev->portnum;
dev->real_port = port_num;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
xhci_dbg(xhci, "Set root hub portnum to %d\n", port_num);
xhci_dbg(xhci, "Set fake root hub portnum to %d\n", dev->fake_port);
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
/* Find the right bandwidth table that this device will be a part of.
* If this is a full speed device attached directly to a root port (or a
* decendent of one), it counts as a primary bandwidth domain, not a
* secondary bandwidth domain under a TT. An xhci_tt_info structure
* will never be created for the HS root hub.
*/
if (!udev->tt || !udev->tt->hub->parent) {
dev->bw_table = &xhci->rh_bw[port_num - 1].bw_table;
} else {
struct xhci_root_port_bw_info *rh_bw;
struct xhci_tt_bw_info *tt_bw;
rh_bw = &xhci->rh_bw[port_num - 1];
/* Find the right TT. */
list_for_each_entry(tt_bw, &rh_bw->tts, tt_list) {
if (tt_bw->slot_id != udev->tt->hub->slot_id)
continue;
if (!dev->udev->tt->multi ||
(udev->tt->multi &&
tt_bw->ttport == dev->udev->ttport)) {
dev->bw_table = &tt_bw->bw_table;
dev->tt_info = tt_bw;
break;
}
}
if (!dev->tt_info)
xhci_warn(xhci, "WARN: Didn't find a matching TT\n");
}
/* Is this a LS/FS device under an external HS hub? */
if (udev->tt && udev->tt->hub->parent) {
slot_ctx->tt_info = cpu_to_le32(udev->tt->hub->slot_id |
(udev->ttport << 8));
if (udev->tt->multi)
slot_ctx->dev_info |= cpu_to_le32(DEV_MTT);
}
xhci_dbg(xhci, "udev->tt = %p\n", udev->tt);
xhci_dbg(xhci, "udev->ttport = 0x%x\n", udev->ttport);
/* Step 4 - ring already allocated */
/* Step 5 */
ep0_ctx->ep_info2 = cpu_to_le32(EP_TYPE(CTRL_EP));
/* EP 0 can handle "burst" sizes of 1, so Max Burst Size field is 0 */
ep0_ctx->ep_info2 |= cpu_to_le32(MAX_BURST(0) | ERROR_COUNT(3) |
max_packets);
ep0_ctx->deq = cpu_to_le64(dev->eps[0].ring->first_seg->dma |
dev->eps[0].ring->cycle_state);
/* Steps 7 and 8 were done in xhci_alloc_virt_device() */
return 0;
}
/*
* Convert interval expressed as 2^(bInterval - 1) == interval into
* straight exponent value 2^n == interval.
*
*/
static unsigned int xhci_parse_exponent_interval(struct usb_device *udev,
struct usb_host_endpoint *ep)
{
unsigned int interval;
interval = clamp_val(ep->desc.bInterval, 1, 16) - 1;
if (interval != ep->desc.bInterval - 1)
dev_warn(&udev->dev,
"ep %#x - rounding interval to %d %sframes\n",
ep->desc.bEndpointAddress,
1 << interval,
udev->speed == USB_SPEED_FULL ? "" : "micro");
if (udev->speed == USB_SPEED_FULL) {
/*
* Full speed isoc endpoints specify interval in frames,
* not microframes. We are using microframes everywhere,
* so adjust accordingly.
*/
interval += 3; /* 1 frame = 2^3 uframes */
}
return interval;
}
/*
* Convert bInterval expressed in microframes (in 1-255 range) to exponent of
* microframes, rounded down to nearest power of 2.
*/
static unsigned int xhci_microframes_to_exponent(struct usb_device *udev,
struct usb_host_endpoint *ep, unsigned int desc_interval,
unsigned int min_exponent, unsigned int max_exponent)
{
unsigned int interval;
interval = fls(desc_interval) - 1;
interval = clamp_val(interval, min_exponent, max_exponent);
if ((1 << interval) != desc_interval)
dev_warn(&udev->dev,
"ep %#x - rounding interval to %d microframes, ep desc says %d microframes\n",
ep->desc.bEndpointAddress,
1 << interval,
desc_interval);
return interval;
}
static unsigned int xhci_parse_microframe_interval(struct usb_device *udev,
struct usb_host_endpoint *ep)
{
if (ep->desc.bInterval == 0)
return 0;
return xhci_microframes_to_exponent(udev, ep,
ep->desc.bInterval, 0, 15);
}
static unsigned int xhci_parse_frame_interval(struct usb_device *udev,
struct usb_host_endpoint *ep)
{
return xhci_microframes_to_exponent(udev, ep,
ep->desc.bInterval * 8, 3, 10);
}
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* Return the polling or NAK interval.
*
* The polling interval is expressed in "microframes". If xHCI's Interval field
* is set to N, it will service the endpoint every 2^(Interval)*125us.
*
* The NAK interval is one NAK per 1 to 255 microframes, or no NAKs if interval
* is set to 0.
*/
static unsigned int xhci_get_endpoint_interval(struct usb_device *udev,
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
struct usb_host_endpoint *ep)
{
unsigned int interval = 0;
switch (udev->speed) {
case USB_SPEED_HIGH:
/* Max NAK rate */
if (usb_endpoint_xfer_control(&ep->desc) ||
usb_endpoint_xfer_bulk(&ep->desc)) {
interval = xhci_parse_microframe_interval(udev, ep);
break;
}
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* Fall through - SS and HS isoc/int have same decoding */
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
case USB_SPEED_SUPER:
if (usb_endpoint_xfer_int(&ep->desc) ||
usb_endpoint_xfer_isoc(&ep->desc)) {
interval = xhci_parse_exponent_interval(udev, ep);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
}
break;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
case USB_SPEED_FULL:
xhci: Fix full speed bInterval encoding. Dmitry's patch dfa49c4ad120a784ef1ff0717168aa79f55a483a USB: xhci - fix math in xhci_get_endpoint_interval() introduced a bug. The USB 2.0 spec says that full speed isochronous endpoints' bInterval must be decoded as an exponent to a power of two (e.g. interval = 2^(bInterval - 1)). Full speed interrupt endpoints, on the other hand, don't use exponents, and the interval in frames is encoded straight into bInterval. Dmitry's patch was supposed to fix up the full speed isochronous to parse bInterval as an exponent, but instead it changed the *interrupt* endpoint bInterval decoding. The isochronous endpoint encoding was the same. This caused full speed devices with interrupt endpoints (including mice, hubs, and USB to ethernet devices) to fail under NEC 0.96 xHCI host controllers: [ 100.909818] xhci_hcd 0000:06:00.0: add ep 0x83, slot id 1, new drop flags = 0x0, new add flags = 0x99, new slot info = 0x38100000 [ 100.909821] xhci_hcd 0000:06:00.0: xhci_check_bandwidth called for udev ffff88011f0ea000 ... [ 100.910187] xhci_hcd 0000:06:00.0: ERROR: unexpected command completion code 0x11. [ 100.910190] xhci_hcd 0000:06:00.0: xhci_reset_bandwidth called for udev ffff88011f0ea000 When the interrupt endpoint was added and a Configure Endpoint command was issued to the host, the host controller would return a very odd error message (0x11 means "Slot Not Enabled", which isn't true because the slot was enabled). Probably the host controller was getting very confused with the bad encoding. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: Dmitry Torokhov <dtor@vmware.com> Reported-by: Thomas Lindroth <thomas.lindroth@gmail.com> Tested-by: Thomas Lindroth <thomas.lindroth@gmail.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-05-14 04:10:01 +08:00
if (usb_endpoint_xfer_isoc(&ep->desc)) {
interval = xhci_parse_exponent_interval(udev, ep);
break;
}
/*
xhci: Fix full speed bInterval encoding. Dmitry's patch dfa49c4ad120a784ef1ff0717168aa79f55a483a USB: xhci - fix math in xhci_get_endpoint_interval() introduced a bug. The USB 2.0 spec says that full speed isochronous endpoints' bInterval must be decoded as an exponent to a power of two (e.g. interval = 2^(bInterval - 1)). Full speed interrupt endpoints, on the other hand, don't use exponents, and the interval in frames is encoded straight into bInterval. Dmitry's patch was supposed to fix up the full speed isochronous to parse bInterval as an exponent, but instead it changed the *interrupt* endpoint bInterval decoding. The isochronous endpoint encoding was the same. This caused full speed devices with interrupt endpoints (including mice, hubs, and USB to ethernet devices) to fail under NEC 0.96 xHCI host controllers: [ 100.909818] xhci_hcd 0000:06:00.0: add ep 0x83, slot id 1, new drop flags = 0x0, new add flags = 0x99, new slot info = 0x38100000 [ 100.909821] xhci_hcd 0000:06:00.0: xhci_check_bandwidth called for udev ffff88011f0ea000 ... [ 100.910187] xhci_hcd 0000:06:00.0: ERROR: unexpected command completion code 0x11. [ 100.910190] xhci_hcd 0000:06:00.0: xhci_reset_bandwidth called for udev ffff88011f0ea000 When the interrupt endpoint was added and a Configure Endpoint command was issued to the host, the host controller would return a very odd error message (0x11 means "Slot Not Enabled", which isn't true because the slot was enabled). Probably the host controller was getting very confused with the bad encoding. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: Dmitry Torokhov <dtor@vmware.com> Reported-by: Thomas Lindroth <thomas.lindroth@gmail.com> Tested-by: Thomas Lindroth <thomas.lindroth@gmail.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-05-14 04:10:01 +08:00
* Fall through for interrupt endpoint interval decoding
* since it uses the same rules as low speed interrupt
* endpoints.
*/
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
case USB_SPEED_LOW:
if (usb_endpoint_xfer_int(&ep->desc) ||
usb_endpoint_xfer_isoc(&ep->desc)) {
interval = xhci_parse_frame_interval(udev, ep);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
}
break;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
default:
BUG();
}
return EP_INTERVAL(interval);
}
/* The "Mult" field in the endpoint context is only set for SuperSpeed isoc eps.
* High speed endpoint descriptors can define "the number of additional
* transaction opportunities per microframe", but that goes in the Max Burst
* endpoint context field.
*/
static u32 xhci_get_endpoint_mult(struct usb_device *udev,
struct usb_host_endpoint *ep)
{
if (udev->speed != USB_SPEED_SUPER ||
!usb_endpoint_xfer_isoc(&ep->desc))
return 0;
return ep->ss_ep_comp.bmAttributes;
}
static u32 xhci_get_endpoint_type(struct usb_device *udev,
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
struct usb_host_endpoint *ep)
{
int in;
u32 type;
in = usb_endpoint_dir_in(&ep->desc);
if (usb_endpoint_xfer_control(&ep->desc)) {
type = EP_TYPE(CTRL_EP);
} else if (usb_endpoint_xfer_bulk(&ep->desc)) {
if (in)
type = EP_TYPE(BULK_IN_EP);
else
type = EP_TYPE(BULK_OUT_EP);
} else if (usb_endpoint_xfer_isoc(&ep->desc)) {
if (in)
type = EP_TYPE(ISOC_IN_EP);
else
type = EP_TYPE(ISOC_OUT_EP);
} else if (usb_endpoint_xfer_int(&ep->desc)) {
if (in)
type = EP_TYPE(INT_IN_EP);
else
type = EP_TYPE(INT_OUT_EP);
} else {
type = 0;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
}
return type;
}
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
/* Return the maximum endpoint service interval time (ESIT) payload.
* Basically, this is the maxpacket size, multiplied by the burst size
* and mult size.
*/
static u32 xhci_get_max_esit_payload(struct xhci_hcd *xhci,
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
struct usb_device *udev,
struct usb_host_endpoint *ep)
{
int max_burst;
int max_packet;
/* Only applies for interrupt or isochronous endpoints */
if (usb_endpoint_xfer_control(&ep->desc) ||
usb_endpoint_xfer_bulk(&ep->desc))
return 0;
if (udev->speed == USB_SPEED_SUPER)
return le16_to_cpu(ep->ss_ep_comp.wBytesPerInterval);
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
USB: use usb_endpoint_maxp() instead of le16_to_cpu() Now ${LINUX}/drivers/usb/* can use usb_endpoint_maxp(desc) to get maximum packet size instead of le16_to_cpu(desc->wMaxPacketSize). This patch fix it up Cc: Armin Fuerst <fuerst@in.tum.de> Cc: Pavel Machek <pavel@ucw.cz> Cc: Johannes Erdfelt <johannes@erdfelt.com> Cc: Vojtech Pavlik <vojtech@suse.cz> Cc: Oliver Neukum <oliver@neukum.name> Cc: David Kubicek <dave@awk.cz> Cc: Johan Hovold <jhovold@gmail.com> Cc: Brad Hards <bhards@bigpond.net.au> Acked-by: Felipe Balbi <balbi@ti.com> Cc: Sebastian Andrzej Siewior <bigeasy@linutronix.de> Cc: Thomas Dahlmann <dahlmann.thomas@arcor.de> Cc: David Brownell <david-b@pacbell.net> Cc: David Lopo <dlopo@chipidea.mips.com> Cc: Alan Stern <stern@rowland.harvard.edu> Cc: Michal Nazarewicz <m.nazarewicz@samsung.com> Cc: Xie Xiaobo <X.Xie@freescale.com> Cc: Li Yang <leoli@freescale.com> Cc: Jiang Bo <tanya.jiang@freescale.com> Cc: Yuan-hsin Chen <yhchen@faraday-tech.com> Cc: Darius Augulis <augulis.darius@gmail.com> Cc: Xiaochen Shen <xiaochen.shen@intel.com> Cc: Yoshihiro Shimoda <yoshihiro.shimoda.uh@renesas.com> Cc: OKI SEMICONDUCTOR, <toshiharu-linux@dsn.okisemi.com> Cc: Robert Jarzmik <robert.jarzmik@free.fr> Cc: Ben Dooks <ben@simtec.co.uk> Cc: Thomas Abraham <thomas.ab@samsung.com> Cc: Herbert Pötzl <herbert@13thfloor.at> Cc: Arnaud Patard <arnaud.patard@rtp-net.org> Cc: Roman Weissgaerber <weissg@vienna.at> Acked-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: Tony Olech <tony.olech@elandigitalsystems.com> Cc: Florian Floe Echtler <echtler@fs.tum.de> Cc: Christian Lucht <lucht@codemercs.com> Cc: Juergen Stuber <starblue@sourceforge.net> Cc: Georges Toth <g.toth@e-biz.lu> Cc: Bill Ryder <bryder@sgi.com> Cc: Kuba Ober <kuba@mareimbrium.org> Cc: Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com> Signed-off-by: Kuninori Morimoto <kuninori.morimoto.gx@renesas.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-08-23 18:12:03 +08:00
max_packet = GET_MAX_PACKET(usb_endpoint_maxp(&ep->desc));
max_burst = (usb_endpoint_maxp(&ep->desc) & 0x1800) >> 11;
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
/* A 0 in max burst means 1 transfer per ESIT */
return max_packet * (max_burst + 1);
}
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
/* Set up an endpoint with one ring segment. Do not allocate stream rings.
* Drivers will have to call usb_alloc_streams() to do that.
*/
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
int xhci_endpoint_init(struct xhci_hcd *xhci,
struct xhci_virt_device *virt_dev,
struct usb_device *udev,
struct usb_host_endpoint *ep,
gfp_t mem_flags)
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
{
unsigned int ep_index;
struct xhci_ep_ctx *ep_ctx;
struct xhci_ring *ep_ring;
unsigned int max_packet;
unsigned int max_burst;
enum xhci_ring_type type;
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
u32 max_esit_payload;
u32 endpoint_type;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
ep_index = xhci_get_endpoint_index(&ep->desc);
ep_ctx = xhci_get_ep_ctx(xhci, virt_dev->in_ctx, ep_index);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
endpoint_type = xhci_get_endpoint_type(udev, ep);
if (!endpoint_type)
return -EINVAL;
ep_ctx->ep_info2 = cpu_to_le32(endpoint_type);
type = usb_endpoint_type(&ep->desc);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* Set up the endpoint ring */
virt_dev->eps[ep_index].new_ring =
xhci_ring_alloc(xhci, 2, 1, type, mem_flags);
if (!virt_dev->eps[ep_index].new_ring) {
/* Attempt to use the ring cache */
if (virt_dev->num_rings_cached == 0)
return -ENOMEM;
virt_dev->eps[ep_index].new_ring =
virt_dev->ring_cache[virt_dev->num_rings_cached];
virt_dev->ring_cache[virt_dev->num_rings_cached] = NULL;
virt_dev->num_rings_cached--;
xhci_reinit_cached_ring(xhci, virt_dev->eps[ep_index].new_ring,
1, type);
}
virt_dev->eps[ep_index].skip = false;
ep_ring = virt_dev->eps[ep_index].new_ring;
ep_ctx->deq = cpu_to_le64(ep_ring->first_seg->dma | ep_ring->cycle_state);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
ep_ctx->ep_info = cpu_to_le32(xhci_get_endpoint_interval(udev, ep)
| EP_MULT(xhci_get_endpoint_mult(udev, ep)));
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* FIXME dig Mult and streams info out of ep companion desc */
/* Allow 3 retries for everything but isoc;
* CErr shall be set to 0 for Isoch endpoints.
*/
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
if (!usb_endpoint_xfer_isoc(&ep->desc))
ep_ctx->ep_info2 |= cpu_to_le32(ERROR_COUNT(3));
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
else
ep_ctx->ep_info2 |= cpu_to_le32(ERROR_COUNT(0));
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* Set the max packet size and max burst */
max_packet = GET_MAX_PACKET(usb_endpoint_maxp(&ep->desc));
max_burst = 0;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
switch (udev->speed) {
case USB_SPEED_SUPER:
/* dig out max burst from ep companion desc */
max_burst = ep->ss_ep_comp.bMaxBurst;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
break;
case USB_SPEED_HIGH:
/* Some devices get this wrong */
if (usb_endpoint_xfer_bulk(&ep->desc))
max_packet = 512;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* bits 11:12 specify the number of additional transaction
* opportunities per microframe (USB 2.0, section 9.6.6)
*/
if (usb_endpoint_xfer_isoc(&ep->desc) ||
usb_endpoint_xfer_int(&ep->desc)) {
USB: use usb_endpoint_maxp() instead of le16_to_cpu() Now ${LINUX}/drivers/usb/* can use usb_endpoint_maxp(desc) to get maximum packet size instead of le16_to_cpu(desc->wMaxPacketSize). This patch fix it up Cc: Armin Fuerst <fuerst@in.tum.de> Cc: Pavel Machek <pavel@ucw.cz> Cc: Johannes Erdfelt <johannes@erdfelt.com> Cc: Vojtech Pavlik <vojtech@suse.cz> Cc: Oliver Neukum <oliver@neukum.name> Cc: David Kubicek <dave@awk.cz> Cc: Johan Hovold <jhovold@gmail.com> Cc: Brad Hards <bhards@bigpond.net.au> Acked-by: Felipe Balbi <balbi@ti.com> Cc: Sebastian Andrzej Siewior <bigeasy@linutronix.de> Cc: Thomas Dahlmann <dahlmann.thomas@arcor.de> Cc: David Brownell <david-b@pacbell.net> Cc: David Lopo <dlopo@chipidea.mips.com> Cc: Alan Stern <stern@rowland.harvard.edu> Cc: Michal Nazarewicz <m.nazarewicz@samsung.com> Cc: Xie Xiaobo <X.Xie@freescale.com> Cc: Li Yang <leoli@freescale.com> Cc: Jiang Bo <tanya.jiang@freescale.com> Cc: Yuan-hsin Chen <yhchen@faraday-tech.com> Cc: Darius Augulis <augulis.darius@gmail.com> Cc: Xiaochen Shen <xiaochen.shen@intel.com> Cc: Yoshihiro Shimoda <yoshihiro.shimoda.uh@renesas.com> Cc: OKI SEMICONDUCTOR, <toshiharu-linux@dsn.okisemi.com> Cc: Robert Jarzmik <robert.jarzmik@free.fr> Cc: Ben Dooks <ben@simtec.co.uk> Cc: Thomas Abraham <thomas.ab@samsung.com> Cc: Herbert Pötzl <herbert@13thfloor.at> Cc: Arnaud Patard <arnaud.patard@rtp-net.org> Cc: Roman Weissgaerber <weissg@vienna.at> Acked-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: Tony Olech <tony.olech@elandigitalsystems.com> Cc: Florian Floe Echtler <echtler@fs.tum.de> Cc: Christian Lucht <lucht@codemercs.com> Cc: Juergen Stuber <starblue@sourceforge.net> Cc: Georges Toth <g.toth@e-biz.lu> Cc: Bill Ryder <bryder@sgi.com> Cc: Kuba Ober <kuba@mareimbrium.org> Cc: Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com> Signed-off-by: Kuninori Morimoto <kuninori.morimoto.gx@renesas.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-08-23 18:12:03 +08:00
max_burst = (usb_endpoint_maxp(&ep->desc)
& 0x1800) >> 11;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
}
break;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
case USB_SPEED_FULL:
case USB_SPEED_LOW:
break;
default:
BUG();
}
ep_ctx->ep_info2 |= cpu_to_le32(MAX_PACKET(max_packet) |
MAX_BURST(max_burst));
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
max_esit_payload = xhci_get_max_esit_payload(xhci, udev, ep);
ep_ctx->tx_info = cpu_to_le32(MAX_ESIT_PAYLOAD_FOR_EP(max_esit_payload));
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
/*
* XXX no idea how to calculate the average TRB buffer length for bulk
* endpoints, as the driver gives us no clue how big each scatter gather
* list entry (or buffer) is going to be.
*
* For isochronous and interrupt endpoints, we set it to the max
* available, until we have new API in the USB core to allow drivers to
* declare how much bandwidth they actually need.
*
* Normally, it would be calculated by taking the total of the buffer
* lengths in the TD and then dividing by the number of TRBs in a TD,
* including link TRBs, No-op TRBs, and Event data TRBs. Since we don't
* use Event Data TRBs, and we don't chain in a link TRB on short
* transfers, we're basically dividing by 1.
*
* xHCI 1.0 specification indicates that the Average TRB Length should
* be set to 8 for control endpoints.
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
*/
if (usb_endpoint_xfer_control(&ep->desc) && xhci->hci_version == 0x100)
ep_ctx->tx_info |= cpu_to_le32(AVG_TRB_LENGTH_FOR_EP(8));
else
ep_ctx->tx_info |=
cpu_to_le32(AVG_TRB_LENGTH_FOR_EP(max_esit_payload));
USB: xhci: properly set endpoint context fields for periodic eps. For periodic endpoints, we must let the xHCI hardware know the maximum payload an endpoint can transfer in one service interval. The xHCI specification refers to this as the Maximum Endpoint Service Interval Time Payload (Max ESIT Payload). This is used by the hardware for bandwidth management and scheduling of packets. For SuperSpeed endpoints, the maximum is calculated by multiplying the max packet size by the number of bursts and the number of opportunities to transfer within a service interval (the Mult field of the SuperSpeed Endpoint companion descriptor). Devices advertise this in the wBytesPerInterval field of their SuperSpeed Endpoint Companion Descriptor. For high speed devices, this is taken by multiplying the max packet size by the "number of additional transaction opportunities per microframe" (the high bits of the wMaxPacketSize field in the endpoint descriptor). For FS/LS devices, this is just the max packet size. The other thing we must set in the endpoint context is the Average TRB Length. This is supposed to be the average of the total bytes in the transfer descriptor (TD), divided by the number of transfer request blocks (TRBs) it takes to describe the TD. This gives the host controller an indication of whether the driver will be enqueuing a scatter gather list with many entries comprised of small buffers, or one contiguous buffer. It also takes into account the number of extra TRBs you need for every TD. This includes No-op TRBs and Link TRBs used to link ring segments together. Some drivers may choose to chain an Event Data TRB on the end of every TD, thus increasing the average number of TRBs per TD. The Linux xHCI driver does not use Event Data TRBs. In theory, if there was an API to allow drivers to state what their bandwidth requirements are, we could set this field accurately. For now, we set it to the same number as the Max ESIT payload. The Average TRB Length should also be set for bulk and control endpoints, but I have no idea how to guess what it should be. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Cc: stable <stable@kernel.org> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-16 23:07:27 +08:00
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
/* FIXME Debug endpoint context */
return 0;
}
void xhci_endpoint_zero(struct xhci_hcd *xhci,
struct xhci_virt_device *virt_dev,
struct usb_host_endpoint *ep)
{
unsigned int ep_index;
struct xhci_ep_ctx *ep_ctx;
ep_index = xhci_get_endpoint_index(&ep->desc);
ep_ctx = xhci_get_ep_ctx(xhci, virt_dev->in_ctx, ep_index);
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
ep_ctx->ep_info = 0;
ep_ctx->ep_info2 = 0;
ep_ctx->deq = 0;
USB: xhci: Bandwidth allocation support Since the xHCI host controller hardware (xHC) has an internal schedule, it needs a better representation of what devices are consuming bandwidth on the bus. Each device is represented by a device context, with data about the device, endpoints, and pointers to each endpoint ring. We need to update the endpoint information for a device context before a new configuration or alternate interface setting is selected. We setup an input device context with modified endpoint information and newly allocated endpoint rings, and then submit a Configure Endpoint Command to the hardware. The host controller can reject the new configuration if it exceeds the bus bandwidth, or the host controller doesn't have enough internal resources for the configuration. If the command fails, we still have the older device context with the previous configuration. If the command succeeds, we free the old endpoint rings. The root hub isn't a real device, so always say yes to any bandwidth changes for it. The USB core will enable, disable, and then enable endpoint 0 several times during the initialization sequence. The device will always have an endpoint ring for endpoint 0 and bandwidth allocated for that, unless the device is disconnected or gets a SetAddress 0 request. So we don't pay attention for when xhci_check_bandwidth() is called for a re-add of endpoint 0. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:58:38 +08:00
ep_ctx->tx_info = 0;
/* Don't free the endpoint ring until the set interface or configuration
* request succeeds.
*/
}
void xhci_clear_endpoint_bw_info(struct xhci_bw_info *bw_info)
{
bw_info->ep_interval = 0;
bw_info->mult = 0;
bw_info->num_packets = 0;
bw_info->max_packet_size = 0;
bw_info->type = 0;
bw_info->max_esit_payload = 0;
}
void xhci_update_bw_info(struct xhci_hcd *xhci,
struct xhci_container_ctx *in_ctx,
struct xhci_input_control_ctx *ctrl_ctx,
struct xhci_virt_device *virt_dev)
{
struct xhci_bw_info *bw_info;
struct xhci_ep_ctx *ep_ctx;
unsigned int ep_type;
int i;
for (i = 1; i < 31; ++i) {
bw_info = &virt_dev->eps[i].bw_info;
/* We can't tell what endpoint type is being dropped, but
* unconditionally clearing the bandwidth info for non-periodic
* endpoints should be harmless because the info will never be
* set in the first place.
*/
if (!EP_IS_ADDED(ctrl_ctx, i) && EP_IS_DROPPED(ctrl_ctx, i)) {
/* Dropped endpoint */
xhci_clear_endpoint_bw_info(bw_info);
continue;
}
if (EP_IS_ADDED(ctrl_ctx, i)) {
ep_ctx = xhci_get_ep_ctx(xhci, in_ctx, i);
ep_type = CTX_TO_EP_TYPE(le32_to_cpu(ep_ctx->ep_info2));
/* Ignore non-periodic endpoints */
if (ep_type != ISOC_OUT_EP && ep_type != INT_OUT_EP &&
ep_type != ISOC_IN_EP &&
ep_type != INT_IN_EP)
continue;
/* Added or changed endpoint */
bw_info->ep_interval = CTX_TO_EP_INTERVAL(
le32_to_cpu(ep_ctx->ep_info));
/* Number of packets and mult are zero-based in the
* input context, but we want one-based for the
* interval table.
*/
bw_info->mult = CTX_TO_EP_MULT(
le32_to_cpu(ep_ctx->ep_info)) + 1;
bw_info->num_packets = CTX_TO_MAX_BURST(
le32_to_cpu(ep_ctx->ep_info2)) + 1;
bw_info->max_packet_size = MAX_PACKET_DECODED(
le32_to_cpu(ep_ctx->ep_info2));
bw_info->type = ep_type;
bw_info->max_esit_payload = CTX_TO_MAX_ESIT_PAYLOAD(
le32_to_cpu(ep_ctx->tx_info));
}
}
}
/* Copy output xhci_ep_ctx to the input xhci_ep_ctx copy.
* Useful when you want to change one particular aspect of the endpoint and then
* issue a configure endpoint command.
*/
void xhci_endpoint_copy(struct xhci_hcd *xhci,
struct xhci_container_ctx *in_ctx,
struct xhci_container_ctx *out_ctx,
unsigned int ep_index)
{
struct xhci_ep_ctx *out_ep_ctx;
struct xhci_ep_ctx *in_ep_ctx;
out_ep_ctx = xhci_get_ep_ctx(xhci, out_ctx, ep_index);
in_ep_ctx = xhci_get_ep_ctx(xhci, in_ctx, ep_index);
in_ep_ctx->ep_info = out_ep_ctx->ep_info;
in_ep_ctx->ep_info2 = out_ep_ctx->ep_info2;
in_ep_ctx->deq = out_ep_ctx->deq;
in_ep_ctx->tx_info = out_ep_ctx->tx_info;
}
/* Copy output xhci_slot_ctx to the input xhci_slot_ctx.
* Useful when you want to change one particular aspect of the endpoint and then
* issue a configure endpoint command. Only the context entries field matters,
* but we'll copy the whole thing anyway.
*/
void xhci_slot_copy(struct xhci_hcd *xhci,
struct xhci_container_ctx *in_ctx,
struct xhci_container_ctx *out_ctx)
{
struct xhci_slot_ctx *in_slot_ctx;
struct xhci_slot_ctx *out_slot_ctx;
in_slot_ctx = xhci_get_slot_ctx(xhci, in_ctx);
out_slot_ctx = xhci_get_slot_ctx(xhci, out_ctx);
in_slot_ctx->dev_info = out_slot_ctx->dev_info;
in_slot_ctx->dev_info2 = out_slot_ctx->dev_info2;
in_slot_ctx->tt_info = out_slot_ctx->tt_info;
in_slot_ctx->dev_state = out_slot_ctx->dev_state;
}
/* Set up the scratchpad buffer array and scratchpad buffers, if needed. */
static int scratchpad_alloc(struct xhci_hcd *xhci, gfp_t flags)
{
int i;
struct device *dev = xhci_to_hcd(xhci)->self.controller;
int num_sp = HCS_MAX_SCRATCHPAD(xhci->hcs_params2);
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Allocating %d scratchpad buffers", num_sp);
if (!num_sp)
return 0;
xhci->scratchpad = kzalloc(sizeof(*xhci->scratchpad), flags);
if (!xhci->scratchpad)
goto fail_sp;
xhci->scratchpad->sp_array = dma_alloc_coherent(dev,
num_sp * sizeof(u64),
&xhci->scratchpad->sp_dma, flags);
if (!xhci->scratchpad->sp_array)
goto fail_sp2;
xhci->scratchpad->sp_buffers = kzalloc(sizeof(void *) * num_sp, flags);
if (!xhci->scratchpad->sp_buffers)
goto fail_sp3;
xhci->scratchpad->sp_dma_buffers =
kzalloc(sizeof(dma_addr_t) * num_sp, flags);
if (!xhci->scratchpad->sp_dma_buffers)
goto fail_sp4;
xhci->dcbaa->dev_context_ptrs[0] = cpu_to_le64(xhci->scratchpad->sp_dma);
for (i = 0; i < num_sp; i++) {
dma_addr_t dma;
void *buf = dma_alloc_coherent(dev, xhci->page_size, &dma,
flags);
if (!buf)
goto fail_sp5;
xhci->scratchpad->sp_array[i] = dma;
xhci->scratchpad->sp_buffers[i] = buf;
xhci->scratchpad->sp_dma_buffers[i] = dma;
}
return 0;
fail_sp5:
for (i = i - 1; i >= 0; i--) {
dma_free_coherent(dev, xhci->page_size,
xhci->scratchpad->sp_buffers[i],
xhci->scratchpad->sp_dma_buffers[i]);
}
kfree(xhci->scratchpad->sp_dma_buffers);
fail_sp4:
kfree(xhci->scratchpad->sp_buffers);
fail_sp3:
dma_free_coherent(dev, num_sp * sizeof(u64),
xhci->scratchpad->sp_array,
xhci->scratchpad->sp_dma);
fail_sp2:
kfree(xhci->scratchpad);
xhci->scratchpad = NULL;
fail_sp:
return -ENOMEM;
}
static void scratchpad_free(struct xhci_hcd *xhci)
{
int num_sp;
int i;
struct device *dev = xhci_to_hcd(xhci)->self.controller;
if (!xhci->scratchpad)
return;
num_sp = HCS_MAX_SCRATCHPAD(xhci->hcs_params2);
for (i = 0; i < num_sp; i++) {
dma_free_coherent(dev, xhci->page_size,
xhci->scratchpad->sp_buffers[i],
xhci->scratchpad->sp_dma_buffers[i]);
}
kfree(xhci->scratchpad->sp_dma_buffers);
kfree(xhci->scratchpad->sp_buffers);
dma_free_coherent(dev, num_sp * sizeof(u64),
xhci->scratchpad->sp_array,
xhci->scratchpad->sp_dma);
kfree(xhci->scratchpad);
xhci->scratchpad = NULL;
}
struct xhci_command *xhci_alloc_command(struct xhci_hcd *xhci,
bool allocate_in_ctx, bool allocate_completion,
gfp_t mem_flags)
{
struct xhci_command *command;
command = kzalloc(sizeof(*command), mem_flags);
if (!command)
return NULL;
if (allocate_in_ctx) {
command->in_ctx =
xhci_alloc_container_ctx(xhci, XHCI_CTX_TYPE_INPUT,
mem_flags);
if (!command->in_ctx) {
kfree(command);
return NULL;
}
}
if (allocate_completion) {
command->completion =
kzalloc(sizeof(struct completion), mem_flags);
if (!command->completion) {
xhci_free_container_ctx(xhci, command->in_ctx);
kfree(command);
return NULL;
}
init_completion(command->completion);
}
command->status = 0;
INIT_LIST_HEAD(&command->cmd_list);
return command;
}
void xhci_urb_free_priv(struct xhci_hcd *xhci, struct urb_priv *urb_priv)
{
if (urb_priv) {
kfree(urb_priv->td[0]);
kfree(urb_priv);
}
}
void xhci_free_command(struct xhci_hcd *xhci,
struct xhci_command *command)
{
xhci_free_container_ctx(xhci,
command->in_ctx);
kfree(command->completion);
kfree(command);
}
void xhci_mem_cleanup(struct xhci_hcd *xhci)
{
struct device *dev = xhci_to_hcd(xhci)->self.controller;
struct xhci_cd *cur_cd, *next_cd;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
int size;
int i, j, num_ports;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* Free the Event Ring Segment Table and the actual Event Ring */
size = sizeof(struct xhci_erst_entry)*(xhci->erst.num_entries);
if (xhci->erst.entries)
dma_free_coherent(dev, size,
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci->erst.entries, xhci->erst.erst_dma_addr);
xhci->erst.entries = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "Freed ERST");
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (xhci->event_ring)
xhci_ring_free(xhci, xhci->event_ring);
xhci->event_ring = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "Freed event ring");
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (xhci->lpm_command)
xhci_free_command(xhci, xhci->lpm_command);
xhci->cmd_ring_reserved_trbs = 0;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (xhci->cmd_ring)
xhci_ring_free(xhci, xhci->cmd_ring);
xhci->cmd_ring = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "Freed command ring");
list_for_each_entry_safe(cur_cd, next_cd,
&xhci->cancel_cmd_list, cancel_cmd_list) {
list_del(&cur_cd->cancel_cmd_list);
kfree(cur_cd);
}
for (i = 1; i < MAX_HC_SLOTS; ++i)
xhci_free_virt_device(xhci, i);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (xhci->segment_pool)
dma_pool_destroy(xhci->segment_pool);
xhci->segment_pool = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "Freed segment pool");
if (xhci->device_pool)
dma_pool_destroy(xhci->device_pool);
xhci->device_pool = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "Freed device context pool");
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (xhci->small_streams_pool)
dma_pool_destroy(xhci->small_streams_pool);
xhci->small_streams_pool = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Freed small stream array pool");
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (xhci->medium_streams_pool)
dma_pool_destroy(xhci->medium_streams_pool);
xhci->medium_streams_pool = NULL;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Freed medium stream array pool");
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
if (xhci->dcbaa)
dma_free_coherent(dev, sizeof(*xhci->dcbaa),
xhci->dcbaa, xhci->dcbaa->dma);
xhci->dcbaa = NULL;
scratchpad_free(xhci);
if (!xhci->rh_bw)
goto no_bw;
num_ports = HCS_MAX_PORTS(xhci->hcs_params1);
for (i = 0; i < num_ports; i++) {
struct xhci_interval_bw_table *bwt = &xhci->rh_bw[i].bw_table;
for (j = 0; j < XHCI_MAX_INTERVAL; j++) {
struct list_head *ep = &bwt->interval_bw[j].endpoints;
while (!list_empty(ep))
list_del_init(ep->next);
}
}
for (i = 0; i < num_ports; i++) {
struct xhci_tt_bw_info *tt, *n;
list_for_each_entry_safe(tt, n, &xhci->rh_bw[i].tts, tt_list) {
list_del(&tt->tt_list);
kfree(tt);
}
}
no_bw:
xhci->num_usb2_ports = 0;
xhci->num_usb3_ports = 0;
xhci->num_active_eps = 0;
kfree(xhci->usb2_ports);
kfree(xhci->usb3_ports);
kfree(xhci->port_array);
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
kfree(xhci->rh_bw);
kfree(xhci->ext_caps);
xhci->page_size = 0;
xhci->page_shift = 0;
xhci->bus_state[0].bus_suspended = 0;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
xhci->bus_state[1].bus_suspended = 0;
}
static int xhci_test_trb_in_td(struct xhci_hcd *xhci,
struct xhci_segment *input_seg,
union xhci_trb *start_trb,
union xhci_trb *end_trb,
dma_addr_t input_dma,
struct xhci_segment *result_seg,
char *test_name, int test_number)
{
unsigned long long start_dma;
unsigned long long end_dma;
struct xhci_segment *seg;
start_dma = xhci_trb_virt_to_dma(input_seg, start_trb);
end_dma = xhci_trb_virt_to_dma(input_seg, end_trb);
seg = trb_in_td(input_seg, start_trb, end_trb, input_dma);
if (seg != result_seg) {
xhci_warn(xhci, "WARN: %s TRB math test %d failed!\n",
test_name, test_number);
xhci_warn(xhci, "Tested TRB math w/ seg %p and "
"input DMA 0x%llx\n",
input_seg,
(unsigned long long) input_dma);
xhci_warn(xhci, "starting TRB %p (0x%llx DMA), "
"ending TRB %p (0x%llx DMA)\n",
start_trb, start_dma,
end_trb, end_dma);
xhci_warn(xhci, "Expected seg %p, got seg %p\n",
result_seg, seg);
return -1;
}
return 0;
}
/* TRB math checks for xhci_trb_in_td(), using the command and event rings. */
static int xhci_check_trb_in_td_math(struct xhci_hcd *xhci, gfp_t mem_flags)
{
struct {
dma_addr_t input_dma;
struct xhci_segment *result_seg;
} simple_test_vector [] = {
/* A zeroed DMA field should fail */
{ 0, NULL },
/* One TRB before the ring start should fail */
{ xhci->event_ring->first_seg->dma - 16, NULL },
/* One byte before the ring start should fail */
{ xhci->event_ring->first_seg->dma - 1, NULL },
/* Starting TRB should succeed */
{ xhci->event_ring->first_seg->dma, xhci->event_ring->first_seg },
/* Ending TRB should succeed */
{ xhci->event_ring->first_seg->dma + (TRBS_PER_SEGMENT - 1)*16,
xhci->event_ring->first_seg },
/* One byte after the ring end should fail */
{ xhci->event_ring->first_seg->dma + (TRBS_PER_SEGMENT - 1)*16 + 1, NULL },
/* One TRB after the ring end should fail */
{ xhci->event_ring->first_seg->dma + (TRBS_PER_SEGMENT)*16, NULL },
/* An address of all ones should fail */
{ (dma_addr_t) (~0), NULL },
};
struct {
struct xhci_segment *input_seg;
union xhci_trb *start_trb;
union xhci_trb *end_trb;
dma_addr_t input_dma;
struct xhci_segment *result_seg;
} complex_test_vector [] = {
/* Test feeding a valid DMA address from a different ring */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = xhci->event_ring->first_seg->trbs,
.end_trb = &xhci->event_ring->first_seg->trbs[TRBS_PER_SEGMENT - 1],
.input_dma = xhci->cmd_ring->first_seg->dma,
.result_seg = NULL,
},
/* Test feeding a valid end TRB from a different ring */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = xhci->event_ring->first_seg->trbs,
.end_trb = &xhci->cmd_ring->first_seg->trbs[TRBS_PER_SEGMENT - 1],
.input_dma = xhci->cmd_ring->first_seg->dma,
.result_seg = NULL,
},
/* Test feeding a valid start and end TRB from a different ring */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = xhci->cmd_ring->first_seg->trbs,
.end_trb = &xhci->cmd_ring->first_seg->trbs[TRBS_PER_SEGMENT - 1],
.input_dma = xhci->cmd_ring->first_seg->dma,
.result_seg = NULL,
},
/* TRB in this ring, but after this TD */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = &xhci->event_ring->first_seg->trbs[0],
.end_trb = &xhci->event_ring->first_seg->trbs[3],
.input_dma = xhci->event_ring->first_seg->dma + 4*16,
.result_seg = NULL,
},
/* TRB in this ring, but before this TD */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = &xhci->event_ring->first_seg->trbs[3],
.end_trb = &xhci->event_ring->first_seg->trbs[6],
.input_dma = xhci->event_ring->first_seg->dma + 2*16,
.result_seg = NULL,
},
/* TRB in this ring, but after this wrapped TD */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = &xhci->event_ring->first_seg->trbs[TRBS_PER_SEGMENT - 3],
.end_trb = &xhci->event_ring->first_seg->trbs[1],
.input_dma = xhci->event_ring->first_seg->dma + 2*16,
.result_seg = NULL,
},
/* TRB in this ring, but before this wrapped TD */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = &xhci->event_ring->first_seg->trbs[TRBS_PER_SEGMENT - 3],
.end_trb = &xhci->event_ring->first_seg->trbs[1],
.input_dma = xhci->event_ring->first_seg->dma + (TRBS_PER_SEGMENT - 4)*16,
.result_seg = NULL,
},
/* TRB not in this ring, and we have a wrapped TD */
{ .input_seg = xhci->event_ring->first_seg,
.start_trb = &xhci->event_ring->first_seg->trbs[TRBS_PER_SEGMENT - 3],
.end_trb = &xhci->event_ring->first_seg->trbs[1],
.input_dma = xhci->cmd_ring->first_seg->dma + 2*16,
.result_seg = NULL,
},
};
unsigned int num_tests;
int i, ret;
num_tests = ARRAY_SIZE(simple_test_vector);
for (i = 0; i < num_tests; i++) {
ret = xhci_test_trb_in_td(xhci,
xhci->event_ring->first_seg,
xhci->event_ring->first_seg->trbs,
&xhci->event_ring->first_seg->trbs[TRBS_PER_SEGMENT - 1],
simple_test_vector[i].input_dma,
simple_test_vector[i].result_seg,
"Simple", i);
if (ret < 0)
return ret;
}
num_tests = ARRAY_SIZE(complex_test_vector);
for (i = 0; i < num_tests; i++) {
ret = xhci_test_trb_in_td(xhci,
complex_test_vector[i].input_seg,
complex_test_vector[i].start_trb,
complex_test_vector[i].end_trb,
complex_test_vector[i].input_dma,
complex_test_vector[i].result_seg,
"Complex", i);
if (ret < 0)
return ret;
}
xhci_dbg(xhci, "TRB math tests passed.\n");
return 0;
}
static void xhci_set_hc_event_deq(struct xhci_hcd *xhci)
{
u64 temp;
dma_addr_t deq;
deq = xhci_trb_virt_to_dma(xhci->event_ring->deq_seg,
xhci->event_ring->dequeue);
if (deq == 0 && !in_interrupt())
xhci_warn(xhci, "WARN something wrong with SW event ring "
"dequeue ptr.\n");
/* Update HC event ring dequeue pointer */
temp = readq(&xhci->ir_set->erst_dequeue);
temp &= ERST_PTR_MASK;
/* Don't clear the EHB bit (which is RW1C) because
* there might be more events to service.
*/
temp &= ~ERST_EHB;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Write event ring dequeue pointer, "
"preserving EHB bit");
writeq(((u64) deq & (u64) ~ERST_PTR_MASK) | temp,
&xhci->ir_set->erst_dequeue);
}
static void xhci_add_in_port(struct xhci_hcd *xhci, unsigned int num_ports,
__le32 __iomem *addr, u8 major_revision, int max_caps)
{
u32 temp, port_offset, port_count;
int i;
if (major_revision > 0x03) {
xhci_warn(xhci, "Ignoring unknown port speed, "
"Ext Cap %p, revision = 0x%x\n",
addr, major_revision);
/* Ignoring port protocol we can't understand. FIXME */
return;
}
/* Port offset and count in the third dword, see section 7.2 */
temp = readl(addr + 2);
port_offset = XHCI_EXT_PORT_OFF(temp);
port_count = XHCI_EXT_PORT_COUNT(temp);
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Ext Cap %p, port offset = %u, "
"count = %u, revision = 0x%x",
addr, port_offset, port_count, major_revision);
/* Port count includes the current port offset */
if (port_offset == 0 || (port_offset + port_count - 1) > num_ports)
/* WTF? "Valid values are 1 to MaxPorts" */
return;
/* cache usb2 port capabilities */
if (major_revision < 0x03 && xhci->num_ext_caps < max_caps)
xhci->ext_caps[xhci->num_ext_caps++] = temp;
/* Check the host's USB2 LPM capability */
if ((xhci->hci_version == 0x96) && (major_revision != 0x03) &&
(temp & XHCI_L1C)) {
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"xHCI 0.96: support USB2 software lpm");
xhci->sw_lpm_support = 1;
}
if ((xhci->hci_version >= 0x100) && (major_revision != 0x03)) {
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"xHCI 1.0: support USB2 software lpm");
xhci->sw_lpm_support = 1;
if (temp & XHCI_HLC) {
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"xHCI 1.0: support USB2 hardware lpm");
xhci->hw_lpm_support = 1;
}
}
port_offset--;
for (i = port_offset; i < (port_offset + port_count); i++) {
/* Duplicate entry. Ignore the port if the revisions differ. */
if (xhci->port_array[i] != 0) {
xhci_warn(xhci, "Duplicate port entry, Ext Cap %p,"
" port %u\n", addr, i);
xhci_warn(xhci, "Port was marked as USB %u, "
"duplicated as USB %u\n",
xhci->port_array[i], major_revision);
/* Only adjust the roothub port counts if we haven't
* found a similar duplicate.
*/
if (xhci->port_array[i] != major_revision &&
xhci->port_array[i] != DUPLICATE_ENTRY) {
if (xhci->port_array[i] == 0x03)
xhci->num_usb3_ports--;
else
xhci->num_usb2_ports--;
xhci->port_array[i] = DUPLICATE_ENTRY;
}
/* FIXME: Should we disable the port? */
continue;
}
xhci->port_array[i] = major_revision;
if (major_revision == 0x03)
xhci->num_usb3_ports++;
else
xhci->num_usb2_ports++;
}
/* FIXME: Should we disable ports not in the Extended Capabilities? */
}
/*
* Scan the Extended Capabilities for the "Supported Protocol Capabilities" that
* specify what speeds each port is supposed to be. We can't count on the port
* speed bits in the PORTSC register being correct until a device is connected,
* but we need to set up the two fake roothubs with the correct number of USB
* 3.0 and USB 2.0 ports at host controller initialization time.
*/
static int xhci_setup_port_arrays(struct xhci_hcd *xhci, gfp_t flags)
{
__le32 __iomem *addr, *tmp_addr;
u32 offset, tmp_offset;
unsigned int num_ports;
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
int i, j, port_index;
int cap_count = 0;
addr = &xhci->cap_regs->hcc_params;
offset = XHCI_HCC_EXT_CAPS(readl(addr));
if (offset == 0) {
xhci_err(xhci, "No Extended Capability registers, "
"unable to set up roothub.\n");
return -ENODEV;
}
num_ports = HCS_MAX_PORTS(xhci->hcs_params1);
xhci->port_array = kzalloc(sizeof(*xhci->port_array)*num_ports, flags);
if (!xhci->port_array)
return -ENOMEM;
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
xhci->rh_bw = kzalloc(sizeof(*xhci->rh_bw)*num_ports, flags);
if (!xhci->rh_bw)
return -ENOMEM;
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
for (i = 0; i < num_ports; i++) {
struct xhci_interval_bw_table *bw_table;
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
INIT_LIST_HEAD(&xhci->rh_bw[i].tts);
xhci: Track interval bandwidth tables per port/TT. In order to update the root port or TT's bandwidth interval table, we will need to keep track of a list of endpoints, per interval. That way we can easily know the new largest max packet size when we have to remove an endpoint. Add an endpoint list for each root port or TT structure, sorted by endpoint max packet size. Insert new endpoints into the list such that the head of the list always has the endpoint with the greatest max packet size. Only insert endpoints and update the interval table with new information when those endpoints are periodic. Make sure to update the number of active TTs when we add or drop periodic endpoints. A TT is only considered active if it has one or more periodic endpoints attached (control and bulk are best effort, and counted in the 20% reserved on the high speed bus). If the number of active endpoints for a TT was zero, and it's now non-zero, increment the number of active TTs for the rootport. If the number of active endpoints was non-zero, and it's now zero, decrement the number of active TTs. We have to be careful when we're checking the bandwidth for a new configuration/alt setting. If we don't have enough bandwidth, we need to be able to "roll back" the bandwidth information stored in the endpoint and the root port/TT interval bandwidth table. We can't just create a copy of the interval bandwidth table, modify it, and check the bandwidth with the copy because we have lists of endpoints and entries can't be on more than one list. Instead, we copy the old endpoint bandwidth information, and use it to revert the interval table when the bandwidth check fails. We don't check the bandwidth after endpoints are dropped from the interval table when a device is reset or freed after a disconnect, because having endpoints use less bandwidth should not push the bandwidth usage over the limits. Besides which, we can't fail a device disconnect. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:50 +08:00
bw_table = &xhci->rh_bw[i].bw_table;
for (j = 0; j < XHCI_MAX_INTERVAL; j++)
INIT_LIST_HEAD(&bw_table->interval_bw[j].endpoints);
}
xhci: Store information about roothubs and TTs. For upcoming patches, we need to keep information about the bandwidth domains under the xHCI host. Each root port is a separate primary bandwidth domain, and each high speed hub's TT (and potentially each port on a multi-TT hub) is a secondary bandwidth domain. If the table were in text form, it would look a bit like this: EP Interval Sum of Number Largest Max Max Packet of Packets Packet Size Overhead 0 N mps overhead ... 15 N mps overhead Overhead is the maximum packet overhead (for bit stuffing, CRC, protocol overhead, etc) for all the endpoints in this interval. Devices with different speeds have different max packet overhead. For example, if there is a low speed and a full speed endpoint that both have an interval of 3, we would use the higher overhead (the low speed overhead). Interval 0 is a bit special, since we really just want to know the sum of the max ESIT payloads instead of the largest max packet size. That's stored in the interval0_esit_payload variable. For root ports, we also need to keep track of the number of active TTs. For each root port, and each TT under a root port, store some information about the bandwidth consumption. Dynamically allocate an array of root port bandwidth information for the number of root ports on the xHCI host. Each root port stores a list of TTs under the root port. A single TT hub only has one entry in the list, but a multi-TT hub will have an entry per port. When the USB core says that a USB device is a hub, create one or more entries in the root port TT list for the hub. When a device is deleted, and it is a hub, search through the root port TT list and delete all TT entries for the hub. Keep track of which TT entry is associated with a device under a TT. LS/FS devices attached directly to the root port will have usb_device->tt set to the roothub. Ignore that, and treat it like a primary bandwidth domain, since there isn't really a high speed bus between the roothub and the host. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-09-03 02:05:47 +08:00
/*
* For whatever reason, the first capability offset is from the
* capability register base, not from the HCCPARAMS register.
* See section 5.3.6 for offset calculation.
*/
addr = &xhci->cap_regs->hc_capbase + offset;
tmp_addr = addr;
tmp_offset = offset;
/* count extended protocol capability entries for later caching */
do {
u32 cap_id;
cap_id = readl(tmp_addr);
if (XHCI_EXT_CAPS_ID(cap_id) == XHCI_EXT_CAPS_PROTOCOL)
cap_count++;
tmp_offset = XHCI_EXT_CAPS_NEXT(cap_id);
tmp_addr += tmp_offset;
} while (tmp_offset);
xhci->ext_caps = kzalloc(sizeof(*xhci->ext_caps) * cap_count, flags);
if (!xhci->ext_caps)
return -ENOMEM;
while (1) {
u32 cap_id;
cap_id = readl(addr);
if (XHCI_EXT_CAPS_ID(cap_id) == XHCI_EXT_CAPS_PROTOCOL)
xhci_add_in_port(xhci, num_ports, addr,
(u8) XHCI_EXT_PORT_MAJOR(cap_id),
cap_count);
offset = XHCI_EXT_CAPS_NEXT(cap_id);
if (!offset || (xhci->num_usb2_ports + xhci->num_usb3_ports)
== num_ports)
break;
/*
* Once you're into the Extended Capabilities, the offset is
* always relative to the register holding the offset.
*/
addr += offset;
}
if (xhci->num_usb2_ports == 0 && xhci->num_usb3_ports == 0) {
xhci_warn(xhci, "No ports on the roothubs?\n");
return -ENODEV;
}
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Found %u USB 2.0 ports and %u USB 3.0 ports.",
xhci->num_usb2_ports, xhci->num_usb3_ports);
/* Place limits on the number of roothub ports so that the hub
* descriptors aren't longer than the USB core will allocate.
*/
if (xhci->num_usb3_ports > 15) {
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Limiting USB 3.0 roothub ports to 15.");
xhci->num_usb3_ports = 15;
}
if (xhci->num_usb2_ports > USB_MAXCHILDREN) {
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Limiting USB 2.0 roothub ports to %u.",
USB_MAXCHILDREN);
xhci->num_usb2_ports = USB_MAXCHILDREN;
}
/*
* Note we could have all USB 3.0 ports, or all USB 2.0 ports.
* Not sure how the USB core will handle a hub with no ports...
*/
if (xhci->num_usb2_ports) {
xhci->usb2_ports = kmalloc(sizeof(*xhci->usb2_ports)*
xhci->num_usb2_ports, flags);
if (!xhci->usb2_ports)
return -ENOMEM;
port_index = 0;
for (i = 0; i < num_ports; i++) {
if (xhci->port_array[i] == 0x03 ||
xhci->port_array[i] == 0 ||
xhci->port_array[i] == DUPLICATE_ENTRY)
continue;
xhci->usb2_ports[port_index] =
&xhci->op_regs->port_status_base +
NUM_PORT_REGS*i;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"USB 2.0 port at index %u, "
"addr = %p", i,
xhci->usb2_ports[port_index]);
port_index++;
if (port_index == xhci->num_usb2_ports)
break;
}
}
if (xhci->num_usb3_ports) {
xhci->usb3_ports = kmalloc(sizeof(*xhci->usb3_ports)*
xhci->num_usb3_ports, flags);
if (!xhci->usb3_ports)
return -ENOMEM;
port_index = 0;
for (i = 0; i < num_ports; i++)
if (xhci->port_array[i] == 0x03) {
xhci->usb3_ports[port_index] =
&xhci->op_regs->port_status_base +
NUM_PORT_REGS*i;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"USB 3.0 port at index %u, "
"addr = %p", i,
xhci->usb3_ports[port_index]);
port_index++;
if (port_index == xhci->num_usb3_ports)
break;
}
}
return 0;
}
int xhci_mem_init(struct xhci_hcd *xhci, gfp_t flags)
{
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
dma_addr_t dma;
struct device *dev = xhci_to_hcd(xhci)->self.controller;
unsigned int val, val2;
u64 val_64;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
struct xhci_segment *seg;
u32 page_size, temp;
int i;
INIT_LIST_HEAD(&xhci->cancel_cmd_list);
page_size = readl(&xhci->op_regs->page_size);
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Supported page size register = 0x%x", page_size);
for (i = 0; i < 16; i++) {
if ((0x1 & page_size) != 0)
break;
page_size = page_size >> 1;
}
if (i < 16)
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Supported page size of %iK", (1 << (i+12)) / 1024);
else
xhci_warn(xhci, "WARN: no supported page size\n");
/* Use 4K pages, since that's common and the minimum the HC supports */
xhci->page_shift = 12;
xhci->page_size = 1 << xhci->page_shift;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"HCD page size set to %iK", xhci->page_size / 1024);
/*
* Program the Number of Device Slots Enabled field in the CONFIG
* register with the max value of slots the HC can handle.
*/
val = HCS_MAX_SLOTS(readl(&xhci->cap_regs->hcs_params1));
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// xHC can handle at most %d device slots.", val);
val2 = readl(&xhci->op_regs->config_reg);
val |= (val2 & ~HCS_SLOTS_MASK);
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Setting Max device slots reg = 0x%x.", val);
writel(val, &xhci->op_regs->config_reg);
/*
* Section 5.4.8 - doorbell array must be
* "physically contiguous and 64-byte (cache line) aligned".
*/
xhci->dcbaa = dma_alloc_coherent(dev, sizeof(*xhci->dcbaa), &dma,
GFP_KERNEL);
if (!xhci->dcbaa)
goto fail;
memset(xhci->dcbaa, 0, sizeof *(xhci->dcbaa));
xhci->dcbaa->dma = dma;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Device context base array address = 0x%llx (DMA), %p (virt)",
(unsigned long long)xhci->dcbaa->dma, xhci->dcbaa);
writeq(dma, &xhci->op_regs->dcbaa_ptr);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/*
* Initialize the ring segment pool. The ring must be a contiguous
* structure comprised of TRBs. The TRBs must be 16 byte aligned,
* however, the command ring segment needs 64-byte aligned segments,
* so we pick the greater alignment need.
*/
xhci->segment_pool = dma_pool_create("xHCI ring segments", dev,
TRB_SEGMENT_SIZE, 64, xhci->page_size);
/* See Table 46 and Note on Figure 55 */
xhci->device_pool = dma_pool_create("xHCI input/output contexts", dev,
2112, 64, xhci->page_size);
if (!xhci->segment_pool || !xhci->device_pool)
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
goto fail;
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
/* Linear stream context arrays don't have any boundary restrictions,
* and only need to be 16-byte aligned.
*/
xhci->small_streams_pool =
dma_pool_create("xHCI 256 byte stream ctx arrays",
dev, SMALL_STREAM_ARRAY_SIZE, 16, 0);
xhci->medium_streams_pool =
dma_pool_create("xHCI 1KB stream ctx arrays",
dev, MEDIUM_STREAM_ARRAY_SIZE, 16, 0);
/* Any stream context array bigger than MEDIUM_STREAM_ARRAY_SIZE
* will be allocated with dma_alloc_coherent()
USB: xhci: Add memory allocation for USB3 bulk streams. Add support for allocating streams for USB 3.0 bulk endpoints. See Documentation/usb/bulk-streams.txt for more information about how and why you would use streams. When an endpoint has streams enabled, instead of having one ring where all transfers are enqueued to the hardware, it has several rings. The ring dequeue pointer in the endpoint context is changed to point to a "Stream Context Array". This is basically an array of pointers to transfer rings, one for each stream ID that the driver wants to use. The Stream Context Array size must be a power of two, and host controllers can place a limit on the size of the array (4 to 2^16 entries). These two facts make calculating the size of the Stream Context Array and the number of entries actually used by the driver a bit tricky. Besides the Stream Context Array and rings for all the stream IDs, we need one more data structure. The xHCI hardware will not tell us which stream ID a transfer event was for, but it will give us the slot ID, endpoint index, and physical address for the TRB that caused the event. For every endpoint on a device, add a radix tree to map physical TRB addresses to virtual segments within a stream ring. Keep track of whether an endpoint is transitioning to using streams, and don't enqueue any URBs while that's taking place. Refuse to transition an endpoint to streams if there are already URBs enqueued for that endpoint. We need to make sure that freeing streams does not fail, since a driver's disconnect() function may attempt to do this, and it cannot fail. Pre-allocate the command structure used to issue the Configure Endpoint command, and reserve space on the command ring for each stream endpoint. This may be a bit overkill, but it is permissible for the driver to allocate all streams in one call and free them in multiple calls. (It is not advised, however, since it is a waste of resources and time.) Even with the memory and ring room pre-allocated, freeing streams can still fail because the xHC rejects the configure endpoint command. It is valid (by the xHCI 0.96 spec) to return a "Bandwidth Error" or a "Resource Error" for a configure endpoint command. We should never see a Bandwidth Error, since bulk endpoints do not effect the reserved bandwidth. The host controller can still return a Resource Error, but it's improbable since the xHC would be going from a more resource-intensive configuration (streams) to a less resource-intensive configuration (no streams). If the xHC returns a Resource Error, the endpoint will be stuck with streams and will be unusable for drivers. It's an unavoidable consequence of broken host controller hardware. Includes bug fixes from the original patch, contributed by John Youn <John.Youn@synopsys.com> and Andy Green <AGreen@PLXTech.com> Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-03 06:34:16 +08:00
*/
if (!xhci->small_streams_pool || !xhci->medium_streams_pool)
goto fail;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* Set up the command ring to have one segments for now. */
xhci->cmd_ring = xhci_ring_alloc(xhci, 1, 1, TYPE_COMMAND, flags);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (!xhci->cmd_ring)
goto fail;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Allocated command ring at %p", xhci->cmd_ring);
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "First segment DMA is 0x%llx",
(unsigned long long)xhci->cmd_ring->first_seg->dma);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* Set the address in the Command Ring Control register */
val_64 = readq(&xhci->op_regs->cmd_ring);
val_64 = (val_64 & (u64) CMD_RING_RSVD_BITS) |
(xhci->cmd_ring->first_seg->dma & (u64) ~CMD_RING_RSVD_BITS) |
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci->cmd_ring->cycle_state;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Setting command ring address to 0x%x", val);
writeq(val_64, &xhci->op_regs->cmd_ring);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci_dbg_cmd_ptrs(xhci);
xhci->lpm_command = xhci_alloc_command(xhci, true, true, flags);
if (!xhci->lpm_command)
goto fail;
/* Reserve one command ring TRB for disabling LPM.
* Since the USB core grabs the shared usb_bus bandwidth mutex before
* disabling LPM, we only need to reserve one TRB for all devices.
*/
xhci->cmd_ring_reserved_trbs++;
val = readl(&xhci->cap_regs->db_off);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
val &= DBOFF_MASK;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Doorbell array is located at offset 0x%x"
" from cap regs base addr", val);
xhci->dba = (void __iomem *) xhci->cap_regs + val;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci_dbg_regs(xhci);
xhci_print_run_regs(xhci);
/* Set ir_set to interrupt register set 0 */
xhci->ir_set = &xhci->run_regs->ir_set[0];
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/*
* Event ring setup: Allocate a normal ring, but also setup
* the event ring segment table (ERST). Section 4.9.3.
*/
xhci_dbg_trace(xhci, trace_xhci_dbg_init, "// Allocating event ring");
xhci->event_ring = xhci_ring_alloc(xhci, ERST_NUM_SEGS, 1, TYPE_EVENT,
flags);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (!xhci->event_ring)
goto fail;
if (xhci_check_trb_in_td_math(xhci, flags) < 0)
goto fail;
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci->erst.entries = dma_alloc_coherent(dev,
sizeof(struct xhci_erst_entry) * ERST_NUM_SEGS, &dma,
GFP_KERNEL);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
if (!xhci->erst.entries)
goto fail;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Allocated event ring segment table at 0x%llx",
(unsigned long long)dma);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
memset(xhci->erst.entries, 0, sizeof(struct xhci_erst_entry)*ERST_NUM_SEGS);
xhci->erst.num_entries = ERST_NUM_SEGS;
xhci->erst.erst_dma_addr = dma;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Set ERST to 0; private num segs = %i, virt addr = %p, dma addr = 0x%llx",
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci->erst.num_entries,
xhci->erst.entries,
(unsigned long long)xhci->erst.erst_dma_addr);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* set ring base address and size for each segment table entry */
for (val = 0, seg = xhci->event_ring->first_seg; val < ERST_NUM_SEGS; val++) {
struct xhci_erst_entry *entry = &xhci->erst.entries[val];
entry->seg_addr = cpu_to_le64(seg->dma);
entry->seg_size = cpu_to_le32(TRBS_PER_SEGMENT);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
entry->rsvd = 0;
seg = seg->next;
}
/* set ERST count with the number of entries in the segment table */
val = readl(&xhci->ir_set->erst_size);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
val &= ERST_SIZE_MASK;
val |= ERST_NUM_SEGS;
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Write ERST size = %i to ir_set 0 (some bits preserved)",
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
val);
writel(val, &xhci->ir_set->erst_size);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Set ERST entries to point to event ring.");
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* set the segment table base address */
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"// Set ERST base address for ir_set 0 = 0x%llx",
(unsigned long long)xhci->erst.erst_dma_addr);
val_64 = readq(&xhci->ir_set->erst_base);
val_64 &= ERST_PTR_MASK;
val_64 |= (xhci->erst.erst_dma_addr & (u64) ~ERST_PTR_MASK);
writeq(val_64, &xhci->ir_set->erst_base);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/* Set the event ring dequeue address */
xhci_set_hc_event_deq(xhci);
xhci_dbg_trace(xhci, trace_xhci_dbg_init,
"Wrote ERST address to ir_set 0.");
xhci_print_ir_set(xhci, 0);
USB: xhci: Ring allocation and initialization. Allocate basic xHCI host controller data structures. For every xHC, there is a command ring, an event ring, and a doorbell array. The doorbell array is used to notify the host controller that work has been enqueued onto one of the rings. The host controller driver enqueues commands on the command ring. The HW enqueues command completion events on the event ring and interrupts the system (currently using PCI interrupts, although the xHCI HW will use MSI interrupts eventually). All rings and the doorbell array must be allocated by the xHCI host controller driver. Each ring is comprised of one or more segments, which consists of 16-byte Transfer Request Blocks (TRBs) that can be chained to form a Transfer Descriptor (TD) that represents a multiple-buffer request. Segments are linked into a ring using Link TRBs, which means they are dynamically growable. The producer of the ring enqueues a TD by writing one or more TRBs in the ring and toggling the TRB cycle bit for each TRB. The consumer knows it can process the TRB when the cycle bit matches its internal consumer cycle state for the ring. The consumer cycle state is toggled an odd amount of times in the ring. An example ring (a ring must have a minimum of 16 TRBs on it, but that's too big to draw in ASCII art): chain cycle bit bit ------------------------ | TD A TRB 1 | 1 | 1 |<------------- <-- consumer dequeue ptr ------------------------ | consumer cycle state = 1 | TD A TRB 2 | 1 | 1 | | ------------------------ | | TD A TRB 3 | 0 | 1 | segment 1 | ------------------------ | | TD B TRB 1 | 1 | 1 | | ------------------------ | | TD B TRB 2 | 0 | 1 | | ------------------------ | | Link TRB | 0 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD C TRB 1 | 0 | 1 |<---- | ------------------------ | | TD D TRB 1 | 1 | 1 | | ------------------------ | | TD D TRB 2 | 1 | 1 | segment 2 | ------------------------ | | TD D TRB 3 | 1 | 1 | | ------------------------ | | TD D TRB 4 | 1 | 1 | | ------------------------ | | Link TRB | 1 | 1 |----- | ------------------------ | | | | chain cycle | | bit bit | | ------------------------ | | | TD D TRB 5 | 1 | 1 |<---- | ------------------------ | | TD D TRB 6 | 0 | 1 | | ------------------------ | | TD E TRB 1 | 0 | 1 | segment 3 | ------------------------ | | | 0 | 0 | | <-- producer enqueue ptr ------------------------ | | | 0 | 0 | | ------------------------ | | Link TRB | 0 | 0 |--------------- ------------------------ Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2009-04-28 10:52:34 +08:00
/*
* XXX: Might need to set the Interrupter Moderation Register to
* something other than the default (~1ms minimum between interrupts).
* See section 5.5.1.2.
*/
init_completion(&xhci->addr_dev);
for (i = 0; i < MAX_HC_SLOTS; ++i)
USB: clean up some host controller sparse warnings Fix usb sparse warnings: drivers/usb/host/isp1362-hcd.c:2220:50: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:43:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:49:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:161:24: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:198:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:319:31: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:1231:33: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-pci.c:177:23: warning: non-ANSI function declaration of function 'xhci_register_pci' drivers/usb/host/xhci-pci.c:182:26: warning: non-ANSI function declaration of function 'xhci_unregister_pci' drivers/usb/host/xhci-ring.c:342:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:525:34: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1009:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1031:32: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1041:16: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1096:30: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-ring.c:1100:27: warning: Using plain integer as NULL pointer drivers/usb/host/xhci-mem.c:224:27: warning: symbol 'xhci_alloc_container_ctx' was not declared. Should it be static? drivers/usb/host/xhci-mem.c:242:6: warning: symbol 'xhci_free_container_ctx' was not declared. Should it be static? Signed-off-by: Randy Dunlap <randy.dunlap@oracle.com> Cc: Lothar Wassmann <LW@KARO-electronics.de> Signed-off By: Sarah Sharp <sarah.a.sharp@linux.intel.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2010-04-19 23:53:50 +08:00
xhci->devs[i] = NULL;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
for (i = 0; i < USB_MAXCHILDREN; ++i) {
xhci->bus_state[0].resume_done[i] = 0;
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
xhci->bus_state[1].resume_done[i] = 0;
usb: Fix xHCI host issues on remote wakeup. When a device signals remote wakeup on a roothub, and the suspend change bit is set, the host controller driver must not give control back to the USB core until the port goes back into the active state. EHCI accomplishes this by waiting in the get port status function until the PORT_RESUME bit is cleared: /* stop resume signaling */ temp &= ~(PORT_RWC_BITS | PORT_SUSPEND | PORT_RESUME); ehci_writel(ehci, temp, status_reg); clear_bit(wIndex, &ehci->resuming_ports); retval = ehci_handshake(ehci, status_reg, PORT_RESUME, 0, 2000 /* 2msec */); Similarly, the xHCI host should wait until the port goes into U0, before passing control up to the USB core. When the port transitions from the RExit state to U0, the xHCI driver will get a port status change event. We need to wait for that event before passing control up to the USB core. After the port transitions to the active state, the USB core should time a recovery interval before it talks to the device. The length of that recovery interval is TRSMRCY, 10 ms, mentioned in the USB 2.0 spec, section 7.1.7.7. The previous xHCI code (which did not wait for the port to go into U0) would cause the USB core to violate that recovery interval. This bug caused numerous USB device disconnects on remote wakeup under ChromeOS and a Lynx Point LP xHCI host that takes up to 20 ms to move from RExit to U0. ChromeOS is very aggressive about power savings, and sets the autosuspend_delay to 100 ms, and disables USB persist. I attempted to replicate this bug with Ubuntu 12.04, but could not. I used Ubuntu 12.04 on the same platform, with the same BIOS that the bug was triggered on ChromeOS with. I also changed the USB sysfs settings as described above, but still could not reproduce the bug under Ubuntu. It may be that ChromeOS userspace triggers this bug through additional settings. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2013-08-20 23:12:12 +08:00
/* Only the USB 2.0 completions will ever be used. */
init_completion(&xhci->bus_state[1].rexit_done[i]);
xhci: Register second xHCI roothub. This patch changes the xHCI driver to allocate two roothubs. This touches the driver initialization and shutdown paths, roothub emulation code, and port status change event handlers. This is a rather large patch, but it can't be broken up, or it would break git-bisect. Make the xHCI driver register its own PCI probe function. This will call the USB core to create the USB 2.0 roothub, and then create the USB 3.0 roothub. This gets the code for registering a shared roothub out of the USB core, and allows other HCDs later to decide if and how many shared roothubs they want to allocate. Make sure the xHCI's reset method marks the xHCI host controller's primary roothub as the USB 2.0 roothub. This ensures that the high speed bus will be processed first when the PCI device is resumed, and any USB 3.0 devices that have migrated over to high speed will migrate back after being reset. This ensures that USB persist works with these odd devices. The reset method will also mark the xHCI USB2 roothub as having an integrated TT. Like EHCI host controllers with a "rate matching hub" the xHCI USB 2.0 roothub doesn't have an OHCI or UHCI companion controller. It doesn't really have a TT, but we'll lie and say it has an integrated TT. We need to do this because the USB core will reject LS/FS devices under a HS hub without a TT. Other details: ------------- The roothub emulation code is changed to return the correct number of ports for the two roothubs. For the USB 3.0 roothub, it only reports the USB 3.0 ports. For the USB 2.0 roothub, it reports all the LS/FS/HS ports. The code to disable a port now checks the speed of the roothub, and refuses to disable SuperSpeed ports under the USB 3.0 roothub. The code for initializing a new device context must be changed to set the proper roothub port number. Since we've split the xHCI host into two roothubs, we can't just use the port number in the ancestor hub. Instead, we loop through the array of hardware port status register speeds and find the Nth port with a similar speed. The port status change event handler is updated to figure out whether the port that reported the change is a USB 3.0 port, or a non-SuperSpeed port. Once it figures out the port speed, it kicks the proper roothub. The function to find a slot ID based on the port index is updated to take into account that the two roothubs will have over-lapping port indexes. It checks that the virtual device with a matching port index is the same speed as the passed in roothub. There's also changes to the driver initialization and shutdown paths: 1. Make sure that the xhci_hcd pointer is shared across the two usb_hcd structures. The xhci_hcd pointer is allocated and the registers are mapped in when xhci_pci_setup() is called with the primary HCD. When xhci_pci_setup() is called with the non-primary HCD, the xhci_hcd pointer is stored. 2. Make sure to set the sg_tablesize for both usb_hcd structures. Set the PCI DMA mask for the non-primary HCD to allow for 64-bit or 32-bit DMA. (The PCI DMA mask is set from the primary HCD further down in the xhci_pci_setup() function.) 3. Ensure that the host controller doesn't start kicking khubd in response to port status changes before both usb_hcd structures are registered. xhci_run() only starts the xHC running once it has been called with the non-primary roothub. Similarly, the xhci_stop() function only halts the host controller when it is called with the non-primary HCD. Then on the second call, it resets and cleans up the MSI-X irqs. Signed-off-by: Sarah Sharp <sarah.a.sharp@linux.intel.com>
2010-12-17 03:21:10 +08:00
}
if (scratchpad_alloc(xhci, flags))
goto fail;
if (xhci_setup_port_arrays(xhci, flags))
goto fail;
/* Enable USB 3.0 device notifications for function remote wake, which
* is necessary for allowing USB 3.0 devices to do remote wakeup from
* U3 (device suspend).
*/
temp = readl(&xhci->op_regs->dev_notification);
temp &= ~DEV_NOTE_MASK;
temp |= DEV_NOTE_FWAKE;
writel(temp, &xhci->op_regs->dev_notification);
return 0;
fail:
xhci_warn(xhci, "Couldn't initialize memory\n");
xhci_halt(xhci);
xhci_reset(xhci);
xhci_mem_cleanup(xhci);
return -ENOMEM;
}