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246 lines
11 KiB
246 lines
11 KiB
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PCI Error Recovery
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------------------
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May 31, 2005
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Current document maintainer:
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Linas Vepstas <linas@austin.ibm.com>
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Some PCI bus controllers are able to detect certain "hard" PCI errors
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on the bus, such as parity errors on the data and address busses, as
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well as SERR and PERR errors. These chipsets are then able to disable
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I/O to/from the affected device, so that, for example, a bad DMA
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address doesn't end up corrupting system memory. These same chipsets
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are also able to reset the affected PCI device, and return it to
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working condition. This document describes a generic API form
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performing error recovery.
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The core idea is that after a PCI error has been detected, there must
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be a way for the kernel to coordinate with all affected device drivers
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so that the pci card can be made operational again, possibly after
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performing a full electrical #RST of the PCI card. The API below
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provides a generic API for device drivers to be notified of PCI
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errors, and to be notified of, and respond to, a reset sequence.
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Preliminary sketch of API, cut-n-pasted-n-modified email from
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Ben Herrenschmidt, circa 5 april 2005
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The error recovery API support is exposed to the driver in the form of
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a structure of function pointers pointed to by a new field in struct
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pci_driver. The absence of this pointer in pci_driver denotes an
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"non-aware" driver, behaviour on these is platform dependant.
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Platforms like ppc64 can try to simulate pci hotplug remove/add.
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The definition of "pci_error_token" is not covered here. It is based on
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Seto's work on the synchronous error detection. We still need to define
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functions for extracting infos out of an opaque error token. This is
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separate from this API.
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This structure has the form:
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struct pci_error_handlers
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{
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int (*error_detected)(struct pci_dev *dev, pci_error_token error);
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int (*mmio_enabled)(struct pci_dev *dev);
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int (*resume)(struct pci_dev *dev);
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int (*link_reset)(struct pci_dev *dev);
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int (*slot_reset)(struct pci_dev *dev);
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};
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A driver doesn't have to implement all of these callbacks. The
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only mandatory one is error_detected(). If a callback is not
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implemented, the corresponding feature is considered unsupported.
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For example, if mmio_enabled() and resume() aren't there, then the
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driver is assumed as not doing any direct recovery and requires
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a reset. If link_reset() is not implemented, the card is assumed as
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not caring about link resets, in which case, if recover is supported,
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the core can try recover (but not slot_reset() unless it really did
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reset the slot). If slot_reset() is not supported, link_reset() can
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be called instead on a slot reset.
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At first, the call will always be :
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1) error_detected()
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Error detected. This is sent once after an error has been detected. At
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this point, the device might not be accessible anymore depending on the
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platform (the slot will be isolated on ppc64). The driver may already
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have "noticed" the error because of a failing IO, but this is the proper
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"synchronisation point", that is, it gives a chance to the driver to
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cleanup, waiting for pending stuff (timers, whatever, etc...) to
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complete; it can take semaphores, schedule, etc... everything but touch
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the device. Within this function and after it returns, the driver
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shouldn't do any new IOs. Called in task context. This is sort of a
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"quiesce" point. See note about interrupts at the end of this doc.
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Result codes:
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- PCIERR_RESULT_CAN_RECOVER:
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Driever returns this if it thinks it might be able to recover
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the HW by just banging IOs or if it wants to be given
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a chance to extract some diagnostic informations (see
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below).
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- PCIERR_RESULT_NEED_RESET:
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Driver returns this if it thinks it can't recover unless the
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slot is reset.
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- PCIERR_RESULT_DISCONNECT:
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Return this if driver thinks it won't recover at all,
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(this will detach the driver ? or just leave it
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dangling ? to be decided)
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So at this point, we have called error_detected() for all drivers
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on the segment that had the error. On ppc64, the slot is isolated. What
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happens now typically depends on the result from the drivers. If all
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drivers on the segment/slot return PCIERR_RESULT_CAN_RECOVER, we would
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re-enable IOs on the slot (or do nothing special if the platform doesn't
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isolate slots) and call 2). If not and we can reset slots, we go to 4),
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if neither, we have a dead slot. If it's an hotplug slot, we might
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"simulate" reset by triggering HW unplug/replug though.
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>>> Current ppc64 implementation assumes that a device driver will
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>>> *not* schedule or semaphore in this routine; the current ppc64
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>>> implementation uses one kernel thread to notify all devices;
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>>> thus, of one device sleeps/schedules, all devices are affected.
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>>> Doing better requires complex multi-threaded logic in the error
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>>> recovery implementation (e.g. waiting for all notification threads
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>>> to "join" before proceeding with recovery.) This seems excessively
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>>> complex and not worth implementing.
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>>> The current ppc64 implementation doesn't much care if the device
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>>> attempts i/o at this point, or not. I/O's will fail, returning
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>>> a value of 0xff on read, and writes will be dropped. If the device
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>>> driver attempts more than 10K I/O's to a frozen adapter, it will
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>>> assume that the device driver has gone into an infinite loop, and
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>>> it will panic the the kernel.
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2) mmio_enabled()
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This is the "early recovery" call. IOs are allowed again, but DMA is
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not (hrm... to be discussed, I prefer not), with some restrictions. This
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is NOT a callback for the driver to start operations again, only to
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peek/poke at the device, extract diagnostic information, if any, and
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eventually do things like trigger a device local reset or some such,
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but not restart operations. This is sent if all drivers on a segment
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agree that they can try to recover and no automatic link reset was
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performed by the HW. If the platform can't just re-enable IOs without
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a slot reset or a link reset, it doesn't call this callback and goes
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directly to 3) or 4). All IOs should be done _synchronously_ from
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within this callback, errors triggered by them will be returned via
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the normal pci_check_whatever() api, no new error_detected() callback
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will be issued due to an error happening here. However, such an error
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might cause IOs to be re-blocked for the whole segment, and thus
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invalidate the recovery that other devices on the same segment might
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have done, forcing the whole segment into one of the next states,
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that is link reset or slot reset.
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Result codes:
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- PCIERR_RESULT_RECOVERED
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Driver returns this if it thinks the device is fully
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functionnal and thinks it is ready to start
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normal driver operations again. There is no
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guarantee that the driver will actually be
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allowed to proceed, as another driver on the
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same segment might have failed and thus triggered a
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slot reset on platforms that support it.
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- PCIERR_RESULT_NEED_RESET
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Driver returns this if it thinks the device is not
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recoverable in it's current state and it needs a slot
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reset to proceed.
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- PCIERR_RESULT_DISCONNECT
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Same as above. Total failure, no recovery even after
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reset driver dead. (To be defined more precisely)
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>>> The current ppc64 implementation does not implement this callback.
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3) link_reset()
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This is called after the link has been reset. This is typically
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a PCI Express specific state at this point and is done whenever a
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non-fatal error has been detected that can be "solved" by resetting
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the link. This call informs the driver of the reset and the driver
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should check if the device appears to be in working condition.
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This function acts a bit like 2) mmio_enabled(), in that the driver
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is not supposed to restart normal driver I/O operations right away.
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Instead, it should just "probe" the device to check it's recoverability
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status. If all is right, then the core will call resume() once all
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drivers have ack'd link_reset().
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Result codes:
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(identical to mmio_enabled)
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>>> The current ppc64 implementation does not implement this callback.
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4) slot_reset()
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This is called after the slot has been soft or hard reset by the
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platform. A soft reset consists of asserting the adapter #RST line
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and then restoring the PCI BARs and PCI configuration header. If the
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platform supports PCI hotplug, then it might instead perform a hard
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reset by toggling power on the slot off/on. This call gives drivers
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the chance to re-initialize the hardware (re-download firmware, etc.),
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but drivers shouldn't restart normal I/O processing operations at
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this point. (See note about interrupts; interrupts aren't guaranteed
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to be delivered until the resume() callback has been called). If all
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device drivers report success on this callback, the patform will call
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resume() to complete the error handling and let the driver restart
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normal I/O processing.
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A driver can still return a critical failure for this function if
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it can't get the device operational after reset. If the platform
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previously tried a soft reset, it migh now try a hard reset (power
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cycle) and then call slot_reset() again. It the device still can't
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be recovered, there is nothing more that can be done; the platform
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will typically report a "permanent failure" in such a case. The
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device will be considered "dead" in this case.
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Result codes:
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- PCIERR_RESULT_DISCONNECT
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Same as above.
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>>> The current ppc64 implementation does not try a power-cycle reset
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>>> if the driver returned PCIERR_RESULT_DISCONNECT. However, it should.
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5) resume()
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This is called if all drivers on the segment have returned
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PCIERR_RESULT_RECOVERED from one of the 3 prevous callbacks.
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That basically tells the driver to restart activity, tht everything
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is back and running. No result code is taken into account here. If
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a new error happens, it will restart a new error handling process.
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That's it. I think this covers all the possibilities. The way those
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callbacks are called is platform policy. A platform with no slot reset
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capability for example may want to just "ignore" drivers that can't
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recover (disconnect them) and try to let other cards on the same segment
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recover. Keep in mind that in most real life cases, though, there will
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be only one driver per segment.
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Now, there is a note about interrupts. If you get an interrupt and your
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device is dead or has been isolated, there is a problem :)
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After much thinking, I decided to leave that to the platform. That is,
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the recovery API only precies that:
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- There is no guarantee that interrupt delivery can proceed from any
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device on the segment starting from the error detection and until the
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restart callback is sent, at which point interrupts are expected to be
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fully operational.
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- There is no guarantee that interrupt delivery is stopped, that is, ad
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river that gets an interrupts after detecting an error, or that detects
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and error within the interrupt handler such that it prevents proper
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ack'ing of the interrupt (and thus removal of the source) should just
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return IRQ_NOTHANDLED. It's up to the platform to deal with taht
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condition, typically by masking the irq source during the duration of
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the error handling. It is expected that the platform "knows" which
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interrupts are routed to error-management capable slots and can deal
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with temporarily disabling that irq number during error processing (this
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isn't terribly complex). That means some IRQ latency for other devices
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sharing the interrupt, but there is simply no other way. High end
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platforms aren't supposed to share interrupts between many devices
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anyway :)
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Revised: 31 May 2005 Linas Vepstas <linas@austin.ibm.com>
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