bus we actually mapped at rather than always based on the last bus we
encountered while moving upward in the tree. Otherwise we might use the
wrong bus space in case the bridge directly underneath the nexus doesn't
require mapping, i.e. was skipped as it's the case for ssm(4) nodes.
to the image_params struct instead of several members of that struct
individually. This makes it easier to expand its arguments in the future
without touching all platforms.
Reviewed by: jhb
7 which corresponds to WSTATE_KMIX in OpenSolaris whenever calling into
it which totally screws us even when restoring %wstate afterwards as
spill/fill traps can happen while in OFW. The rather hackish OpenBSD
approach of just setting the equivalent of WSTATE_KERNEL to 7 also is
no option as we treat %wstate as a bit field. So in order to deal with
this problem actually implement spill/fill handlers for %wstate 7 which
just act as the WSTATE_KERNEL ones except of theoretically also handling
32-bit, turn off interrupts completely so we don't even take IPIs while
in OFW which should ensure we only take spill/fill traps at most and
restore %wstate after calling into OFW once we have taken over the trap
table. While at it, actually set WSTATE_{,PROM}_KMIX before calling into
OFW just like OpenSolaris does, which should at least help testing this
change on non-V1280.
- Remove comments referring to the %wstate usage in BSD/OS.
- Remove the no longer used RSF_ALIGN_RETRY macro.
- Correct some trap table addresses in comments.
- Ensure %wstate is set to WSTATE_KERNEL when taking over the trap table.
- Ensure PSTATE_AM is off when entering or exiting to OFW as well as that
interrupts are also completely off when exiting to OFW as the firmware
trap table shouldn't be used to handle our interrupts.
can actually use all of the available lockable entries of the tiny dTLB
for the kernel TSB. With this change the KVA space sizing happens to be
more in line with the MI one so up to at least 24GB machines KVA doesn't
need to be limited manually. This is just another stopgap though, the
real solution is to take advantage of ASI_ATOMIC_QUAD_LDD_PHYS on CPUs
providing it so we don't need to lock the kernel TSB pages into the dTLB
in the first place.
- Swap the configuration of the first and second large dTLB as with
US-IV+ these can only hold entries of certain page sizes each, which
we happened to chose the non-working way around.
- Additionally ensure that the large iTLB is set up to hold 8k pages
(currently this happens to be a NOP though).
- Add a workaround for US-IV+ erratum #2.
- Turn off dTLB parity error reporting as otherwise we get seemingly
false positives when copying in the user window by simulating a
fill trap on return to usermode. Given that these parity errors can
be avoided by disabling multi issue mode and the problem could be
reproduced with a second machine this appears to be a silicon bug of
some sort.
- Add a membar #Sync also before the stores to ASI_DCACHE_TAG. While
at it, turn of interrupts across the whole cheetah_cache_flush() for
simplicity instead of around every flush. This should have next to no
impact as for cheetah-class machines we typically only need to flush
the caches a few times during boot when recovering from peeking/poking
non-existent PCI devices, if at all.
- Just use KERNBASE for FLUSH as we also do elsewhere as the US-IV+
documentation doesn't seem to mention that these CPUs also ignore the
address like previous cheetah-class CPUs do. Again the code changing
LSU_IC is executed seldom enough that the negligible optimization of
using %g0 instead should have no real impact.
With these changes FreeBSD runs stable on V890 equipped with US-IV+
and -j128 buildworlds in a loop for days are no problem. Unfortunately,
the performance isn't were it should be as a buildworld on a 4x1.5GHz
US-IV+ V890 takes nearly 3h while on a V440 with (theoretically) less
powerfull 4x1.5GHz US-IIIi it takes just over 1h. It's unclear whether
this is related to the supposed silicon bug mentioned above or due to
another issue. The documentation (which contains a sever bug in the
description of the bits added to the context registers though) at least
doesn't mention any requirements for changes in the CPU handling besides
those implemented and the cache as well as the TLB configurations and
handling look fine.
o Re-arrange cheetah_init() so it's easier to add support for SPARC64
V up to VIIIfx CPUs, which only require parts of this initialization.
by UltraSparc-IV and -IV+ as well as SPARC64 V, VI, VII and VIIIfx CPUs.
- Replace TLB_PCXR_PGSZ_MASK and TLB_SCXR_PGSZ_MASK with TLB_CXR_PGSZ_MASK
which just is the complement of TLB_CXR_CTX_MASK instead of trying to
assemble it from the page size bits which vary across CPUs.
- Add macros for the remainder of the SFSR bits, which are useful for at
least debugging purposes.
provides no ino-bitmap properties so forge them using the default set
of controller interrupts and let schizo_setup_intr() take care of the
children, hoping for non-fancy routing.
- Add quirk handling for Sun Fire V890. When booting these machines from
disk a Schizo comes up with PCI error residing which triggers as soon
as we register schizo_pci_bus() even when clearing it from all involved
registers (it's no longer indicated once we're in schizo_pci_bus()
though). Thus make PCI bus errors non-fatal until we actually touch the
bus. With this change schizo_pci_bus() typically triggers once during
attach in this case. Obviously this approach isn't exactly race free
but it's about the best we can do about this problem as we're not
guaranteed that the interrupt will actually trigger on V890 either, as
it certainly doesn't when for example netbooting them.
COMPAT_43TTY enables the sgtty interface. Even though its exposure has
only been removed in FreeBSD 8.0, it wasn't used by anything in the base
system in FreeBSD 5.x (possibly even 4.x?). On those releases, if your
ports/packages are less than two years old, they will prefer termios
over sgtty.
but also of different types, f.e. Sun Fire V890 can be equipped with a
mix of UltraSPARC IV and IV+ CPUs, requiring different MMU initialization
and different workarounds for model specific errata. Therefore move the
CPU implementation number from a global variable to the per-CPU data.
Functions which are called before the latter is available are passed the
implementation number as a parameter now.
This file was missed in r204152.
but also of different types, f.e. Sun Fire V890 can be equipped with a
mix of UltraSPARC IV and IV+ CPUs, requiring different MMU initialization
and different workarounds for model specific errata. Therefore move the
CPU implementation number from a global variable to the per-CPU data.
Functions which are called before the latter is available are passed the
implementation number as a parameter now.
scalable shared memory node, which is used in large UltraSPARC III based
machines to group snooping-coherency domains together, like schizo(4) to
be treated like nexus(4) children.
to the exclusion lists as the CPU nodes aren't handled as regular devices
either. Also add the pseudo-devices found in Sun Fire V1280.
- Allow nexus_attach() and nexus_alloc_resource() to be used by drivers
derived from nexus(4) for subordinate busses.
- Don't add the zero-sized memory resources of glue devices to the resource
lists.
root nexus device for the CPUs as starting with UltraSPARC IV the 'cpu'
nodes hang off of from 'cmp' (chip multi-threading processor) or 'core'
or combinations thereof. Also in large UltraSPARC III based machines
the 'cpu' nodes hang off of 'ssm' (scalable shared memory) nodes which
group snooping-coherency domains together instead of directly from the
nexus.
It would be great if we could use newbus to deal with the different ways
the 'cpu' devices can hang off of pseudo ones but unfortunately both
cpu_mp_setmaxid() and sparc64_init() have to work prior to regular device
probing.
- Add support for UltraSPARC IV and IV+ CPUs. Due to the fact that these
are multi-core each CPU has two Fireplane config registers and thus the
module/target ID has to be determined differently so the one specific
to a certain core is used. Similarly, starting with UltraSPARC IV the
individual cores use a different property in the OFW device tree to
indicate the CPU/core ID as it no longer is in coincidence with the
shared slot/socket ID.
This involves changing the MD KTR code to not directly read the UPA
module ID either. We use the MID stored in the per-CPU data instead of
calling cpu_get_mid() as a replacement in order prevent clobbering any
registers as side-effect in the assembler version. This requires CATR()
invocations from mp_startup() prior to mapping the per-CPU pages to be
removed though.
While at it additionally distinguish between CPUs with Fireplane and
JBus interconnects as these also use slightly different sizes for the
JBus/agent/module/target IDs.
- Make sparc64_shutdown_final() static as it's not used outside of
machdep.c.
no cleanwindows handler so just remove trying to trigger it from _start
and the AP trampoline code as that leads to a crash there. This should
be okay as leaking data from the OFW via the CPU registers on start of
the kernel should be no real concern.
- Make the comments of _start and the AP trampoline code regarding the
initializations they perform match each other and reality.
- Make the comments of the AP trampoline code regarding iTLB accesses
refer to the right macro.
of Sun Fire V1280 doesn't round up the size itself but instead lets
claiming of non page-sized amounts of memory fail.
- Change parameters and variables related to the TLB slots to unsigned
which is more appropriate.
- Search the whole OFW device tree instead of only the children of the
root nexus device for the BSP as starting with UltraSPARC IV the 'cpu'
nodes hang off of from 'cmp' (chip multi-threading processor) or 'core'
or combinations thereof. Also in large UltraSPARC III based machines
the 'cpu' nodes hang off of 'ssm' (scalable shared memory) nodes which
group snooping-coherency domains together instead of directly from the
nexus.
- Add support for UltraSPARC IV and IV+ BSPs. Due to the fact that these
are multi-core each CPU has two Fireplane config registers and thus the
module/target ID has to be determined differently so the one specific
to a certain core is used. Similarly, starting with UltraSPARC IV the
individual cores use a different property in the OFW device tree to
indicate the CPU/core ID as it no longer is in coincidence with the
shared slot/socket ID.
While at it additionally distinguish between CPUs with Fireplane and
JBus interconnects as these also use slightly different sizes for the
JBus/agent/module/target IDs.
- Check the return value of init_heap(). This requires moving it after
cons_probe() so we can panic when appropriate. This should be fine as
the PowerPC OFW loader uses that order for quite some time now.
the 'debugging' section of any HEAD kernel and enable for the mainstream
ones, excluding the embedded architectures.
It may, of course, enabled on a case-by-case basis.
Sponsored by: Sandvine Incorporated
Requested by: emaste
Discussed with: kib
indicating an already initialized lock.
- Check for an empty MSI/MSI-X queue entry before asserting that we have
received a MSI/MSI-X message in order to not panic in case of stray MSI/
MSI-X queue interrupts which may happen in case of using an interrupt
handler rather than a filter.
MFC after: 3 days
For PT_TO_SCE stop that stops the ptraced process upon syscall entry,
syscall arguments are collected before ptracestop() is called. As a
consequence, debugger cannot modify syscall or its arguments.
In syscall(), reread syscall number and arguments after ptracestop(),
if debugger modified anything in the process environment. Since procfs
stopevent requires number of syscall arguments in p_xstat, this cannot
be solved by moving stop/trace point before argument fetching.
Move the code to read arguments into separate function
fetch_syscall_args() to avoid code duplication. Note that ktrace point
for modified syscall is intentionally recorded twice, once with original
arguments, and second time with the arguments set by debugger.
PT_TO_SCX stop is executed after cpu_syscall_set_retval() already.
Reviewed by: kib
device in the table based on the count rather than the maxcount.
Also the previous code didn't work properly as it would have been
necessary to reserve the entire maxcount range in order keep later
requests from filling the spare MSIs between count and maxcount,
which would be complicated to unreserve in fire_release_msi().
- For MSIs with filters rather than handlers only don't clear the
event queue interrupt via fire_intr_clear() since given that these
are executed directly would clear it while we're still processing
the event queue, which in turn would lead to lost MSIs.
- Save one level of indentation in fire_setup_intr().
- Correct a bug in fire_teardown_intr() which prevented it from
correctly restoring the MSI in the resource, causing allocation of
a resource representing an MSI to fail after the first pass when
repeatedly loading and unloading a driver module.
sys/conf/makeLINT.mk to only do certain things for certain
architectures.
Note that neither arm nor mips have the Makefile there, thus
essentially not (yet) supporting LINT. This would enable them
do add special treatment to sys/conf/makeLINT.mk as well chosing
one of the many configurations as LINT.
This is a hack of doing this and keeping it in a separate commit
will allow us to more easily identify and back it out.
Discussed on/with: arch, jhb (as part of the LINT-VIMAGE thread)
MFC after: 1 month
the associated debugging under bootverbose.
- Remove freebsd4_sigreturn(); given that FreeBSD 4 didn't supported
sparc64 this only ever served as a transition aid prior to FreeBSD
5.0 and is unused by default since COMPAT_FREEBSD4 was removed from
GENERIC in r143072 nearly 5 years ago.
work.
- Sanity check the parameters passed to the implementations of the
pcib_{read,write}_config() methods. Using illegal values can cause
no real harm but it doesn't hurt to avoid unnecessary data error
traps requiring to flush and re-enable the level 1 caches.
the Sun Fire V215/V245 and Sun Ultra 25/45 machines. This driver also
already includes all the code to support the `Oberon' Uranus to PCIe
bridges found in the Fujitsu-Siemens based Mx000 machines but due to
lack of access to such a system for testing, probing of these bridges
is currently disabled.
Unfortunately, the event queue mechanism of these bridges for MSIs/
MSI-Xs matches our current MD and MI interrupt frameworks like square
pegs fit into round holes so for now we are generous and use one event
queue per MSI, which limits us to 35 MSIs/MSI-Xs per Host-PCIe-bridge
(we use one event queue for the PCIe error messages). This seems
tolerable as long as most devices just use one MSI/MSI-X anyway.
Adding knowledge about MSIs/MSI-Xs to the MD interrupt code should
allow us to decouple the 1:1 mapping at the cost of no longer being
able to bind MSIs/MSI-Xs to specific CPUs as we currently have no
reliable way to quiesce a device during the transition of its MSIs/
MSI-Xs to another event queue. This would still require the problem
of interrupt storms generated by devices which have no one-shot
behavior or can't/don't mask interrupts while the filter/handler is
executed (like the older PCIe NICs supported by bge(4)) to be solved
though.
Committed from: 26C3
so requests may bubble up to a host-PCI bridge driver.
- Distinguish between PCI and PCIe bridges in the device description
so it's a bit easier to follow what hangs off of what in the dmesg.
Unfortunately we can't also tell PCI and PCI-X apart based on the
information provided in the OFW device tree.
- Add quirk handling for the ALi M5249 found in Fire-based machines
which are used as a PCIe-PCIe bridge there. These are obviously
subtractive decoding as as they have a PCI-ISA bridge on their
secondary side (and likewise don't include the ISA I/O range in
their bridge decode) but don't indicate this via the class code.
Given that this quirk isn't likely to apply to all ALi M5249 and
I have no datasheet for these chips so I could implement a check
using the chip specific bits enabling subtractive decoding this
quirk handling is added to the MD code rather than the MI one.