Previously FsRtlNotifyVolumeEvent would pass a pointer to a TARGET_DEVICE_CUSTOM_NOTIFICATION structure on the stack to IoReportTargetDeviceChangeAsynchronous, which would store a pointer to it in a work-item and process that after the stack object was already out of scope. This broke x64 boot. Started happening after recent fixes to IoReportTargetDeviceChangeAsynchronous.
Follow-up to commit 24a14abf2 (r57412).
HBelusca's comment:
> If this ExFreePoolWithTag() call was left commented, it's probably
> because, back in the day where I introduced it, there was a pool
> corruption that was detected, the source of which was unknown at
> that time. In retrospect, it is most probably the interrupt disconnect
> bug in IoDisconnectInterrupt() that was causing it. Now that this
> bug has been fixed just previously, it should be safe to re-enable
> pool freeing with tag.
ExAllocatePoolWithTag doesn't raise an exception on failure, only ExAllocatePoolWithQuotaTag does. Use that when quotas are relevant instead of silently continuing with a NULL pointer.
Problematic behaviour was added in commit a97f262ed (r26067), and
commit c39812d1b (r46193) converted to RtlUpcaseUnicodeString() call.
This was modifying the caller's given string. This is not really
a good practice to do so just to make display fancier.
For example, IopInitializeBuiltinDriver(), that calls the display
function, also uses the passed ServiceName later after.
Because IopDisplayLoadingMessage() executes only in SOS mode,
uppercasing the ServiceName in one case but not the other would
implicitly modify the observable OS behaviour.
IopSuffixUnicodeString() is adapted to be similar to RtlPrefixUnicodeString().
- Make the boolean SosEnabled from ex/init.c visible globally so that
it can be checked against by IopDisplayLoadingMessage().
- Also use RtlString* function to construct the string.
- Doxygen comments;
- SAL annotations;
- These two functions are local to driver.c file only -> static'ify them.
- 2 -> sizeof(WCHAR);
- Rename Length to NumChars;
- static const'ify the L".SYS" string.
- Move the GUID_DEVICE_ENUMERATED event from the TargetDeviceChangeEvent category to the DeviceInstallEvent category
- Create a new function that handles DeviceInstallEvent category events
Implement IoConnectInterruptEx() for CONNECT_FULLY_SPECIFIED.
This gives ability to load various modern drivers that use IoConnectInterruptEx.
Various drivers work after this change, such as serial.sys MS sample driver when compiled with the reactos tree and many more KMDF drivers from later Windows versions.
Co-authored-by: Victor Perevertkin <victor@perevertkin.ru>
Besides creating the PDO and device node for it, it has to set up the
necessary registry keys, and register PDO at PnP root driver properly.
CORE-18989
The root device object is in fact a PDO and a FDO at the same time. Thus
there is no need in creating two device objects here, one is enough.
This commit also removes the explicit device extension for the root DO,
because the only reason it existed is to distinguish the root driver's
FDO from its PDOs. This can easily be done by comparing with
IopRootDeviceNode.
Also collect some unused garbage while we are here.
Handling PnP root driver power IRPs requires that a device object must come up
with a device extension to determine whether it is a function driver and if so,
handle the IRP accordingly.
CORE-18989
- Add missing ExAllocatePool NULL checks.
- Fix order of KeBugCheckEx parameters for PNP_DETECTED_FATAL_ERROR.
- The Controller and Peripheral numbers are zero-based, so if the caller
wants to inspect controller (or peripheral) zero, let it be so!
The original code was treating controller number zero for enumerating
controllers of a given class within the different buses, which is
wrong. See the diff'ed trace below.
Tested with Windows' videoprt.sys VideoPortGetDeviceData().
```diff
IoQueryDeviceDescription()
BusType: 0xB093C224 (0)
BusNumber: 0xB093C228 (0)
ControllerType: 0xF9D01030 (19)
ControllerNumber: 0xF9D01038 (0)
PeripheralType: 0x00000000 (4294967295)
PeripheralNumber: 0x00000000 (4294967295)
CalloutRoutine: 0xF9CF74E4
Context: 0xF9D5A340
--> Query: 0xF9D5A22C
IopQueryBusDescription(Query: 0xF9D5A22C)
RootKey: '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM'
RootKeyHandle: 0x00000598
KeyIsRoot: TRUE
Bus: 0xF9D5A290 (4294967295)
Seen: 'CentralProcessor'
Seen: 'FloatingPointProcessor'
Seen: 'MultifunctionAdapter'
SubRootRegName: '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter'
IopQueryBusDescription(Query: 0xF9D5A22C)
RootKey: '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter'
RootKeyHandle: 0x00000590
KeyIsRoot: FALSE
Bus: 0xF9D5A290 (4294967295)
Seen: '0'
SubRootRegName: '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter\0'
Getting bus value: 'Identifier'
Getting bus value: 'Configuration Data'
Getting bus value: 'Component Information'
--> Getting device on Bus #0 : '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter\0'
IopQueryDeviceDescription(Query: 0xF9D5A22C)
RootKey: '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter\0'
RootKeyHandle: 0x00000590
Bus: 0
- Enumerating controllers in '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter\0\DisplayController'...
+ Getting controller #0
+ Retrieving controller '\REGISTRY\MACHINE\HARDWARE\DESCRIPTION\SYSTEM\MultifunctionAdapter\0\DisplayController\0'
```
Based on a commit by Vadim Galyant:
5ef5c11e7f
Also fix a minor type conversion warning. CORE-18963 CORE-17977
Co-authored-by: Vadim Galyant <vgal@rambler.ru>
We should compare against DeviceObject as DeviceInstance is never NULL.
Fix a resource leak as well. The bug CORE-18983 seems to lay somewhere
else though, I just stumbled upon this one while researching it.
Note there is a BSOD in the PnP manager on reboot after the driver
installation failure, but it seems it was uncovered by the fix
as opposed to caused by it.
- Fix whitespace; add SAL annotations, doxygen documentation...
- Deduplicate the array of description strings corresponding to
IO_QUERY_DEVICE_DATA_FORMAT.
- Unhardcode the "[3]" into 'IoQueryDeviceMaxData': the maximum number
of device data queried.
CORE-18962
- Deduplicate a while-loop by adding one more recursive call.
- Add IopMapDetectedDeviceId() helper function with a structure
in order to reduce hardcoded constants and checks.
CORE-17470
+ KdpDebugLogInit: Add resources cleanup in failure code paths.
Fix, in an NT-compatible manner, how (and when) the KD/KDBG BootPhase >=2
initialization steps are performed.
These are necessary for any functionality KDBG needs, that would depend
on the NT I/O Manager and the storage and filesystem stacks to be running.
This includes, creating the debug log file, and for KDBG, loading its
KDBinit initialization file.
As a result, file debug logging is fixed.
The old ReactOS-specific (NT-incompatible) callback we did in the middle
of IoInitSystem() is removed, in favor of a runtime mechanism that should
work on Windows as well.
The idea for this new mechanism is loosely inspired by the TDL4 rootkit,
see http://blog.w4kfu.com/public/tdl4_article/draft_tdl4article.html
but contrary to it, a specific hook is used instead, as well as the
technique of driver reinitialization:
https://web.archive.org/web/20211021050515/https://driverentry.com.br/en/blog/?p=261
Its rationale is as follows:
We want to be able to perform I/O-related initialization (starting a
logger thread for file log debugging, loading KDBinit file for KDBG,
etc.). A good place for this would be as early as possible, once the
I/O Manager has started the storage and the boot filesystem drivers.
Here is an overview of the initialization steps of the NT Kernel and
Executive:
----
KiSystemStartup(KeLoaderBlock)
if (Cpu == 0) KdInitSystem(0, KeLoaderBlock);
KiSwitchToBootStack() -> KiSystemStartupBootStack()
-> KiInitializeKernel() -> ExpInitializeExecutive(Cpu, KeLoaderBlock)
(NOTE: Any unexpected debugger break will call KdInitSystem(0, NULL); )
KdInitSystem(0, LoaderBlock) -> KdDebuggerInitialize0(LoaderBlock);
ExpInitializeExecutive(Cpu == 0): ExpInitializationPhase = 0;
HalInitSystem(0, KeLoaderBlock); <-- Sets HalInitPnpDriver callback.
...
PsInitSystem(LoaderBlock)
PsCreateSystemThread(Phase1Initialization)
Phase1Initialization(Discard): ExpInitializationPhase = 1;
HalInitSystem(1, KeLoaderBlock);
...
Early initialization of Ob, Ex, Ke.
KdInitSystem(1, KeLoaderBlock);
...
KdDebuggerInitialize1(LoaderBlock);
...
IoInitSystem(LoaderBlock);
...
----
As we can see, KdDebuggerInitialize1() is the last KD initialization
routine the kernel calls, and is called *before* the I/O Manager starts.
Thus, direct Nt/ZwCreateFile ... calls done there would fail. Also,
we want to do the I/O initialization as soon as possible. There does
not seem to be any exported way to be notified about the I/O manager
initialization steps... that is, unless we somehow become a driver and
insert ourselves in the flow!
Since we are not a regular driver, we need to invoke IoCreateDriver()
to create one. However, remember that we are currently running *before*
IoInitSystem(), the I/O subsystem is not initialized yet. Due to this,
calling IoCreateDriver(), much like any other IO functions, would lead
to a crash, because it calls
ObCreateObject(..., IoDriverObjectType, ...), and IoDriverObjectType
is non-initialized yet (it's NULL).
The chosen solution is to hook a "known" exported callback: namely, the
HalInitPnpDriver() callback (it initializes the "HAL Root Bus Driver").
It is set very early on by the HAL via the HalInitSystem(0, ...) call,
and is called early on by IoInitSystem() before any driver is loaded,
but after the I/O Manager has been minimally set up so that new drivers
can be created.
When the hook: KdpInitDriver() is called, we create our driver with
IoCreateDriver(), specifying its entrypoint KdpDriverEntry(), then
restore and call the original HalInitPnpDriver() callback.
Another possible unexplored alternative, could be to insert ourselves
in the KeLoaderBlock->LoadOrderListHead boot modules list, or in the
KeLoaderBlock->BootDriverListHead boot-driver list. (Note that while
we may be able to do this, because boot-drivers are resident in memory,
much like we are, we cannot insert ourselves in the system-driver list
however, since those drivers are expected to come from PE image files.)
Once the KdpDriverEntry() driver entrypoint is called, we register
KdpDriverReinit() for re-initialization with the I/O Manager, in order
to provide more initialization points. KdpDriverReinit() calls the KD
providers at BootPhase >= 2, and schedules further reinitializations
(at most 3 more) if any of the providers request so.
- Remove KdbInit() macro and directly use KdbpCliInit() (since the place
where it was used was already within an #ifdef KDBG block).
- Declare KdpKdbgInit() only when KDBG is defined, move its definition
into kdio.c and remove the legacy wrappers/kdbg.c file.
And in KdbInitialize(), set KdpInitRoutine directly to the former,
instead of using the KdpKdbgInit indirection.
- Don't reset KdComPortInUse in KdpDebugLogInit().
- Minor refactorings: KdpSerialDebugPrint -> KdpSerialPrint and make it
static; argument name "Message" -> "String", "StringLength" -> "Length".