Commit graph

6 commits

Author SHA1 Message Date
Sam Atkins
3cbc0fdbb0 Kernel: Remove declarations for non-existent methods 2023-01-27 20:33:18 +00:00
Liav A
1f9d3a3523 Kernel/PCI: Hold a reference to DeviceIdentifier in the Device class
There are now 2 separate classes for almost the same object type:
- EnumerableDeviceIdentifier, which is used in the enumeration code for
  all PCI host controller classes. This is allowed to be moved and
  copied, as it doesn't support ref-counting.
- DeviceIdentifier, which inherits from EnumerableDeviceIdentifier. This
  class uses ref-counting, and is not allowed to be copied. It has a
  spinlock member in its structure to allow safely executing complicated
  IO sequences on a PCI device and its space configuration.
  There's a static method that allows a quick conversion from
  EnumerableDeviceIdentifier to DeviceIdentifier while creating a
  NonnullRefPtr out of it.

The reason for doing this is for the sake of integrity and reliablity of
the system in 2 places:
- Ensure that "complicated" tasks that rely on manipulating PCI device
  registers are done in a safe manner. For example, determining a PCI
  BAR space size requires multiple read and writes to the same register,
  and if another CPU tries to do something else with our selected
  register, then the result will be a catastrophe.
- Allow the PCI API to have a united form around a shared object which
  actually holds much more data than the PCI::Address structure. This is
  fundamental if we want to do certain types of optimizations, and be
  able to support more features of the PCI bus in the foreseeable
  future.

This patch already has several implications:
- All PCI::Device(s) hold a reference to a DeviceIdentifier structure
  being given originally from the PCI::Access singleton. This means that
  all instances of DeviceIdentifier structures are located in one place,
  and all references are pointing to that location. This ensures that
  locking the operation spinlock will take effect in all the appropriate
  places.
- We no longer support adding PCI host controllers and then immediately
  allow for enumerating it with a lambda function. It was found that
  this method is extremely broken and too much complicated to work
  reliably with the new paradigm being introduced in this patch. This
  means that for Volume Management Devices (Intel VMD devices), we
  simply first enumerate the PCI bus for such devices in the storage
  code, and if we find a device, we attach it in the PCI::Access method
  which will scan for devices behind that bridge and will add new
  DeviceIdentifier(s) objects to its internal Vector. Afterwards, we
  just continue as usual with scanning for actual storage controllers,
  so we will find a corresponding NVMe controllers if there were any
  behind that VMD bridge.
2023-01-26 23:04:26 +01:00
Liav A
91db482ad3 Kernel: Reorganize Arch/x86 directory to Arch/x86_64 after i686 removal
No functional change.
2022-12-28 11:53:41 +01:00
Liav A
5ff318cf3a Kernel: Remove i686 support 2022-12-28 11:53:41 +01:00
Linus Groh
d26aabff04 Everywhere: Run clang-format 2022-12-03 23:52:23 +00:00
Liav A
05ba034000 Kernel: Introduce the IOWindow class
This class is intended to replace all IOAddress usages in the Kernel
codebase altogether. The idea is to ensure IO can be done in
arch-specific manner that is determined mostly in compile-time, but to
still be able to use most of the Kernel code in non-x86 builds. Specific
devices that rely on x86-specific IO instructions are already placed in
the Arch/x86 directory and are omitted for non-x86 builds.

The reason this works so well is the fact that x86 IO space acts in a
similar fashion to the traditional memory space being available in most
CPU architectures - the x86 IO space is essentially just an array of
bytes like the physical memory address space, but requires x86 IO
instructions to load and store data. Therefore, many devices allow host
software to interact with the hardware registers in both ways, with a
noticeable trend even in the modern x86 hardware to move away from the
old x86 IO space to exclusively using memory-mapped IO.

Therefore, the IOWindow class encapsulates both methods for x86 builds.
The idea is to allow PCI devices to be used in either way in x86 builds,
so when trying to map an IOWindow on a PCI BAR, the Kernel will try to
find the proper method being declared with the PCI BAR flags.
For old PCI hardware on non-x86 builds this might turn into a problem as
we can't use port mapped IO, so the Kernel will gracefully fail with
ENOTSUP error code if that's the case, as there's really nothing we can
do within such case.

For general IO, the read{8,16,32} and write{8,16,32} methods are
available as a convenient API for other places in the Kernel. There are
simply no direct 64-bit IO API methods yet, as it's not needed right now
and is not considered to be Arch-agnostic too - the x86 IO space doesn't
support generating 64 bit cycle on IO bus and instead requires two 2
32-bit accesses. If for whatever reason it appears to be necessary to do
IO in such manner, it could probably be added with some neat tricks to
do so. It is recommended to use Memory::TypedMapping struct if direct 64
bit IO is actually needed.
2022-09-23 17:22:15 +01:00