into the host-specific files and wrapped access to them
with atomic operations since that's a structure global to
all the VMs. I think all the other globals are SMP clean
since they are only written once during module init time,
and read thereafter my all VMs.
Renamed all host OS specific functions to hostOS*(). All host
independent functions to host*().
I'd like to rename all monitor space functions to mon*() next.
bablokb says in [ 664926 ]
please remove the patch patches/patch.bochs.sh. This
patch was developed for 1.4.x and does not work
anymore with 2.0.x.
It has been superseded by bxtstart in Bochs-Tools (see
http://www.bablokb.de/bochs-tools/).
all the memory it needs, and the plex86 kernel module uses
get_user_pages() from the Linux kernel to get at them and
pin the few that are needed statically (and later up to
a watermark of pages that are needed dynamically).
Guest physical memory pages are now dynamically pinned/unpinned.
For now, I use a hard limit of 4Megs of pinned pages and
a really primitive algorithm to decide which one to unpin
when the limit is reached and one needs to be bumped. Seems
to work. Though I haven't run into the limit yet since I'm using
just a small test program.
and pinning user pages from the plex86 kernel module. The
guest physical memory array is no longer mmap()'d from kernel
space where it used to be allocated.
in the plex86 module and mmap()'ing it into user space (bochs),
to letting bochs malloc() it normally and using the
Linux kernel facility get_user_pages() to get the associated
physical pages and pin them in memory. I only have code for
Linux kernel 2.4.20 and up, as that's the first version to
export the get_user_pages() symbol so modules can use it.
- add int75_handler, for msdos compatbility fpu exception
This handler calls int 2 (nmi). The NMI handler should really be aware
of this and should iret in case of FPU exception (to be implemented)
a region of virtual memory. Now the same one works for getting
the pages of the kernel driver and memory objects allocated via
vmalloc().
Converted to using Linux interfaces to walk the page tables to
get at the physical memory addresses above. The old code was
digging up this info starting with looking at CR3. Linux has
functions/macros to do this, which can handle 2/3-level cases.
Wrapped the page table walk with proper locks. A spin lock
for new Linuxes, a big kernel lock for old ones.
- implementation of the UIP bit using a new timer handler. The one_second_timer()
function only sets the UIP bit and starts the UIP timer. The uip_timer()
function handles the date / time update, the alarm check and finally clears
the UIP bit.
- writing to control register A doesn't change the UIP bit