163 lines
5.2 KiB
Text
163 lines
5.2 KiB
Text
bochs 2.2.6:
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./configure --enable-smp --enable-disasm --enable-debugger --enable-all-optimizations --enable-4meg-pages --enable-global-pages --enable-pae --disable-reset-on-triple-fault
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bochs CVS after 2.2.6:
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./configure --enable-smp --enable-disasm --enable-debugger --enable-all-optimizations --enable-4meg-pages --enable-global-pages --enable-pae
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bootmain.c doesn't work right if the ELF sections aren't
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sector-aligned. so you can't use ld -N. and the sections may also need
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to be non-zero length, only really matters for tiny "kernels".
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kernel loaded at 1 megabyte. stack same place that bootasm.S left it.
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kinit() should find real mem size
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and rescue useable memory below 1 meg
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no paging, no use of page table hardware, just segments
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no user area: no magic kernel stack mapping
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so no copying of kernel stack during fork
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though there is a kernel stack page for each process
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no kernel malloc(), just kalloc() for user core
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user pointers aren't valid in the kernel
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setting up first process
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we do want a process zero, as template
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but not runnable
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just set up return-from-trap frame on new kernel stack
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fake user program that calls exec
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map text read-only?
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shared text?
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what's on the stack during a trap or sys call?
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PUSHA before scheduler switch? for callee-saved registers.
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segment contents?
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what does iret need to get out of the kernel?
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how does INT know what kernel stack to use?
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are interrupts turned on in the kernel? probably.
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per-cpu curproc
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one tss per process, or one per cpu?
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one segment array per cpu, or per process?
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pass curproc explicitly, or implicit from cpu #?
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e.g. argument to newproc()?
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hmm, you need a global curproc[cpu] for trap() &c
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test stack expansion
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test running out of memory, process slots
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we can't really use a separate stack segment, since stack addresses
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need to work correctly as ordinary pointers. the same may be true of
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data vs text. how can we have a gap between data and stack, so that
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both can grow, without committing 4GB of physical memory? does this
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mean we need paging?
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what's the simplest way to add the paging we need?
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one page table, re-write it each time we leave the kernel?
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page table per process?
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probably need to use 0-0xffffffff segments, so that
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both data and stack pointers always work
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so is it now worth it to make a process's phys mem contiguous?
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or could use segment limits and 4 meg pages?
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but limits would prevent using stack pointers as data pointers
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how to write-protect text? not important?
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perhaps have fixed-size stack, put it in the data segment?
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oops, if kernel stack is in contiguous user phys mem, then moving
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users' memory (e.g. to expand it) will wreck any pointers into the
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kernel stack.
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do we need to set fs and gs? so user processes can't abuse them?
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setupsegs() may modify current segment table, is that legal?
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trap() ought to lgdt on return, since currently only done in swtch()
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protect hardware interrupt vectors from user INT instructions?
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test out-of-fd cases for creating pipe.
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test pipe reader closes then write
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test two readers, two writers.
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test children being inherited by grandparent &c
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some sleep()s should be interruptible by kill()
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cli/sti in acquire/release should nest!
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in case you acquire two locks
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what would need fixing if we got rid of kernel_lock?
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console output
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proc_exit() needs lock on proc *array* to deallocate
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kill() needs lock on proc *array*
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allocator's free list
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global fd table (really free-ness)
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sys_close() on fd table
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fork on proc list, also next pid
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hold lock until public slots in proc struct initialized
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locks
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init_lock
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sequences CPU startup
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proc_table_lock
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also protects next_pid
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per-fd lock *just* protects count read-modify-write
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also maybe freeness?
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memory allocator
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printf
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wakeup needs proc_table_lock
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so we need recursive locks?
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or you must hold the lock to call wakeup?
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in general, the table locks protect both free-ness and
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public variables of table elements
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in many cases you can use table elements w/o a lock
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e.g. if you are the process, or you are using an fd
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lock code shouldn't call cprintf...
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nasty hack to allow locks before first process,
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and to allow them in interrupts when curproc may be zero
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race between release and sleep in sys_wait()
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race between sys_exit waking up parent and setting state=ZOMBIE
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race in pipe code when full/empty
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lock order
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per-pipe lock
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proc_table_lock fd_table_lock kalloc_lock
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console_lock
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condition variable + mutex that protects it
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proc * (for wait()), proc_table_lock
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pipe structure, pipe lock
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systematic way to test sleep races?
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print something at the start of sleep?
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do you have to be holding the mutex in order to call wakeup()?
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device interrupts don't clear FL_IF
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so a recursive timer interrupt is possible
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what does inode->busy mean?
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might be held across disk reads
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no-one is allowed to do anything to the inode
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protected by inode_table_lock
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inode->count counts in-memory pointers to the struct
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prevents inode[] element from being re-used
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protected by inode_table_lock
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blocks and inodes have ad-hoc sleep-locks
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provide a single mechanism?
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need to lock bufs in bio between bread and brelse
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test 14-character file names
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and file arguments longer than 14
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and directories longer than one sector
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