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In this assignment, we give you a minimally functional thread system. Your job is to extend the functionality of this system to gain a better understanding of synchronization problems.
You will be working primarily in the threads
directory for
this assignment, with some work in the devices
directory on the
side. Compilation should be done in the threads
directory.
Before you read the description of this project, you should read all of the following sections: 1. Introduction, C. Coding Standards, E. Debugging Tools, and F. Development Tools. You should at least skim the material from A.1 Loading through A.5 Memory Allocation, especially A.3 Synchronization.
The first step is to read and understand the code for the initial thread system. Pintos already implements thread creation and thread completion, a simple scheduler to switch between threads, and synchronization primitives (semaphores, locks, condition variables, and optimization barriers).
Some of this code might seem slightly mysterious. If
you haven't already compiled and run the base system, as described in
the introduction (see section 1. Introduction), you should do so now. You
can read through parts of the source code to see what's going
on. If you like, you can add calls to printf()
almost
anywhere, then recompile and run to see what happens and in what
order. You can also run the kernel in a debugger and set breakpoints
at interesting spots, single-step through code and examine data, and
so on.
When a thread is created, you are creating a new context to be
scheduled. You provide a function to be run in this context as an
argument to thread_create()
. The first time the thread is
scheduled and runs, it starts from the beginning of that function
and executes in that context. When the function returns, the thread
terminates. Each thread, therefore, acts like a mini-program running
inside Pintos, with the function passed to thread_create()
acting like main()
.
At any given time, exactly one thread runs and the rest, if any,
become inactive. The scheduler decides which thread to
run next. (If no thread is ready to run
at any given time, then the special "idle" thread, implemented in
idle()
, runs.)
Synchronization primitives can force context switches when one
thread needs to wait for another thread to do something.
The mechanics of a context switch are
in threads/switch.S
, which is 80x86
assembly code. (You don't have to understand it.) It saves the
state of the currently running thread and restores the state of the
thread we're switching to.
Using the GDB debugger, slowly trace through a context
switch to see what happens (see section E.5 GDB). You can set a
breakpoint on schedule()
to start out, and then
single-step from there.(1) Be sure
to keep track of each thread's address
and state, and what procedures are on the call stack for each thread.
You will notice that when one thread calls switch_threads()
,
another thread starts running, and the first thing the new thread does
is to return from switch_threads()
. You will understand the thread
system once you understand why and how the switch_threads()
that
gets called is different from the switch_threads()
that returns.
See section A.2.3 Thread Switching, for more information.
Warning: In Pintos, each thread is assigned a small,
fixed-size execution stack just under 4 kB in size. The kernel
tries to detect stack overflow, but it cannot do so perfectly. You
may cause bizarre problems, such as mysterious kernel panics, if you
declare large data structures as non-static local variables,
e.g. int buf[1000];
. Alternatives to stack allocation include
the page allocator and the block allocator (see section A.5 Memory Allocation).
Here is a brief overview of the files in the threads
directory. You will not need to modify most of this code, but the
hope is that presenting this overview will give you a start on what
code to look at.
loader.S
loader.h
start()
in start.S. See section A.1.1 The Loader, for details. You should not need to look at this code or modify it.
start.S
kernel.lds.S
start.Sto be near the beginning of the kernel image. See section A.1.1 The Loader, for details. Again, you should not need to look at this code or modify it, but it's here in case you're curious.
init.c
init.h
main()
, the kernel's "main
program." You should look over main()
at least to see what
gets initialized. You might want to add your own initialization code
here. See section A.1.3 High-Level Kernel Initialization, for details.
thread.c
thread.h
thread.hdefines
struct thread
, which you are likely to modify
in all four projects. See A.2.1 struct thread
and A.2 Threads for
more information.
switch.S
switch.h
palloc.c
palloc.h
malloc.c
malloc.h
malloc()
and free()
for
the kernel. See section A.5.2 Block Allocator, for more information.
interrupt.c
interrupt.h
intr-stubs.S
intr-stubs.h
synch.c
synch.h
io.h
devicesdirectory that you won't have to touch.
vaddr.h
pte.h
flags.h
devicescode
The basic threaded kernel also includes these files in the
devices
directory:
timer.c
timer.h
vga.c
vga.h
printf()
calls into the VGA display driver for you, so there's little reason to
call this code yourself.
serial.c
serial.h
printf()
calls this code for you,
so you don't need to do so yourself.
It handles serial input by passing it to the input layer (see below).
block.c
block.h
ide.c
ide.h
partition.c
partition.h
kbd.c
kbd.h
input.c
input.h
intq.c
intq.h
rtc.c
rtc.h
thread/init.cto choose an initial seed for the random number generator.
speaker.c
speaker.h
pit.c
pit.h
devices/timer.cand
devices/speaker.cbecause each device uses one of the PIT's output channel.
libfiles
Finally, lib
and lib/kernel
contain useful library
routines. (lib/user
will be used by user programs, starting in
project 2, but it is not part of the kernel.) Here's a few more
details:
ctype.h
inttypes.h
limits.h
stdarg.h
stdbool.h
stddef.h
stdint.h
stdio.c
stdio.h
stdlib.c
stdlib.h
string.c
string.h
debug.c
debug.h
random.c
random.h
-rskernel command-line option on each run, or use a simulator other than Bochs, or specify the
-roption to
pintos
.
round.h
syscall-nr.h
kernel/list.c
kernel/list.h
kernel/bitmap.c
kernel/bitmap.h
kernel/hash.c
kernel/hash.h
kernel/console.c
kernel/console.h
kernel/stdio.h
printf()
and a few other functions.
Proper synchronization is an important part of the solutions to these
problems. Any synchronization problem can be easily solved by turning
interrupts off: while interrupts are off, there is no concurrency, so
there's no possibility for race conditions. Therefore, it's tempting to
solve all synchronization problems this way, but don't.
Instead, use semaphores, locks, and condition variables to solve the
bulk of your synchronization problems. Read the tour section on
synchronization (see section A.3 Synchronization) or the comments in
threads/synch.c
if you're unsure what synchronization primitives
may be used in what situations.
In the Pintos projects, the only class of problem best solved by disabling interrupts is coordinating data shared between a kernel thread and an interrupt handler. Because interrupt handlers can't sleep, they can't acquire locks. This means that data shared between kernel threads and an interrupt handler must be protected within a kernel thread by turning off interrupts.
This project only requires accessing a little bit of thread state from interrupt handlers. For the alarm clock, the timer interrupt needs to wake up sleeping threads. In the advanced scheduler, the timer interrupt needs to access a few global and per-thread variables. When you access these variables from kernel threads, you will need to disable interrupts to prevent the timer interrupt from interfering.
When you do turn off interrupts, take care to do so for the least amount of code possible, or you can end up losing important things such as timer ticks or input events. Turning off interrupts also increases the interrupt handling latency, which can make a machine feel sluggish if taken too far.
The synchronization primitives themselves in synch.c
are
implemented by disabling interrupts. You may need to increase the
amount of code that runs with interrupts disabled here, but you should
still try to keep it to a minimum.
Disabling interrupts can be useful for debugging, if you want to make sure that a section of code is not interrupted. You should remove debugging code before turning in your project. (Don't just comment it out, because that can make the code difficult to read.)
There should be no busy waiting in your submission. A tight loop that
calls thread_yield()
is one form of busy waiting.
In the past, many groups divided the assignment into pieces, then each group member worked on his or her piece until just before the deadline, at which time the group reconvened to combine their code and submit. This is a bad idea. We do not recommend this approach. Groups that do this often find that two changes conflict with each other, requiring lots of last-minute debugging. Some groups who have done this have turned in code that did not even compile or boot, much less pass any tests.
Instead, we recommend integrating your team's changes early and often, using a source code control system such as Git (see section F.3 Git). This is less likely to produce surprises, because everyone can see everyone else's code as it is written, instead of just when it is finished. These systems also make it possible to review changes and, when a change introduces a bug, drop back to working versions of code.
You should expect to run into bugs that you simply don't understand while working on this and subsequent projects. When you do, reread the appendix on debugging tools, which is filled with useful debugging tips that should help you to get back up to speed (see section E. Debugging Tools). Be sure to read the section on backtraces (see section E.4 Backtraces), which will help you to get the most out of every kernel panic or assertion failure.
Before you turn in your project, you must fill the the
project 1 design document template that is under pintos/design/threads.tpml
.
We recommend that you read the design document template before you start working on the
project. See section D. Project Documentation, for a sample design document
that goes along with a fictitious project.
Reimplement timer_sleep()
, defined in devices/timer.c
.
Although a working implementation is provided, it "busy waits," that
is, it spins in a loop checking the current time and calling
thread_yield()
until enough time has gone by. Reimplement it to
avoid busy waiting.
timer_sleep()
is useful for threads that operate in real-time,
e.g. for blinking the cursor once per second.
The argument to timer_sleep()
is expressed in timer ticks, not in
milliseconds or any another unit. There are TIMER_FREQ
timer
ticks per second, where TIMER_FREQ
is a macro defined in
devices/timer.h
. The default value is 100. We don't recommend
changing this value, because any change is likely to cause many of
the tests to fail.
Separate functions timer_msleep()
, timer_usleep()
, and
timer_nsleep()
do exist for sleeping a specific number of
milliseconds, microseconds, or nanoseconds, respectively, but these will
call timer_sleep()
automatically when necessary. You do not need
to modify them.
If your delays seem too short or too long, reread the explanation of the
-r
option to pintos
(see section 1.1.4 Debugging versus Testing).
The alarm clock implementation is not needed for later projects, although it could be useful for project 4.
Implement priority scheduling in Pintos. When a thread is added to the ready list that has a higher priority than the currently running thread, the current thread should immediately yield the processor to the new thread. Similarly, when threads are waiting for a lock, semaphore, or condition variable, the highest priority waiting thread should be awakened first. A thread may raise or lower its own priority at any time, but lowering its priority such that it no longer has the highest priority must cause it to immediately yield the CPU.
Thread priorities range from PRI_MIN
(0) to PRI_MAX
(63).
Lower numbers correspond to lower priorities, so that priority 0
is the lowest priority and priority 63 is the highest.
The initial thread priority is passed as an argument to
thread_create()
. If there's no reason to choose another
priority, use PRI_DEFAULT
(31). The PRI_
macros are
defined in threads/thread.h
, and you should not change their
values.
One issue with priority scheduling is "priority inversion". Consider high, medium, and low priority threads H, M, and L, respectively. If H needs to wait for L (for instance, for a lock held by L), and M is on the ready list, then H will never get the CPU because the low priority thread will not get any CPU time. A partial fix for this problem is for H to "donate" its priority to L while L is holding the lock, then recall the donation once L releases (and thus H acquires) the lock.
Implement priority donation. You will need to account for all different situations in which priority donation is required. Be sure to handle multiple donations, in which multiple priorities are donated to a single thread. You must also handle nested donation: if H is waiting on a lock that M holds and M is waiting on a lock that L holds, then both M and L should be boosted to H's priority. If necessary, you may impose a reasonable limit on depth of nested priority donation, such as 8 levels.
You must implement priority donation for locks. You need not implement priority donation for the other Pintos synchronization constructs. You do need to implement priority scheduling in all cases.
Finally, implement the following functions that allow a thread to
examine and modify its own priority. Skeletons for these functions are
provided in threads/thread.c
.
You need not provide any interface to allow a thread to directly modify other threads' priorities.
The priority scheduler is not used in any later project.
Here's a summary of our reference solution, produced by the
diffstat
program. The final row gives total lines inserted
and deleted; a changed line counts as both an insertion and a deletion.
The reference solution represents just one possible solution. Many other solutions are also possible and many of those differ greatly from the reference solution. Some excellent solutions may not modify all the files modified by the reference solution, and some may modify files not modified by the reference solution.
devices/timer.c | 42 +++++- threads/synch.c | 88 ++++++++++++- threads/thread.c | 196 ++++++++++++++++++++++++++---- threads/thread.h | 23 +++ |
Makefiles when I add a new source file?
To add a .c
file, edit the top-level Makefile.build
.
Add the new file to variable dir_SRC
, where
dir is the directory where you added the file. For this
project, that means you should add it to threads_SRC
or
devices_SRC
. Then run make
. If your new file
doesn't get
compiled, run make clean
and then try again.
When you modify the top-level Makefile.build
and re-run
make
, the modified
version should be automatically copied to
threads/build/Makefile
. The converse is
not true, so any changes will be lost the next time you run make
clean
from the threads
directory. Unless your changes are
truly temporary, you should prefer to edit Makefile.build
.
A new .h
file does not require editing the Makefile
s.
warning: no previous prototype for `func'
mean?
It means that you defined a non-static
function without
preceding it by a prototype. Because non-static
functions are
intended for use by other .c
files, for safety they should be
prototyped in a header file included before their definition. To fix
the problem, add a prototype in a header file that you include, or, if
the function isn't actually used by other .c
files, make it
static
.
Timer interrupts occur TIMER_FREQ
times per second. You can
adjust this value by editing devices/timer.h
. The default is
100 Hz.
We don't recommend changing this value, because any changes are likely to cause many of the tests to fail.
There are TIME_SLICE
ticks per time slice. This macro is
declared in threads/thread.c
. The default is 4 ticks.
We don't recommend changing this value, because any changes are likely to cause many of the tests to fail.
See section 1.2.1 Testing.
Using the jitter feature in Bochs (see section 1.1.4 Debugging versus Testing)
is a great way to discover bugs that are timing dependent. However,
the following tests are known to
fail with jitter even if your code is correct: alarm-priority
,
alarm-simultaneous
,
mlfqs-recent-1
, mlfqs-fair-2
, mlfqs-fair-20
,
mlfqs-nice-2
, mlfqs-nice-10
, and priority-fifo
.
The behavior of these tests can sometimes vary based on timing (e.g.,
if a timer interrupt arrives at an inconvenient time).
pass()
?
You are probably looking at a backtrace that looks something like this:
0xc0108810: debug_panic (lib/kernel/debug.c:32) 0xc010a99f: pass (tests/threads/tests.c:93) 0xc010bdd3: test_mlfqs_load_1 (...threads/mlfqs-load-1.c:33) 0xc010a8cf: run_test (tests/threads/tests.c:51) 0xc0100452: run_task (threads/init.c:283) 0xc0100536: run_actions (threads/init.c:333) 0xc01000bb: main (threads/init.c:137) |
This is just confusing output from the backtrace
program. It
does not actually mean that pass()
called debug_panic()
. In
fact, fail()
called debug_panic()
(via the PANIC()
macro). GCC knows that debug_panic()
does not return, because it
is declared NO_RETURN
(see section E.3 Function and Parameter Attributes), so it doesn't include any code in fail()
to take
control when debug_panic()
returns. This means that the return
address on the stack looks like it is at the beginning of the function
that happens to follow fail()
in memory, which in this case happens
to be pass()
.
See section E.4 Backtraces, for more information.
schedule()
?
Every path into schedule()
disables interrupts. They eventually
get re-enabled by the next thread to be scheduled. Consider the
possibilities: the new thread is running in switch_thread()
(but
see below), which is called by schedule()
, which is called by one
of a few possible functions:
thread_exit()
, but we'll never switch back into such a thread, so
it's uninteresting.
thread_yield()
, which immediately restores the interrupt level upon
return from schedule()
.
thread_block()
, which is called from multiple places:
sema_down()
, which restores the interrupt level before returning.
idle()
, which enables interrupts with an explicit assembly STI
instruction.
wait()
in devices/intq.c, whose callers are responsible for re-enabling interrupts.
There is a special case when a newly created thread runs for the first
time. Such a thread calls intr_enable()
as the first action in
kernel_thread()
, which is at the bottom of the call stack for every
kernel thread but the first.
Don't worry about the possibility of timer values overflowing. Timer values are expressed as signed 64-bit numbers, which at 100 ticks per second should be good for almost 2,924,712,087 years. By then, we expect Pintos to have been phased out of the Computer Science curriculum.
Yes, strict priority scheduling can lead to starvation because a thread will not run if any higher-priority thread is runnable. The advanced scheduler introduces a mechanism for dynamically changing thread priorities.
Strict priority scheduling is valuable in real-time systems because it offers the programmer more control over which jobs get processing time. High priorities are generally reserved for time-critical tasks. It's not "fair," but it addresses other concerns not applicable to a general-purpose operating system.
When a lock is released, the highest priority thread waiting for that lock should be unblocked and put on the list of ready threads. The scheduler should then run the highest priority thread on the ready list.
Yes. If there is a single highest-priority thread, it continues
running until it blocks or finishes, even if it calls
thread_yield()
.
If multiple threads have the same highest priority,
thread_yield()
should switch among them in "round robin" order.
Priority donation only changes the priority of the donee thread. The donor thread's priority is unchanged. Priority donation is not additive: if thread A (with priority 5) donates to thread B (with priority 3), then B's new priority is 5, not 8.
Yes. Consider a ready, low-priority thread L that holds a lock. High-priority thread H attempts to acquire the lock and blocks, thereby donating its priority to ready thread L.
Yes. While a thread that has acquired lock L is blocked for any
reason, its priority can increase by priority donation if a
higher-priority thread attempts to acquire L. This case is
checked by the priority-donate-sema
test.
Yes. If a thread added to the ready list has higher priority than the running thread, the correct behavior is to immediately yield the processor. It is not acceptable to wait for the next timer interrupt. The highest priority thread should run as soon as it is runnable, preempting whatever thread is currently running.
thread_set_priority()
affect a thread receiving donations?
It sets the thread's base priority. The thread's effective priority
becomes the higher of the newly set priority or the highest donated
priority. When the donations are released, the thread's priority
becomes the one set through the function call. This behavior is checked
by the priority-donate-lower
test.
Suppose you are seeing output in which some test names are doubled, like this:
(alarm-priority) begin (alarm-priority) (alarm-priority) Thread priority 30 woke up. Thread priority 29 woke up. (alarm-priority) Thread priority 28 woke up. |
What is happening is that output from two threads is being
interleaved. That is, one thread is printing "(alarm-priority)
Thread priority 29 woke up.\n"
and another thread is printing
"(alarm-priority) Thread priority 30 woke up.\n"
, but the first
thread is being preempted by the second in the middle of its output.
This problem indicates a bug in your priority scheduler. After all, a thread with priority 29 should not be able to run while a thread with priority 30 has work to do.
Normally, the implementation of the printf()
function in the
Pintos kernel attempts to prevent such interleaved output by acquiring
a console lock during the duration of the printf
call and
releasing it afterwards. However, the output of the test name,
e.g., (alarm-priority)
, and the message following it is output
using two calls to printf
, resulting in the console lock being
acquired and released twice.
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