# Bakery Lock when used inside a struct doesn't work

I'm new at multi-threaded programming and I tried to code the Bakery Lock Algorithm in C.

Here is the code:

``````int number[N];  // N is the number of threads
int choosing[N];

void lock(int id)  {
choosing[id] = 1;
number[id] = max(number, N) + 1;
choosing[id] = 0;

for (int j = 0; j < N; j++)
{
if (j == id)
continue;

while (1)
if (choosing[j] == 0)
break;

while (1)
{
if (number[j] == 0)
break;
if (number[j] > number[id]
|| (number[j] == number[id] && j > id))
break;
}
}
}

void unlock(int id)  {
number[id] = 0;
}
``````

Then I run the following example. I run 100 threads and each thread runs the following code:

``````  for (i = 0; i < 10; ++i)  {
lock(id);
counter++;
unlock(id);
}
``````

After all threads have been executed, the result of the shared `counter` is `10 * 100 = 1000` which is the expected value. I executed my program multiple times and the result was always `1000`. So it seems that the implementation of the lock is correct. That seemed weird based on a previous question I had because I didn't use any memory barriers/fences. Was I just lucky?

Then I wanted to create a multi-threaded program that will use many different locks. So I created this (full code can be found here):

``````typedef struct {
int number[N];
int choosing[N];
} LOCK;
``````

and the code changes to:

``````void lock(LOCK l, int id)
{
l.choosing[id] = 1;
l.number[id] = max(l.number, N) + 1;
l.choosing[id] = 0;
...
``````

Now when executing my program, sometimes I get `997`, sometimes `998`, sometimes `1000`. So the lock algorithm isn't correct.

What am I doing wrong? What can I do in order to fix it?

Is it perhaps a problem now that I'm reading arrays `number` and `choosing` from a `struct` and that's not atomic or something?

Should I use memory fences and if so at which points (I tried using `asm("mfence")` in various points of my code, but it didn't help)?

-
I hope this is just an academic exercise and not something you're actually trying to use... – R.. Feb 10 '12 at 23:43
@R.. I wouldn't use in practice Bakery's lock in practice :). It's not an exercise either. I'm just trying to get used on how to work with multi-threaded programs. – Fooko R. Feb 10 '12 at 23:44
@Fooko R. If so, don't implement primitives like locking yourself. Use standard, working and proven APIs/libraries. – nos Feb 11 '12 at 0:07
That too. My point was that this bakery lock is so inefficient and unscalable you shouldn't do it. Most people who try to roll their own locking are unhappy with the performance of system-library-provided locks, so I could see it making sense to roll your own low-level locking with atomic types (especially if you have C11 to work with), but writing a lock that's always going to be tens or hundreds of times slower than the real system-provided locks makes no sense. – R.. Feb 11 '12 at 0:16

With `pthreads`, the standard states that accessing a varable in one thread while another thread is, or might be, modifying it is undefined behavior. Your code does this all over the place. For example:

``````  while (1)
if (choosing[j] == 0)
break;
``````

This code accesses `choosing[j]` over and over while waiting for another thread to modify it. The compiler is entirely free to modify this code as follows:

``````int cj=choosing[j];
while(1)
if(cj == 0)
break;
``````

Why? Because the standard is clear that another thread may not modify the variable while this thread may be accessing it, so the value can be assumed to stay the same. But clearly, that won't work.

It can also do this:

``````while(1)
{
int cj=choosing[j];
if(cj==0) break;
choosing[j]=cj;
}
``````

Same logic. It is perfectly legal for the compiler to write back a variable whether it has been modified or not, so long as it does so at a time when the code could be accessing the variable. (Because, at that time, it's not legal for another thread to modify it, so the value must be the same and the write is harmless. In some cases, the write really is an optimization and real-world code has been broken by such writebacks.)

If you want to write your own synchronization functions, you have to build them with primitive functions that have the appropriate atomicity and memory visibility semantics. You must follow the rules or your code will fail, and fail horribly and unpredictably.

-
Or use C11 or compiler-specific-pre-C11 atomics. – R.. Feb 11 '12 at 0:13
Actually for the bakery silliness, `volatile` might work... – R.. Feb 11 '12 at 0:14
@R.. The problem is, I don't know of any platform where `volatile` is guaranteed to work. And the process of confirming that it did actually work is way more trouble than it's worth. It might appear to work, and in some circumstances, that might be good enough. – David Schwartz Feb 11 '12 at 0:19
@DavidSchwartz thanks for answering. But If I use for example `asm("mfence":::"memory")` won't I avoid such memory reorderings you give in your examples? – Fooko R. Feb 11 '12 at 0:24
And something more, if that's undefined behaviour how are all the concurrent data structures created? E.g. in a list you won't be able to read `head` of the list because some other thread might changing it (doing an insertion). – Fooko R. Feb 11 '12 at 0:33