I feel good today and I will not downvote all the other posters for saying that it is not even remotely possible to create a lock with just and only a Cassandra cluster. I just implemented the Lamport's bakery algorithm¹ and it works just fine. No need for any other strange thing like zoos, cages, memory tables, etc.
Instead you can implement a poor's man multi-process / multi-computer locking mechanism as long as you can obtain a read and write with at least QUORUM consistency. That's all you really need to be able to properly implement this algorithm. (the QUORUM level can change depending on the type of lock that you need: local, rack, full network.)
My implementation will appear in version 0.4.7 of libQtCassandra (in C++). I already tested and it locks perfectly. There are a few more things I want to test and let you define a set of parameters that right now are hard coded. But the mechanism works perfectly.
When I found this thread I thought that something was wrong. I searched some more and found a page on Apache which I mention below. The page is not very advanced but their MoinMoin does not offer a discussion page... Anyway, I think that it was worth mentioning. Hopefully people will start implementing that locking mechanism in all sorts of languages such as PHP, Ruby, Java, etc. so it gets used and known that it works.
Source: http://wiki.apache.org/cassandra/Locking
¹ http://en.wikipedia.org/wiki/Lamport%27s_bakery_algorithm
The following is more or less the way I implemented my version. This is just a simplified synopsis. I may need to update it some more because I did some enhancements while testing the resulting code (also the real code uses RAII and includes a timeout capability on top of the TTL.) The final version will be found in the libQtCassandra library.
// lock "object_name"
void lock(QString object_name)
{
QString locks = context->lockTableName();
QString hosts_key = context->lockHostsKey();
QString host_name = context->lockHostName();
int host = table[locks][hosts_key][host_name];
pid_t pid = getpid();
// get the next available ticket
table[locks]["entering::" + object_name][host + "/" + pid] = true;
int my_ticket(0);
QCassandraCells tickets(table[locks]["tickets::" + object_name]);
foreach(tickets as t)
{
// we assume that t.name is the column name
// and t.value is its value
if(t.value > my_ticket)
{
my_ticket = t.value;
}
}
++my_ticket; // add 1, since we want the next ticket
table[locks]["tickets::" + object_name][my_ticket + "/" + host + "/" + pid] = 1;
// not entering anymore, by deleting the cell we also release the row
// once all the processes are done with that object_name
table[locks]["entering::" + object_name].dropCell(host + "/" + pid);
// here we wait on all the other processes still entering at this
// point; if entering more or less at the same time we cannot
// guarantee that their ticket number will be larger, it may instead
// be equal; however, anyone entering later will always have a larger
// ticket number so we won't have to wait for them they will have to wait
// on us instead; note that we load the list of "entering" once;
// then we just check whether the column still exists; it is enough
QCassandraCells entering(table[locks]["entering::" + object_name]);
foreach(entering as e)
{
while(table[locks]["entering::" + object_name].exists(e))
{
sleep();
}
}
// now check whether any other process was there before us, if
// so sleep a bit and try again; in our case we only need to check
// for the processes registered for that one lock and not all the
// processes (which could be 1 million on a large system!);
// like with the entering vector we really only need to read the
// list of tickets once and then check when they get deleted
// (unfortunately we can only do a poll on this one too...);
// we exit the foreach() loop once our ticket is proved to be the
// smallest or no more tickets needs to be checked; when ticket
// numbers are equal, then we use our host numbers, the smaller
// is picked; when host numbers are equal (two processes on the
// same host fighting for the lock), then we use the processes
// pid since these are unique on a system, again the smallest wins.
tickets = table[locks]["tickets::" + object_name];
foreach(tickets as t)
{
// do we have a smaller ticket?
// note: the t.host and t.pid come from the column key
if(t.value > my_ticket
|| (t.value == my_ticket && t.host > host)
|| (t.value == my_ticket && t.host == host && t.pid >= pid))
{
// do not wait on larger tickets, just ignore them
continue;
}
// not smaller, wait for the ticket to go away
while(table[locks]["tickets::" + object_name].exists(t.name))
{
sleep();
}
// that ticket was released, we may have priority now
// check the next ticket
}
}
// unlock "object_name"
void unlock(QString object_name)
{
// release our ticket
QString locks = context->lockTableName();
QString hosts_key = context->lockHostsKey();
QString host_name = context->lockHostName();
int host = table[locks][hosts_key][host_name];
pid_t pid = getpid();
table[locks]["tickets::" + object_name].dropCell(host + "/" + pid);
}
// sample process using the lock/unlock
void SomeProcess(QString object_name)
{
while(true)
{
[...]
// non-critical section...
lock(object_name);
// The critical section code goes here...
unlock(object_name);
// non-critical section...
[...]
}
}
IMPORTANT NOTE (2019/05/05): Although it was a great exercise to get the Lamport's Bakery implemented using Cassandra, it is an anti-pattern for a Cassandra database. This means it is likely to perform poorly on a heavy load. Since then I created a new lock system, still using the Lamport's Algorithm, but keeping all of the data in memory (it's very small) and still allowing multiple computers to participate in the lock so if one goes down, the lock system continues to work as expected (many of the other lock systems do not have that capability. When the master goes down, you lose your lock capability until another computer decides to itself become the new master...)