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I was reading the SQLite FAQ, and came upon this passage:

Threads are evil. Avoid them.

I don't quite understand the statement "Thread are evil". If that is true, then what is the alternative?

My superficial understanding of threads is:

  • Threads make concurrence happen. Otherwise, the CPU horsepower will be wasted, waiting for (e.g.) slow I/O.
  • But the bad thing is that you must synchronize your logic to avoid contention and you have to protect shared resources.

Note: As I am not familiar with threads on Windows, I hope the discussion will be limited to Linux/Unix threads.

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Perhaps you should read the pdf? ;) –  jalf Jul 28 '09 at 2:28
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Voted to close as "not a real question" because the question links to the answer. –  Wim Coenen Jul 28 '09 at 14:19
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The original question, before it was edited, did not contain the phrase "My superficial understanding of threads is:" but was rather like: "My superficial understanding of the article is:" –  akavel Oct 24 '09 at 16:48
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9 Answers

up vote 10 down vote accepted

When people say that "threads are evil", the usually do so in the context of saying "processes are good". Threads implicitly share all application state and handles (and thread locals are opt-in). This means that there are plenty of opportunities to forget to synchronize (or not even understand that you need to synchronize!) while accessing that shared data.

Processes have separate memory space, and any communication between them is explicit. Furthermore, primitives used for interprocess communication are often such that you don't need to synchronize at all (e.g. pipes). And you can still share state directly if you need to, using shared memory, but that is also explicit in every given instance. So there are fewer opportunities to make mistakes, and the intent of the code is more explicit.

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The paper isn't really talking about processes specifically as the alternative –  jalf Jul 28 '09 at 2:27
    
+1 - An interesting point are Erlang's threads which, since the language is purely functional and prohibits side-effects, work like processes and share data through message passing. –  Dario Feb 15 '10 at 18:38
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Simple answer the way I understand it...

Most threading models use "shared state concurrency," which means that two execution processes can share the same memory at the same time. If one thread doesn't know what the other is doing, it can modify the data in a way that the other thread doesn't expect. This causes bugs.

Threads are "evil" because you need to wrap your mind around n threads all working on the same memory at the same time, and all of the fun things that go with it (deadlocks, racing conditions, etc).

You might read up about the Clojure (immutable data structures) and Erlang (message passsing) concurrency models for alternative ideas on how to achieve similar ends.

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What makes threads "evil" is that once you introduce more than one stream of execution into your program, you can no longer count on your program to behave in a deterministic manner.

That is to say: Given the same set of inputs, a single-threaded program will (in most cases) always do the same thing.

A multi-threaded program, given the same set of inputs, may well do something different every time it is run, unless it is very carefully controlled. That is because the the order in which the different threads run different bits of code is determined by the OS's thread scheduler combined with a system timer, and this introduces a good deal of "randomness" into what the program does when it runs.

The upshot is: debugging a multi-threaded program can be much harder than debugging a single-threaded program, because if you don't know what you are doing it can be very easy to end up with a race condition or deadlock bug that only appears (seemingly) at random once or twice a month. The program will look fine to your QA department (since they don't have a month to run it) but once it's out in the field, you'll be hearing from customers that the program crashed, and nobody can reproduce the crash.... bleah.

To sum up, threads aren't really "evil", but they are strong juju and should not be used unless (a) you really need them and (b) you know what you are getting yourself into. If you do use them, use them as sparingly as possible, and try to make their behavior as stupid-simple as you possibly can. Especially with multithreading, if anything can go wrong, it (sooner or later) will.

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I would interpret it another way. It's not that threads are evil, it's that side-effects are evil in a multithreaded context (which is a lot less catchy to say).

A side effect in this context is something that affects state shared by more than one thread, be it global or just shared. I recently wrote a review of Spring Batch and one of the code snippets used is:

private static Map<Long, JobExecution> executionsById = TransactionAwareProxyFactory.createTransactionalMap();
private static long currentId = 0;

public void saveJobExecution(JobExecution jobExecution) {
  Assert.isTrue(jobExecution.getId() == null);
  Long newId = currentId++;
  jobExecution.setId(newId);
  jobExecution.incrementVersion();
  executionsById.put(newId, copy(jobExecution));
}

Now there are at least three serious threading issues in less than 10 lines of code here. An example of a side effect in this context would be updating the currentId static variable.

Functional programming (Haskell, Scheme, Ocaml, Lisp, others) tend to espouse "pure" functions. A pure function is one with no side effects. Many imperative languages (eg Java, C#) also encourage the use of immutable objects (an immutable object is one whose state cannot change once created).

The reason for (or at least the effect of) both of these things is largely the same: they make multithreaded code much easier. A pure function by definition is threadsafe. An immutable object by definition is threadsafe.

The advantage processes have is that there is less shared state (generally). In traditional UNIX C programming, doing a fork() to create a new process would result in shared process state and this was used as a means of IPC (inter-process communication) but generally that state is replaced (with exec()) with something else.

But threads are much cheaper to create and destroy and they take less system resources (in fact, the operating itself may have no concept of threads yet you can still create multithreaded programs). These are called green threads.

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The paper you linked to seems to explain itself very well. Did you read it?

Keep in mind that a thread can refer to the programming-language construct (as in most procedural or OOP languages, you create a thread manually, and tell it to executed a function), or they can refer to the hardware construct (Each CPU core executes one thread at a time).

The hardware-level thread is obviously unavoidable, it's just how the CPU works. But the CPU doesn't care how the concurrency is expressed in your source code. It doesn't have to be by a "beginthread" function call, for example. The OS and the CPU just have to be told which instruction threads should be executed.

His point is that if we used better languages than C or Java with a programming model designed for concurrency, we could get concurrency basically for free. If we'd used a message-passing language, or a functional one with no side-effects, the compiler would be able to parallelize our code for us. And it would work.

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Threads aren't any more "evil" than hammers or screwdrivers or any other tools; they just require skill to utilize. The solution isn't to avoid them; it's to educate yourself and up your skill set.

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Creating a lot of threads without constraint is indeed evil.. using a pooling mechanisme (threadpool) will mitigate this problem.

Another way threads are 'evil' is that most framework code is not designed to deal with multiple threads, so you have to manage your own locking mechanisme for those datastructures.

Threads are good, but you have to think about how and when you use them and remember to measure if there really is a performance benefit.

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A thread is a bit like a light weight process. Think of it as an independent path of execution within an application. The thread runs in the same memory space as the application and therefore has access to all the same resources, global objects and global variables.

The good thing about them: you can parallelise a program to improve performance. Some examples, 1) In an image editing program a thread may run the filter processing independently of the GUI. 2) Some algorithms lend themselves to multiple threads.

Whats bad about them? if a program is poorly designed they can lead to deadlock issues where both threads are waiting on each other to access the same resource. And secondly, program design can me more complex because of this. Also, some class libraries don't support threading. e.g. the c library function "strtok" is not "thread safe". In other words, if two threads were to use it at the same time they would clobber each others results. Fortunately, there are often thread safe alternatives... e.g. boost library.

Threads are not evil, they can be very useful indeed.

Under Linux/Unix, threading hasn't been well supported in the past although I believe Linux now has Posix thread support and other unices support threading now via libraries or natively. i.e. pthreads.

The most common alternative to threading under Linux/Unix platforms is fork. Fork is simply a copy of a program including it's open file handles and global variables. fork() returns 0 to the child process and the process id to the parent. It's an older way of doing things under Linux/Unix but still well used. Threads use less memory than fork and are quicker to start up. Also, inter process communications is more work than simple threads.

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In a simple sense you can think of a thread as another instruction pointer in the current process. In other words it points the IP of another processor to some code in the same executable. So instead of having one instruction pointer moving through the code there are two or more IP's executing instructions from the same executable and address space simultaneously.

Remember the executable has it's own address space with data / stack etc... So now that two or more instructions are being executed simultaneously you can imagine what happens when more than one of the instructions wants to read/write to the same memory address at the same time.

The catch is that threads are operating within the process address space and are not afforded protection mechanisms from the processor that full blown processes are. (Forking a process on UNIX is standard practice and simply creates another process.)

Out of control threads can consume CPU cycles, chew up RAM, cause execeptions etc.. etc.. and the only way to stop them is to tell the OS process scheduler to forcibly terminate the thread by nullifying it's instruction pointer (i.e. stop executing). If you forcibly tell a CPU to stop executing a sequence of instructions what happens to the resources that have been allocated or are being operated on by those instructions? Are they left in a stable state? Are they properly freed? etc...

So, yes, threads require more thought and responsibility than executing a process because of the shared resources.

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