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In

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threading, pthreads can optionally be set to cancel immediately or defer until a specific cancellation point. Canceling asynchronously (immediately) is dangerous, however, because most threads are in fact not safe to cancel immediately.

The IEEE standards page states that

only functions that are cancel-safe may be called from a thread that is asynchronously cancelable.

Canceling asynchronously would follow the same route as passing a signal into the thread to kill it, posing problems similar to those in CON37-C. Do not call signal() in a multithreaded program, which is strongly related to SIG02-C. Avoid using signals to implement normal functionality. POS44-C and SIG02-C expand on the dangers of canceling a thread suddenly, which can create a data race condition.

Noncompliant Code Example

In this noncompliant code example, the worker thread is doing something as simple as swapping a and b repeatedly.

This code uses one lock. The global_lock mutex ensures that the worker thread and main thread do not collide in accessing the a and b variables.

The worker thread repeatedly exchanges the values of a and b until it is canceled by the main thread. The main thread then prints out the current values of a and b. Ideally, one should be 5, and the other should be 10.

 pthreads have the option of being set to cancel immediately or defer until a specific cancellation point. Canceling asynchronously (immediately) is dangerous, however, because most threads are in fact not safe to cancel immediately.

The [IEEE standards page|AA. Bibliography#Open Group 04] states that
{quote}
only functions that are cancel-safe may be called from a thread that is asynchronously cancelable.
{quote}

Canceling asynchronously would follow the same route as passing a signal in to the thread to kill it, thus posing similar problems as in rule [POS44-C. Do not use signals to terminate threads], which is strongly related to recommendation [SIG02-C. Avoid using signals to implement normal functionality]. These expand on the dangers of canceling a thread suddenly, which can create a [data race condition|BB. Definitions#data race].


h2. Noncompliant Code Example

In this noncompliant code example, the {{worker}} thread is doing something as simple as swapping {{a}} and {{b}} repeatedly.

This code uses one lock. The {{global_lock}} mutex ensures that the worker thread and main thread do not collide in accessing the {{a}} and {{b}} variables.

The worker thread repeatedly exchanges the values of {{a}} and {{b}} until it is canceled by the main thread. The main thread then prints out the current values of {{a}} and {{b}}. Ideally, one should be 5, and the other should be 10.

{code:bgColor=#ffcccc}
volatile int a = 5,;
volatile int b = 10;

/* Lock to enable threads to access a and b safely */
pthread_mutex_t global_lock = PTHREAD_MUTEX_INITIALIZER;

void* worker_thread(void* dummy) {
  int i,;
  int c;
  int result;

  if ((result = pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS,&i)) != 0) {
    /* handle error */
  }

  while (1) {
    if ((result = pthread_mutex_lock(&global_lock)) != 0) {
      /* handle error */
    }
    c = b;
    b = a;
    a = c;
    if ((result = pthread_mutex_unlock(&global_lock)) != 0) {
      /* handle error */
    }
  }
  return NULL;
}


int main(void) {
  int result;
  pthread_t worker;

  if ((result = pthread_create( &worker, NULL, worker_thread, NULL)) != 0) {
    /* handle error */
  }

  /* .. Do stuff...meanwhile worker thread runs for some time */

  /* since we don't know when the character is read in, the program could continue at any time */
  if ((result = pthread_cancel(worker)) != 0) {
    /* handle error */
  }
  /* pthread_join waits for the thread to finish up before continuing */
  if ((result = pthread_join(worker, 0)) != 0) {
    /* handle error */
  }

  if ((result = pthread_mutex_lock(&global_lock)) != 0) {
    /* handle error */
  }
  printf("a: %i | b: %i", a, b);
  if ((result = pthread_mutex_unlock(&global_lock)) != 0) {
    /* handle error */
  }

  return 0;
}
{code}

{mc}
For test purposes, the 'Do stuff' section in {{main()}} can just contain {{getc(stdin);}}
{mc}

However, this program is subject to a race condition because an asynchronous cancel can happen at any time. If the worker thread is canceled while the {{global_lock}} mutex is held, it is never actually released. In this case, the main thread will wait forever trying to acquire the {{global_lock}}, and the program will deadlock.

It is also possible that the main thread cancels the worker thread before it has invoked {{pthread_setcanceltype()}}. If this happens,  the cancellation will be delayed until the worker thread calls {{pthread_setcanceltype()}}.

h2. Noncompliant Code Example

In this example, the {{worker}} thread arranges to release the {{global_lock}} mutex if it gets interrupted.

{code:bgColor=#ffcccc}

However, this program is subject to a race condition because an asynchronous cancel can happen at any time. If the worker thread is canceled while the global_lock mutex is held, it is never actually released. In this case, the main thread will wait forever trying to acquire the global_lock, and the program will deadlock.

It is also possible that the main thread cancels the worker thread before it has invoked pthread_setcanceltype(). If this happens, the cancellation will be delayed until the worker thread calls pthread_setcanceltype().

Noncompliant Code Example

In this example, the worker thread arranges to release the global_lock mutex if it gets interrupted:

void release_global_lock(void* dummy) {
  int result;
  if ((result = pthread_mutex_unlock(&global_lock)) != 0) {
    /* handle error */
  }
}

void* worker_thread(void* dummy) {
  int i,;
  int c;
  int result;

  if ((result = pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS,&i)) != 0) {
    /* handle error */
  }

  while (1) {
    if ((result = pthread_mutex_lock(&global_lock)) != 0) {
      /* handle error */
    }
    pthread_cleanup_push( release_global_lock, NULL);
    c = b;
    b = a;
    a = c;
    pthread_cleanup_pop(1);
  }
  return NULL;
}
{code}

The

...

global

...

variables

...

are

...

still

...

subject

...

to

...

a

...

race

...

condition

...

because

...

an

...

asynchronous

...

cancel

...

can

...

happen

...

at

...

any

...

time.

...

For

...

instance,

...

the

...

worker

...

thread

...

could

...

be

...

canceled

...

just

...

before

...

the

...

last

...

line

...

(

...

a

...

=

...

c

...

)

...

and

...

thereby

...

lose

...

the

...

old

...

value

...

of

...

b

...

.

...

Consequently,

...

the

...

main

...

thread

...

might

...

print

...

that

...

a

...

and

...

b

...

have

...

the

...

same

...

value.

...

The

...

program

...

is

...

still

...

subject

...

to

...

the

...

race

...

condition

...

where

...

the

...

main

...

thread

...

cancels

...

the

...

worker

...

thread

...

before

...

it

...

has

...

invoked

...

pthread_setcanceltype()

...

.

...

If

...

this

...

happens,

...

the

...

cancelation

...

will

...

be

...

delayed

...

until

...

the

...

worker

...

thread

...

calls

...

pthread_setcanceltype()

...

.

...

Furthermore,

...

though less

...

likely,

...

the

...

program

...

can

...

still

...

deadlock

...

if

...

the

...

worker

...

thread

...

gets

...

canceled

...

after

...

the

...

global_lock

...

is

...

acquired

...

but

...

before

...

pthread_cleanup_push()

...

is

...

invoked.

...

In

...

this

...

case,

...

the

...

worker

...

thread

...

is

...

canceled

...

while

...

holding

...

global_lock

...

,

...

and

...

the

...

program

...

will

...

deadlock.

...

Compliant Solution

From IEEE standards page:

The cancelability state and type of any newly created threads, including the thread in which main() was first invoked, shall be PTHREAD_CANCEL_ENABLE

...

and

...

PTHREAD_CANCEL_DEFERRED

...

respectively.

...

Because the default condition for POSIX, according to the IEEE standards, is PTHREAD_CANCEL_DEFERRED

...

,

...

it

...

is

...

not

...

necessary

...

to

...

invoke

...

pthread_setcanceltype()

...

in

...

the

...

compliant solution:

 solution.

{code:bgColor=#ccccff}
void* worker_thread(void* dummy) {
  int c;
  int result;

  while (1) {
    if ((result = pthread_mutex_lock(&global_lock)) != 0) {
      /* handle error */
    }
    c = b;
    b = a;
    a = c;
    if ((result = pthread_mutex_unlock(&global_lock)) != 0) {
      /* handle error */
    }

    /* now we're safe to cancel, creating cancel point */
    pthread_testcancel();
  }
  return NULL;
}
{code}

Because

...

this

...

code

...

limits

...

cancellation

...

of

...

the

...

worker

...

thread

...

to

...

the

...

end

...

of

...

the

...

while

...

loop,

...

the

...

worker

...

thread

...

can

...

preserve

...

the

...

data

...

invariant

...

that

...

a

...

!=

...

b

...

.

...

Consequently,

...

the

...

program

...

might

...

print

...

that

...

a

...

is

...

5

...

and

...

b

...

is

...

10

...

or

...

that

...

a

...

is

...

10

...

and

...

b

...

is

...

5,

...

but

...

they

...

will

...

always

...

be

...

revealed

...

to

...

have

...

different

...

values

...

when

...

the

...

worker

...

thread

...

is

...

canceled.

...

The

...

other

...

race

...

conditions

...

that

...

plague

...

the

...

noncompliant

...

code

...

examples

...

are

...

not

...

possible

...

here.

...

Because

...

the

...

worker

...

thread

...

does

...

not

...

modify

...

its

...

cancel

...

type,

...

it

...

cannot

...

be

...

canceled

...

before

...

being

...

improperly

...

initialized.

...

And

...

because it

...

cannot

...

be

...

canceled

...

while

...

the

...

global_lock

...

mutex

...

is

...

held,

...

there

...

is

...

no

...

possibility

...

of

...

deadlock,

...

and

...

the

...

worker

...

thread

...

does

...

not

...

need

...

to

...

register

...

any

...

cleanup

...

handlers.

...

Risk Assessment

Incorrectly using threads that asynchronously cancel may result in silent corruption, resource leaks, and, in the worst case, unpredictable interactions.

Automated Detection

Bibliography

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

Related Guidelines

SEI CERT Oracle Coding Standard for Java: THI05-J. Do not use Thread.stop() to terminate threads
In Java, similar reasoning resulted in the deprecation of Thread.stop().

Bibliography

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