Mutexes are often used for critical resources to prevent multiple threads from accessing them causing a data race by accessing shared resources at the same time. Sometimes, when locking mutexes, deadlock will happen when multiple threads hold each other's lock, and the program consequently comes to a halt. There are four requirements for deadlockdeadlocks. Four conditions are required for deadlock to occur:
- Mutual Exclusionexclusion
- Hold and Waitwait
- No Preemptionpreemption
- Circular Waitwait
Deadlock needs Each deadlock requires all four conditions. Therefore, to prevent deadlock, prevent so preventing deadlock requires preventing any one of the four conditions from being satisfied. This guideline recommends locking . One simple solution is to lock the mutexes in a predefined order to prevent , which prevents circular wait.
Noncompliant Code Example
Based on The behavior of this noncompliant code example depends on the runtime environment and the scheduler on the operating system, the following code will have different behaviors. However, with proper timing, the main() will deadlock when running thr1 and thr2 in which thr1 tries platform's scheduler. The program is susceptible to deadlock if thread thr1
attempts to lock ba2
's mutex while thr2 tries at the same time thread thr2
attempts to lock on ba1
's mutex in the deposit()
function and the program will not progress.
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#include <stdio<stdlib.h> #include <pthread<threads.h> #include <stdlib.h> typedef struct { int balance; pthreadmtx_mutex_t balance_mutex; } bank_account; typedef struct { bank_account *from; bank_account *to; int amount; } deposit_thr_argstransaction; /* return negative on error */ int void create_bank_account(bank_account **ba, int initial_amount) { int ret; bank_account *nba = (bank_account *)malloc( sizeof(bank_account) ); if (nba == NULL) { /* Handle return -1;error */ } nba->balance = initial_amount; if (thrd_success ret != pthread_mutexmtx_init(&nba->balance_mutex, NULL); if (ret) exit(ret);mtx_plain)) { /* Handle error */ } *ba = nba; return 0; } voidint *deposit(void *ptr) { deposit_thr_argstransaction *args = (deposit_thr_argstransaction *)ptr; if pthread_mutex(thrd_success != mtx_lock(&(args->from->balance_mutex)); { /* Handle error */ } /* notNot enough balance to transfer */ if (args->from->balance < args->amount) { if pthread_mutex(thrd_success != mtx_unlock(&(args->from->balance_mutex)); { /* Handle error */ } return NULL;-1; /* Indicate error */ } if pthread_mutex(thrd_success != mtx_lock(&(args->to->balance_mutex)); { /* Handle error */ } args->from->balance -= args->amount; args->to->balance += args->amount; pthread_mutexif (thrd_success != mtx_unlock(&(args->from->balance_mutex)); pthread_mutex { /* Handle error */ } if (thrd_success != mtx_unlock(&(args->to->balance_mutex)); { /* Handle error */ } free(ptr); return NULL0; } int main(void) { pthreadthrd_t thr1, thr2; inttransaction err*arg1; transaction *arg2; bank_account *ba1,; bank_account *ba2; err = create_bank_account(&ba1, 1000); if (err < 0) exit(err); err = create_bank_account(&ba2, 1000); if (err < 0) arg1 = exit(err); deposit_thr_args *arg1 = (transaction *)malloc(sizeof(deposit_thr_argstransaction)); if (arg1 == NULL) { /* Handle exit(-1); error */ } deposit_thr_args *arg2 = (transaction *)malloc(sizeof(deposit_thr_argstransaction)); if (arg2 == NULL) { exit(-1); /* Handle error */ } arg1->from = ba1; arg1->to = ba2; arg1->amount = 100; arg2->from = ba2; arg2->to = ba1; arg2->amount = 100; /* performPerform the depositdeposits */ err if (thrd_success != pthreadthrd_create(&thr1, NULL, deposit, (void *)arg1); if (err)) { /* Handle error */ } if exit(err); (thrd_success err != pthreadthrd_create(&thr2, NULL, deposit, (void *)arg2)); { if (err) /* Handle exit(err); error */ pthread_exit(NULL); } return 0; } |
Compliant Solution
The This compliant solution to the deadlock problem is to lock in predefined order eliminates the circular wait condition by establishing a predefined order for locking in the deposit()
function. In the following example, each Each thread will lock based on lock on the basis of the bank_account
's id defined in the struct initialization. This way circular wait problem is avoided and when one thread requires a lock will guarantee it will require the next lock ID, which is set when the bank_account struct
is initialized.
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#include <stdlib.h> #include <threads.h> typedef struct { int balance; pthread_mutexmtx_t balance_mutex; /* Should not change after initialization */ unsigned int id; /* read only and should never be changed */ } bank_account } bank_account; typedef struct { bank_account *from; bank_account *to; int amount; } transaction; unsigned int global_id = 1; /* return negative on error */ int void create_bank_account(bank_account **ba, int initial_amount) { int ret; bank_account *nba = (bank_account *)malloc( sizeof(bank_account) ); if (nba == NULL) { /* Handle return -1;error */ } nba->balance = initial_amount; ret = pthread_mutex_if (thrd_success != mtx_init(&nba->balance_mutex, NULL); if (ret) exit(ret);mtx_plain)) { /* Handle error */ } nba->id = global_id++; *ba = nba; return 0; } voidint *deposit(void *ptr) { deposit_thr_argstransaction *args = (deposit_thr_args *)ptrtransaction *)ptr; int result = -1; mtx_t *first; mtx_t *second; if (args->from->id == args->to->id) { return NULL;-1; /* Indicate error */ } /* ensureEnsure proper ordering for locking */ if (args->from->id < args->to->id) { pthread_mutex_lock(&(first = &args->from->balance_mutex)); pthread_mutex_lock(&(second = &args->to->balance_mutex)); } else { first = pthread_mutex_lock(&(args->to->balance_mutex)); pthread_mutex_lock(&(second = &args->from->balance_mutex; } if (thrd_success != mtx_lock(first))); { /* Handle error */ } if (thrd_success != mtx_lock(second)) { /* Handle error */ } /* notNot enough balance to transfer */ if (args->from->balance <>= args->amount) { pthread_mutex_unlock(&(args->from->balance_mutex)) -= args->amount; pthread_mutex_unlock(&(args->to->balance_mutex)) += args->amount; result return= NULL0; } args->from->balance -= args->amount; args->to->balance += args->amount; pthread_mutex_unlock(&(args->from->balance_mutex)); pthread_mutex_unlock(&(args->to->balance_mutex)); if (thrd_success != mtx_unlock(second)) { /* Handle error */ } if (thrd_success != mtx_unlock(first)) { /* Handle error */ } free(ptr); return NULLresult; } |
Risk Assessment
Deadlock causes prevents multiple threads to become unable to progress and thus halts the executing program. This is a potential from progressing, halting program execution. A denial-of-service attack because is possible if the attacker can force deadlock situations. It is likely for deadlock to occur in multi-threaded programs that manage multiple shared resources. create the conditions for deadlock.
Rule |
---|
Severity | Likelihood | Remediation Cost | Priority | Level |
---|
Priority
POS43-C
low
probable
medium
L3
P3
Other Languages
CON35-C | Low | Probable | Medium | P4 | L3 |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| deadlock | Supported by sound analysis (deadlock alarm) | ||||||
CodeSonar |
| CONCURRENCY.LOCK.ORDER | Conflicting lock order | ||||||
Coverity |
| ORDER_REVERSAL | Fully implemented | ||||||
Cppcheck Premium |
| premium-cert-con35-c | Partially implemented | ||||||
Helix QAC |
| C1772, C1773 | |||||||
Klocwork |
| CONC.DL | |||||||
Parasoft C/C++test |
| CERT_C-CON35-a | Do not acquire locks in different order | ||||||
PC-lint Plus |
| 2462 | Fully supported | ||||||
Polyspace Bug Finder |
| CERT C: Rule CON35-C | Checks for deadlock (rule partially covered) |
Related Guidelines
Key here (explains table format and definitions)
Taxonomy | Taxonomy item | Relationship |
---|---|---|
CERT Oracle Secure Coding Standard for Java | LCK07 |
...
...
Prior to 2018-01-12: CERT: Unspecified Relationship |
...
References
\[[pthread_mutex | https://computing.llnl.gov/tutorials/pthreads/#Mutexes]\] pthread_mutex tutorial
\[[MITRE CWE:764 | http://cwe.mitre.org/data/definitions/764.html]\] Multiple Locks of Critical Resources
\[[Bryant 03|AA. References#Bryant 03]\] Chapter 13, Concurrent Programming Wiki Markup