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I have an iPhone app that is using sqlite 3.6 (not with FMDB) to store and load data. I load the database when the app loads and uses the same database connection through the whole app.

In a background thread the app downloads some data from a webserver and writes to the database. At the same time the main thread also might need to write to the same database. This sometimes leads to EXC_BAD_ACCESS as both threads are trying to access the database.

What is the best and easiest way to be able to use the database from different threads?

This is an example that shows the problem:

sqlite3 *database;   

- (BOOL)application:(UIApplication *)application didFinishLaunchingWithOptions:(NSDictionary *)launchOptions {   

    NSArray *paths = NSSearchPathForDirectoriesInDomains(NSDocumentDirectory, NSUserDomainMask, YES);
    NSString *documentsDirectory = [paths objectAtIndex:0];
    NSString *path = [documentsDirectory stringByAppendingPathComponent:@"database.db"];

    if (sqlite3_open([path UTF8String], &database) != SQLITE_OK) {
        return YES;

    [NSThread detachNewThreadSelector:@selector(test) toTarget:self withObject:nil];
    [self test];
    return YES;

-(void)test {
    for (int i = 0; i < 2000; i++) {
        sqlite3_exec([self getDb],"UPDATE mytable SET test=''", 0, 0, 0);


After willcodejavaforfood's answer below I've tried to change my code to use a separate database object (connection) for each separate thread and also added sqlite3_busy_timeout() so that sqlite will retry to write if the database is busy. Now I don't get EXC_BAD_ACCESS anymore but I've noticed that not all data get inserted. So this is not a stable solution either. It seems to be really hard to get sqlite working with threading..

My new solution with separate connections:

-(void)test {
    sqlite3 *db = [self getNewDb];
    for (int i = 0; i < 2000; i++) {
        sqlite3_exec(db,"UPDATE mytable SET test=''", 0, 0, 0);

- (sqlite3 *)getNewDb {
    sqlite3 *newDb = nil;
    if (sqlite3_open([[self getDbPath] UTF8String], &newDb) == SQLITE_OK) {
        sqlite3_busy_timeout(newDb, 1000);
    } else {
    return newDb;
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4 Answers 4

up vote 2 down vote accepted

I solved this problem by using one thread and an NSOperationQueue to insert the Data. I would give it some thought. I've never been able to get a stable System with mutliple threads, and most writes aren't that important that queuing really helps.

As per request, some more Infos:

I have a subclass of NSOperation that I instantiate with the model object I want to store. These operations are than submitted to an extension of NSOperationsQueue that runs in a seperate thread. This custom Queue just adds a pointer to the database instance. When the operation is executed, it uses the [NSOperationsQueue currentQueue] property to access the queue and than the database. On purpose, i used non-concurrent operations (maxOperations was set to 1)
Hence, only one query (or update) is executed at a time consecutivly, completely in the background.

Obviously you need some kind of callback after you're finished.

It is possibly not the fast, but the most stable and cleanest solution i could find.


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Can you try to explain a little more in detail how you solved it this way? Thanks! –  mrrmatinsi Dec 6 '10 at 19:19
A bit longer. If you need more detail, have a look at the docs i added –  LordT Dec 7 '10 at 16:15
Thanks for this answer! Seems like I've got a lot of work to do to get this working.. –  mrrmatinsi Dec 8 '10 at 12:41
if this helped you, you should accept the answer! –  LordT Dec 12 '10 at 19:38

This is all explained in the Core Data Programming Guide in the section for Concurrency.

The pattern recommended for concurrent programming with Core Data is thread confinement.

You should give each thread its own entirely private managed object context and keep their associated object graphs separated on a per-thread basis.

There are two possible ways to adopt the pattern:

Create a separate managed object context for each thread and share a single persistent store coordinator. This is the typically-recommended approach.

Create a separate managed object context and persistent store coordinator for each thread. This approach provides for greater concurrency at the expense of greater complexity (particularly if you need to communicate changes between different contexts) and increased memory usage.

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Thanks for your answer! But what is wrong with using one connection between all the threads and SQLITE_OPEN_FULLMUTEX (SQLite, serialized mode)? Like I asked before, what is the drawbacks? –  mrrmatinsi Dec 2 '10 at 18:45
Did you read the guide? –  willcodejavaforfood Dec 2 '10 at 18:48
I have now edited and updated my question after rewriting my code a little bit. Do you think this is a better solution? –  mrrmatinsi Dec 6 '10 at 16:11
@mrrmatinsi - Do you still get that exception? –  willcodejavaforfood Dec 6 '10 at 16:16
@willcodejavaforfood - No exceptions but I've noticed that if I have like 2-3 threads inserting lots of data to the database at the same time not all data gets inserted. Maybe there is a better way of doing this to make it more stable? When setting sqlite3_busy_timeout to an interval, will it loop and try again several times or just once after the interval? Thanks! –  mrrmatinsi Dec 6 '10 at 17:17

As you've noticed only one thread can access an sqlite database at a time. Options to prevent simultaneous access:

  1. Create a new database connection in each thread and rely on file locking (costly).
  2. Turn on sqlite3_config(SQLITE_CONFIG_SERIALIZED).
  3. Use NSLock's.
  4. Use GCD (Grand Central Dispatch) queue's.

The first three options may cause busy waiting (one thread waiting on another to release the lock) which is wasteful.

I use option 4 because it simplifies the task of creating new queries to run in the background and has no busy waiting. It also makes sure all queries execute in the order they were added (which my code tends to assume).

dispatch_queue_t _queue = dispatch_queue_create("com.mycompany.myqueue", DISPATCH_QUEUE_SERIAL);

// Run a query in the background.
dispatch_async(_queue, ^{

    ...some query

    // Perhaps call a completion block on the main thread when done?
    dispatch_async(dispatch_get_main_queue(), ^{

        //completion(results, error);

// Run a query and wait for the result.
// This will block until all previous queries have finished.
// Note that you shouldn't do this in production code but it may
// be useful to retrofit old (blocking) code.
__block NSArray *results;

dispatch_sync(_queue, ^{

    results = ...

...use the results


In a perfect world sqlite would let you perform simultaneous reads but only one write at a time (eg. like using dispatch_barrier_async() for writes and dispatch_async() for reads).

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I've tried these two solutions and they worked perfectly. You can either use critical sections or NSOperationQueue and I prefer the first one, here is the code for both of them:

define some class "DatabaseController" and add this code to its implementation:

static NSString * DatabaseLock = nil;
+ (void)initialize {
    [super initialize];
    DatabaseLock = [[NSString alloc] initWithString:@"Database-Lock"];
+ (NSString *)databaseLock {
    return DatabaseLock;

- (void)writeToDatabase1 {
    @synchronized ([DatabaseController databaseLock]) {
        // Code that writes to an sqlite3 database goes here...
- (void)writeToDatabase2 {
    @synchronized ([DatabaseController databaseLock]) {
        // Code that writes to an sqlite3 database goes here...

OR to use the NSOperationQueue you can use:

static NSOperationQueue * DatabaseQueue = nil;
+ (void)initialize {
    [super initialize];

    DatabaseQueue = [[NSOperationQueue alloc] init];
    [DatabaseQueue setMaxConcurrentOperationCount:1];
+ (NSOperationQueue *)databaseQueue {
    return DatabaseQueue;

- (void)writeToDatabase {
    NSInvocationOperation * operation = [[NSInvocationOperation alloc] initWithTarget:self selector:@selector(FUNCTION_THAT_WRITES_TO_DATABASE) object:nil];
    [operation setQueuePriority:NSOperationQueuePriorityHigh];
    [[DatabaseController databaseQueue] addOperations:[NSArray arrayWithObject:operation] waitUntilFinished:YES];
    [operation release];

these two solutions block the current thread until the writing to database is finished which you may consider in most of the cases.

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