#undef G_DISABLE_ASSERT #undef G_LOG_DOMAIN #include <time.h> #include <stdlib.h> #include <glib.h> #define DEBUG_MSG(args) /* #define DEBUG_MSG(args) g_printerr args ; g_printerr ("\n"); */ #define PRINT_MSG(args) /* #define PRINT_MSG(args) g_print args ; g_print ("\n"); */ #define MAX_THREADS 50 #define MAX_SORTS 5 /* only applies if ASYC_QUEUE_DO_SORT is set to 1 */ #define MAX_TIME 20 /* seconds */ #define MIN_TIME 5 /* seconds */ #define SORT_QUEUE_AFTER 1 #define SORT_QUEUE_ON_PUSH 1 /* if this is done, the SORT_QUEUE_AFTER is ignored */ #define QUIT_WHEN_DONE 1 #if SORT_QUEUE_ON_PUSH == 1 # undef SORT_QUEUE_AFTER # define SORT_QUEUE_AFTER 0 #endif static GMainLoop *main_loop = NULL; static GThreadPool *thread_pool = NULL; static GAsyncQueue *async_queue = NULL; static gint sort_compare (gconstpointer p1, gconstpointer p2, gpointer user_data) { gint32 id1; gint32 id2; id1 = GPOINTER_TO_INT (p1); id2 = GPOINTER_TO_INT (p2); DEBUG_MSG (("comparing #1:%d and #2:%d, returning %d", id1, id2, (id1 > id2 ? +1 : id1 == id2 ? 0 : -1))); return (id1 > id2 ? +1 : id1 == id2 ? 0 : -1); } static gboolean sort_queue (gpointer user_data) { static gint sorts = 0; static gpointer last_p = NULL; gpointer p; gboolean can_quit = FALSE; gint sort_multiplier; gint len; gint i; sort_multiplier = GPOINTER_TO_INT (user_data); if (SORT_QUEUE_AFTER) { PRINT_MSG (("sorting async queue...")); g_async_queue_sort (async_queue, sort_compare, NULL); sorts++; if (sorts >= sort_multiplier) { can_quit = TRUE; } g_async_queue_sort (async_queue, sort_compare, NULL); len = g_async_queue_length (async_queue); PRINT_MSG (("sorted queue (for %d/%d times, size:%d)...", sorts, MAX_SORTS, len)); } else { can_quit = TRUE; len = g_async_queue_length (async_queue); DEBUG_MSG (("printing queue (size:%d)...", len)); } for (i = 0, last_p = NULL; i < len; i++) { p = g_async_queue_pop (async_queue); DEBUG_MSG (("item %d ---> %d", i, GPOINTER_TO_INT (p))); if (last_p) { g_assert (GPOINTER_TO_INT (last_p) <= GPOINTER_TO_INT (p)); } last_p = p; } if (can_quit && QUIT_WHEN_DONE) { g_main_loop_quit (main_loop); } return !can_quit; } static void enter_thread (gpointer data, gpointer user_data) { gint len; gint id; gulong ms; id = GPOINTER_TO_INT (data); ms = g_random_int_range (MIN_TIME * 1000, MAX_TIME * 1000); DEBUG_MSG (("entered thread with id:%d, adding to queue in:%ld ms", id, ms)); g_usleep (ms * 1000); if (SORT_QUEUE_ON_PUSH) { g_async_queue_push_sorted (async_queue, GINT_TO_POINTER (id), sort_compare, NULL); } else { g_async_queue_push (async_queue, GINT_TO_POINTER (id)); } len = g_async_queue_length (async_queue); DEBUG_MSG (("thread id:%d added to async queue (size:%d)", id, len)); } int main (int argc, char *argv[]) { #if defined(G_THREADS_ENABLED) && ! defined(G_THREADS_IMPL_NONE) gint i; gint max_threads = MAX_THREADS; gint max_unused_threads = MAX_THREADS; gint sort_multiplier = MAX_SORTS; gint sort_interval; gchar *msg; g_thread_init (NULL); PRINT_MSG (("creating async queue...")); async_queue = g_async_queue_new (); g_return_val_if_fail (async_queue != NULL, EXIT_FAILURE); PRINT_MSG (("creating thread pool with max threads:%d, max unused threads:%d...", max_threads, max_unused_threads)); thread_pool = g_thread_pool_new (enter_thread, async_queue, max_threads, FALSE, NULL); g_return_val_if_fail (thread_pool != NULL, EXIT_FAILURE); g_thread_pool_set_max_unused_threads (max_unused_threads); PRINT_MSG (("creating threads...")); for (i = 1; i <= max_threads; i++) { GError *error = NULL; g_thread_pool_push (thread_pool, GINT_TO_POINTER (i), &error); g_assert_no_error (error); } if (!SORT_QUEUE_AFTER) { sort_multiplier = 1; } sort_interval = ((MAX_TIME / sort_multiplier) + 2) * 1000; g_timeout_add (sort_interval, sort_queue, GINT_TO_POINTER (sort_multiplier)); if (SORT_QUEUE_ON_PUSH) { msg = "sorting when pushing into the queue, checking queue is sorted"; } else { msg = "sorting"; } PRINT_MSG (("%s %d %s %d ms", msg, sort_multiplier, sort_multiplier == 1 ? "time in" : "times, once every", sort_interval)); DEBUG_MSG (("entering main event loop")); main_loop = g_main_loop_new (NULL, FALSE); g_main_loop_run (main_loop); #endif return EXIT_SUCCESS; }