/* * Copyright © 2008 Ryan Lortie * Copyright © 2010 Codethink Limited * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the licence, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * * Author: Ryan Lortie */ #include "gbitlock.h" #include #include #include #include #include #include "gthreadprivate.h" #include "config.h" #undef HAVE_FUTEX #ifdef G_BIT_LOCK_FORCE_FUTEX_EMULATION #endif #ifndef HAVE_FUTEX static GMutex g_futex_mutex; static GSList *g_futex_address_list = NULL; #endif #ifdef HAVE_FUTEX /* * We have headers for futex(2) on the build machine. This does not * imply that every system that ever runs the resulting glib will have * kernel support for futex, but you'd have to have a pretty old * kernel in order for that not to be the case. * * If anyone actually gets bit by this, please file a bug. :) */ #include #include #include /* < private > * g_futex_wait: * @address: a pointer to an integer * @value: the value that should be at @address * * Atomically checks that the value stored at @address is equal to * @value and then blocks. If the value stored at @address is not * equal to @value then this function returns immediately. * * To unblock, call g_futex_wake() on @address. * * This call may spuriously unblock (for example, in response to the * process receiving a signal) but this is not guaranteed. Unlike the * Linux system call of a similar name, there is no guarantee that a * waiting process will unblock due to a g_futex_wake() call in a * separate process. */ static void g_futex_wait (const volatile gint *address, gint value) { syscall (__NR_futex, address, (gsize) FUTEX_WAIT, (gsize) value, NULL); } /* < private > * g_futex_wake: * @address: a pointer to an integer * * Nominally, wakes one thread that is blocked in g_futex_wait() on * @address (if any thread is currently waiting). * * As mentioned in the documention for g_futex_wait(), spurious * wakeups may occur. As such, this call may result in more than one * thread being woken up. */ static void g_futex_wake (const volatile gint *address) { syscall (__NR_futex, address, (gsize) FUTEX_WAKE, (gsize) 1, NULL); } #else /* emulate futex(2) */ typedef struct { const volatile gint *address; gint ref_count; GCond wait_queue; } WaitAddress; static WaitAddress * g_futex_find_address (const volatile gint *address) { GSList *node; for (node = g_futex_address_list; node; node = node->next) { WaitAddress *waiter = node->data; if (waiter->address == address) return waiter; } return NULL; } static void g_futex_wait (const volatile gint *address, gint value) { g_mutex_lock (&g_futex_mutex); if G_LIKELY (g_atomic_int_get (address) == value) { WaitAddress *waiter; if ((waiter = g_futex_find_address (address)) == NULL) { waiter = g_slice_new (WaitAddress); waiter->address = address; g_cond_init (&waiter->wait_queue); waiter->ref_count = 0; g_futex_address_list = g_slist_prepend (g_futex_address_list, waiter); } waiter->ref_count++; g_cond_wait (&waiter->wait_queue, &g_futex_mutex); if (!--waiter->ref_count) { g_futex_address_list = g_slist_remove (g_futex_address_list, waiter); g_cond_clear (&waiter->wait_queue); g_slice_free (WaitAddress, waiter); } } g_mutex_unlock (&g_futex_mutex); } static void g_futex_wake (const volatile gint *address) { WaitAddress *waiter; /* need to lock here for two reasons: * 1) need to acquire/release lock to ensure waiter is not in * the process of registering a wait * 2) need to -stay- locked until the end to ensure a wake() * in another thread doesn't cause 'waiter' to stop existing */ g_mutex_lock (&g_futex_mutex); if ((waiter = g_futex_find_address (address))) g_cond_signal (&waiter->wait_queue); g_mutex_unlock (&g_futex_mutex); } #endif #define CONTENTION_CLASSES 11 static volatile gint g_bit_lock_contended[CONTENTION_CLASSES]; #if (defined (i386) || defined (__amd64__)) #if __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 5) #define USE_ASM_GOTO 1 #endif #endif /** * g_bit_lock: * @address: a pointer to an integer * @lock_bit: a bit value between 0 and 31 * * Sets the indicated @lock_bit in @address. If the bit is already * set, this call will block until g_bit_unlock() unsets the * corresponding bit. * * Attempting to lock on two different bits within the same integer is * not supported and will very probably cause deadlocks. * * The value of the bit that is set is (1u << @bit). If @bit is not * between 0 and 31 then the result is undefined. * * This function accesses @address atomically. All other accesses to * @address must be atomic in order for this function to work * reliably. * * Since: 2.24 **/ void g_bit_lock (volatile gint *address, gint lock_bit) { #ifdef USE_ASM_GOTO retry: asm volatile goto ("lock bts %1, (%0)\n" "jc %l[contended]" : /* no output */ : "r" (address), "r" (lock_bit) : "cc", "memory" : contended); return; contended: { guint mask = 1u << lock_bit; guint v; v = g_atomic_int_get (address); if (v & mask) { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); g_atomic_int_add (&g_bit_lock_contended[class], +1); g_futex_wait (address, v); g_atomic_int_add (&g_bit_lock_contended[class], -1); } } goto retry; #else guint mask = 1u << lock_bit; guint v; retry: v = g_atomic_int_or (address, mask); if (v & mask) /* already locked */ { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); g_atomic_int_add (&g_bit_lock_contended[class], +1); g_futex_wait (address, v); g_atomic_int_add (&g_bit_lock_contended[class], -1); goto retry; } #endif } /** * g_bit_trylock: * @address: a pointer to an integer * @lock_bit: a bit value between 0 and 31 * * Sets the indicated @lock_bit in @address, returning %TRUE if * successful. If the bit is already set, returns %FALSE immediately. * * Attempting to lock on two different bits within the same integer is * not supported. * * The value of the bit that is set is (1u << @bit). If @bit is not * between 0 and 31 then the result is undefined. * * This function accesses @address atomically. All other accesses to * @address must be atomic in order for this function to work * reliably. * * Returns: %TRUE if the lock was acquired * * Since: 2.24 **/ gboolean g_bit_trylock (volatile gint *address, gint lock_bit) { #ifdef USE_ASM_GOTO gboolean result; asm volatile ("lock bts %2, (%1)\n" "setnc %%al\n" "movzx %%al, %0" : "=r" (result) : "r" (address), "r" (lock_bit) : "cc", "memory"); return result; #else guint mask = 1u << lock_bit; guint v; v = g_atomic_int_or (address, mask); return ~v & mask; #endif } /** * g_bit_unlock: * @address: a pointer to an integer * @lock_bit: a bit value between 0 and 31 * * Clears the indicated @lock_bit in @address. If another thread is * currently blocked in g_bit_lock() on this same bit then it will be * woken up. * * This function accesses @address atomically. All other accesses to * @address must be atomic in order for this function to work * reliably. * * Since: 2.24 **/ void g_bit_unlock (volatile gint *address, gint lock_bit) { #ifdef USE_ASM_GOTO asm volatile ("lock btr %1, (%0)" : /* no output */ : "r" (address), "r" (lock_bit) : "cc", "memory"); #else guint mask = 1u << lock_bit; g_atomic_int_and (address, ~mask); #endif { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); if (g_atomic_int_get (&g_bit_lock_contended[class])) g_futex_wake (address); } } /* We emulate pointer-sized futex(2) because the kernel API only * supports integers. * * We assume that the 'interesting' part is always the lower order bits. * This assumption holds because pointer bitlocks are restricted to * using the low order bits of the pointer as the lock. * * On 32 bits, there is nothing to do since the pointer size is equal to * the integer size. On little endian the lower-order bits don't move, * so do nothing. Only on 64bit big endian do we need to do a bit of * pointer arithmetic: the low order bits are shifted by 4 bytes. We * have a helper function that always does the right thing here. * * Since we always consider the low-order bits of the integer value, a * simple cast from (gsize) to (guint) always takes care of that. * * After that, pointer-sized futex becomes as simple as: * * g_futex_wait (g_futex_int_address (address), (guint) value); * * and * * g_futex_wake (g_futex_int_address (int_address)); */ static const volatile gint * g_futex_int_address (const volatile void *address) { const volatile gint *int_address = address; /* this implementation makes these (reasonable) assumptions: */ G_STATIC_ASSERT (G_BYTE_ORDER == G_LITTLE_ENDIAN || (G_BYTE_ORDER == G_BIG_ENDIAN && sizeof (int) == 4 && (sizeof (gpointer) == 4 || sizeof (gpointer) == 8))); #if G_BYTE_ORDER == G_BIG_ENDIAN && GLIB_SIZEOF_VOID_P == 8 int_address++; #endif return int_address; } /** * g_pointer_bit_lock: * @address: a pointer to a #gpointer-sized value * @lock_bit: a bit value between 0 and 31 * * This is equivalent to g_bit_lock, but working on pointers (or other * pointer-sized values). * * For portability reasons, you may only lock on the bottom 32 bits of * the pointer. * * Since: 2.30 **/ void (g_pointer_bit_lock) (volatile void *address, gint lock_bit) { g_return_if_fail (lock_bit < 32); { #ifdef USE_ASM_GOTO retry: asm volatile goto ("lock bts %1, (%0)\n" "jc %l[contended]" : /* no output */ : "r" (address), "r" ((gsize) lock_bit) : "cc", "memory" : contended); return; contended: { volatile gsize *pointer_address = address; gsize mask = 1u << lock_bit; gsize v; v = (gsize) g_atomic_pointer_get (pointer_address); if (v & mask) { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); g_atomic_int_add (&g_bit_lock_contended[class], +1); g_futex_wait (g_futex_int_address (address), v); g_atomic_int_add (&g_bit_lock_contended[class], -1); } } goto retry; #else volatile gsize *pointer_address = address; gsize mask = 1u << lock_bit; gsize v; retry: v = g_atomic_pointer_or (pointer_address, mask); if (v & mask) /* already locked */ { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); g_atomic_int_add (&g_bit_lock_contended[class], +1); g_futex_wait (g_futex_int_address (address), (guint) v); g_atomic_int_add (&g_bit_lock_contended[class], -1); goto retry; } #endif } } /** * g_pointer_bit_trylock: * @address: a pointer to a #gpointer-sized value * @lock_bit: a bit value between 0 and 31 * * This is equivalent to g_bit_trylock, but working on pointers (or * other pointer-sized values). * * For portability reasons, you may only lock on the bottom 32 bits of * the pointer. * * Returns: %TRUE if the lock was acquired * * Since: 2.30 **/ gboolean (g_pointer_bit_trylock) (volatile void *address, gint lock_bit) { g_return_val_if_fail (lock_bit < 32, FALSE); { #ifdef USE_ASM_GOTO gboolean result; asm volatile ("lock bts %2, (%1)\n" "setnc %%al\n" "movzx %%al, %0" : "=r" (result) : "r" (address), "r" ((gsize) lock_bit) : "cc", "memory"); return result; #else volatile gsize *pointer_address = address; gsize mask = 1u << lock_bit; gsize v; g_return_val_if_fail (lock_bit < 32, FALSE); v = g_atomic_pointer_or (pointer_address, mask); return ~v & mask; #endif } } /** * g_pointer_bit_unlock: * @address: a pointer to a #gpointer-sized value * @lock_bit: a bit value between 0 and 31 * * This is equivalent to g_bit_unlock, but working on pointers (or other * pointer-sized values). * * For portability reasons, you may only lock on the bottom 32 bits of * the pointer. * * Since: 2.30 **/ void (g_pointer_bit_unlock) (volatile void *address, gint lock_bit) { g_return_if_fail (lock_bit < 32); { #ifdef USE_ASM_GOTO asm volatile ("lock btr %1, (%0)" : /* no output */ : "r" (address), "r" ((gsize) lock_bit) : "cc", "memory"); #else volatile gsize *pointer_address = address; gsize mask = 1u << lock_bit; g_atomic_pointer_and (pointer_address, ~mask); #endif { guint class = ((gsize) address) % G_N_ELEMENTS (g_bit_lock_contended); if (g_atomic_int_get (&g_bit_lock_contended[class])) g_futex_wake (g_futex_int_address (address)); } } }