#ifndef __SPARC64_BARRIER_H #define __SPARC64_BARRIER_H /* These are here in an effort to more fully work around Spitfire Errata * #51. Essentially, if a memory barrier occurs soon after a mispredicted * branch, the chip can stop executing instructions until a trap occurs. * Therefore, if interrupts are disabled, the chip can hang forever. * * It used to be believed that the memory barrier had to be right in the * delay slot, but a case has been traced recently wherein the memory barrier * was one instruction after the branch delay slot and the chip still hung. * The offending sequence was the following in sym_wakeup_done() of the * sym53c8xx_2 driver: * * call sym_ccb_from_dsa, 0 * movge %icc, 0, %l0 * brz,pn %o0, .LL1303 * mov %o0, %l2 * membar #LoadLoad * * The branch has to be mispredicted for the bug to occur. Therefore, we put * the memory barrier explicitly into a "branch always, predicted taken" * delay slot to avoid the problem case. */ #define membar_safe(type) \ do { __asm__ __volatile__("ba,pt %%xcc, 1f\n\t" \ " membar " type "\n" \ "1:\n" \ : : : "memory"); \ } while (0) /* The kernel always executes in TSO memory model these days, * and furthermore most sparc64 chips implement more stringent * memory ordering than required by the specifications. */ #define mb() membar_safe("#StoreLoad") #define rmb() __asm__ __volatile__("":::"memory") #define wmb() __asm__ __volatile__("":::"memory") #define __smp_store_release(p, v) \ do { \ compiletime_assert_atomic_type(*p); \ barrier(); \ WRITE_ONCE(*p, v); \ } while (0) #define __smp_load_acquire(p) \ ({ \ typeof(*p) ___p1 = READ_ONCE(*p); \ compiletime_assert_atomic_type(*p); \ barrier(); \ ___p1; \ }) #define __smp_mb__before_atomic() barrier() #define __smp_mb__after_atomic() barrier() #include <asm-generic/barrier.h> #endif /* !(__SPARC64_BARRIER_H) */ |