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- /*
- * Copyright 2010 Tilera Corporation. All Rights Reserved.
- *
- * This program is free software; you can redistribute it and/or
- * modify it under the terms of the GNU General Public License
- * as published by the Free Software Foundation, version 2.
- *
- * This program 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, GOOD TITLE or
- * NON INFRINGEMENT. See the GNU General Public License for
- * more details.
- *
- * Support routines for atomic operations. Each function takes:
- *
- * r0: address to manipulate
- * r1: pointer to atomic lock guarding this operation (for ATOMIC_LOCK_REG)
- * r2: new value to write, or for cmpxchg/add_unless, value to compare against
- * r3: (cmpxchg/xchg_add_unless) new value to write or add;
- * (atomic64 ops) high word of value to write
- * r4/r5: (cmpxchg64/add_unless64) new value to write or add
- *
- * The 32-bit routines return a "struct __get_user" so that the futex code
- * has an opportunity to return -EFAULT to the user if needed.
- * The 64-bit routines just return a "long long" with the value,
- * since they are only used from kernel space and don't expect to fault.
- * Support for 16-bit ops is included in the framework but we don't provide
- * any (x86_64 has an atomic_inc_short(), so we might want to some day).
- *
- * Note that the caller is advised to issue a suitable L1 or L2
- * prefetch on the address being manipulated to avoid extra stalls.
- * In addition, the hot path is on two icache lines, and we start with
- * a jump to the second line to make sure they are both in cache so
- * that we never stall waiting on icache fill while holding the lock.
- * (This doesn't work out with most 64-bit ops, since they consume
- * too many bundles, so may take an extra i-cache stall.)
- *
- * These routines set the INTERRUPT_CRITICAL_SECTION bit, just
- * like sys_cmpxchg(), so that NMIs like PERF_COUNT will not interrupt
- * the code, just page faults.
- *
- * If the load or store faults in a way that can be directly fixed in
- * the do_page_fault_ics() handler (e.g. a vmalloc reference) we fix it
- * directly, return to the instruction that faulted, and retry it.
- *
- * If the load or store faults in a way that potentially requires us
- * to release the atomic lock, then retry (e.g. a migrating PTE), we
- * reset the PC in do_page_fault_ics() to the "tns" instruction so
- * that on return we will reacquire the lock and restart the op. We
- * are somewhat overloading the exception_table_entry notion by doing
- * this, since those entries are not normally used for migrating PTEs.
- *
- * If the main page fault handler discovers a bad address, it will see
- * the PC pointing to the "tns" instruction (due to the earlier
- * exception_table_entry processing in do_page_fault_ics), and
- * re-reset the PC to the fault handler, atomic_bad_address(), which
- * effectively takes over from the atomic op and can either return a
- * bad "struct __get_user" (for user addresses) or can just panic (for
- * bad kernel addresses).
- *
- * Note that if the value we would store is the same as what we
- * loaded, we bypass the store. Other platforms with true atomics can
- * make the guarantee that a non-atomic __clear_bit(), for example,
- * can safely race with an atomic test_and_set_bit(); this example is
- * from bit_spinlock.h in slub_lock() / slub_unlock(). We can't do
- * that on Tile since the "atomic" op is really just a
- * read/modify/write, and can race with the non-atomic
- * read/modify/write. However, if we can short-circuit the write when
- * it is not needed, in the atomic case, we avoid the race.
- */
- #include <linux/linkage.h>
- #include <asm/atomic_32.h>
- #include <asm/page.h>
- #include <asm/processor.h>
- .section .text.atomic,"ax"
- ENTRY(__start_atomic_asm_code)
- .macro atomic_op, name, bitwidth, body
- .align 64
- STD_ENTRY_SECTION(__atomic\name, .text.atomic)
- {
- movei r24, 1
- j 4f /* branch to second cache line */
- }
- 1: {
- .ifc \bitwidth,16
- lh r22, r0
- .else
- lw r22, r0
- addi r28, r0, 4
- .endif
- }
- .ifc \bitwidth,64
- lw r23, r28
- .endif
- \body /* set r24, and r25 if 64-bit */
- {
- seq r26, r22, r24
- seq r27, r23, r25
- }
- .ifc \bitwidth,64
- bbnst r27, 2f
- .endif
- bbs r26, 3f /* skip write-back if it's the same value */
- 2: {
- .ifc \bitwidth,16
- sh r0, r24
- .else
- sw r0, r24
- .endif
- }
- .ifc \bitwidth,64
- sw r28, r25
- .endif
- mf
- 3: {
- move r0, r22
- .ifc \bitwidth,64
- move r1, r23
- .else
- move r1, zero
- .endif
- sw ATOMIC_LOCK_REG_NAME, zero
- }
- mtspr INTERRUPT_CRITICAL_SECTION, zero
- jrp lr
- 4: {
- move ATOMIC_LOCK_REG_NAME, r1
- mtspr INTERRUPT_CRITICAL_SECTION, r24
- }
- #ifndef CONFIG_SMP
- j 1b /* no atomic locks */
- #else
- {
- tns r21, ATOMIC_LOCK_REG_NAME
- moveli r23, 2048 /* maximum backoff time in cycles */
- }
- {
- bzt r21, 1b /* branch if lock acquired */
- moveli r25, 32 /* starting backoff time in cycles */
- }
- 5: mtspr INTERRUPT_CRITICAL_SECTION, zero
- mfspr r26, CYCLE_LOW /* get start point for this backoff */
- 6: mfspr r22, CYCLE_LOW /* test to see if we've backed off enough */
- sub r22, r22, r26
- slt r22, r22, r25
- bbst r22, 6b
- {
- mtspr INTERRUPT_CRITICAL_SECTION, r24
- shli r25, r25, 1 /* double the backoff; retry the tns */
- }
- {
- tns r21, ATOMIC_LOCK_REG_NAME
- slt r26, r23, r25 /* is the proposed backoff too big? */
- }
- {
- bzt r21, 1b /* branch if lock acquired */
- mvnz r25, r26, r23
- }
- j 5b
- #endif
- STD_ENDPROC(__atomic\name)
- .ifc \bitwidth,32
- .pushsection __ex_table,"a"
- .align 4
- .word 1b, __atomic\name
- .word 2b, __atomic\name
- .word __atomic\name, __atomic_bad_address
- .popsection
- .endif
- .endm
- atomic_op _cmpxchg, 32, "seq r26, r22, r2; { bbns r26, 3f; move r24, r3 }"
- atomic_op _xchg, 32, "move r24, r2"
- atomic_op _xchg_add, 32, "add r24, r22, r2"
- atomic_op _xchg_add_unless, 32, \
- "sne r26, r22, r2; { bbns r26, 3f; add r24, r22, r3 }"
- atomic_op _or, 32, "or r24, r22, r2"
- atomic_op _and, 32, "and r24, r22, r2"
- atomic_op _andn, 32, "nor r2, r2, zero; and r24, r22, r2"
- atomic_op _xor, 32, "xor r24, r22, r2"
- atomic_op 64_cmpxchg, 64, "{ seq r26, r22, r2; seq r27, r23, r3 }; \
- { bbns r26, 3f; move r24, r4 }; { bbns r27, 3f; move r25, r5 }"
- atomic_op 64_xchg, 64, "{ move r24, r2; move r25, r3 }"
- atomic_op 64_xchg_add, 64, "{ add r24, r22, r2; add r25, r23, r3 }; \
- slt_u r26, r24, r22; add r25, r25, r26"
- atomic_op 64_xchg_add_unless, 64, \
- "{ sne r26, r22, r2; sne r27, r23, r3 }; \
- { bbns r26, 3f; add r24, r22, r4 }; \
- { bbns r27, 3f; add r25, r23, r5 }; \
- slt_u r26, r24, r22; add r25, r25, r26"
- atomic_op 64_or, 64, "{ or r24, r22, r2; or r25, r23, r3 }"
- atomic_op 64_and, 64, "{ and r24, r22, r2; and r25, r23, r3 }"
- atomic_op 64_xor, 64, "{ xor r24, r22, r2; xor r25, r23, r3 }"
- jrp lr /* happy backtracer */
- ENTRY(__end_atomic_asm_code)
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