arch/sparc/include/asm/backoff.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 #ifndef _SPARC64_BACKOFF_H
 #define _SPARC64_BACKOFF_H

 /* The macros in this file implement an exponential backoff facility
  * for atomic operations.
  *
  * When multiple threads compete on an atomic operation, it is
  * possible for one thread to be continually denied a successful
  * completion of the compare-and-swap instruction.  Heavily
  * threaded cpu implementations like Niagara can compound this
  * problem even further.
  *
  * When an atomic operation fails and needs to be retried, we spin a
  * certain number of times.  At each subsequent failure of the same
  * operation we double the spin count, realizing an exponential
  * backoff.
  *
  * When we spin, we try to use an operation that will cause the
  * current cpu strand to block, and therefore make the core fully
  * available to any other runnable strands.  There are two
  * options, based upon cpu capabilities.
  *
  * On all cpus prior to SPARC-T4 we do three dummy reads of the
  * condition code register.  Each read blocks the strand for something
  * between 40 and 50 cpu cycles.
  *
  * For SPARC-T4 and later we have a special "pause" instruction
  * available.  This is implemented using writes to register %asr27.
  * The cpu will block the number of cycles written into the register,
  * unless a disrupting trap happens first.  SPARC-T4 specifically
  * implements pause with a granularity of 8 cycles.  Each strand has
  * an internal pause counter which decrements every 8 cycles.  So the
  * chip shifts the %asr27 value down by 3 bits, and writes the result
  * into the pause counter.  If a value smaller than 8 is written, the
  * chip blocks for 1 cycle.
  *
  * To achieve the same amount of backoff as the three %ccr reads give
  * on earlier chips, we shift the backoff value up by 7 bits.  (Three
  * %ccr reads block for about 128 cycles, 1 << 7 == 128) We write the
  * whole amount we want to block into the pause register, rather than
  * loop writing 128 each time.
  */

 #define BACKOFF_LIMIT	(4 * 1024)

 #ifdef CONFIG_SMP

 #define BACKOFF_SETUP(reg)	\
 	mov	1, reg

 #define BACKOFF_LABEL(spin_label, continue_label) \
 	spin_label

 #define BACKOFF_SPIN(reg, tmp, label)		\
 	mov		reg, tmp;		\
 88:	rd		%ccr, %g0;		\
 	rd		%ccr, %g0;		\
 	rd		%ccr, %g0;		\
 	.section	.pause_3insn_patch,"ax";\
 	.word		88b;			\
 	sllx		tmp, 7, tmp;		\
 	wr		tmp, 0, %asr27;		\
 	clr		tmp;			\
 	.previous;				\
 	brnz,pt		tmp, 88b;		\
 	 sub		tmp, 1, tmp;		\
 	set		BACKOFF_LIMIT, tmp;	\
 	cmp		reg, tmp;		\
 	bg,pn		%xcc, label;		\
 	 nop;					\
 	ba,pt		%xcc, label;		\
 	 sllx		reg, 1, reg;

 #else

 #define BACKOFF_SETUP(reg)

 #define BACKOFF_LABEL(spin_label, continue_label) \
 	continue_label

 #define BACKOFF_SPIN(reg, tmp, label)

 #endif

 #endif /* _SPARC64_BACKOFF_H */
	/* SPDX-License-Identifier: GPL-2.0 */
	#ifndef _SPARC64_BACKOFF_H
	#define _SPARC64_BACKOFF_H

	/* The macros in this file implement an exponential backoff facility
	* for atomic operations.
	*
	* When multiple threads compete on an atomic operation, it is
	* possible for one thread to be continually denied a successful
	* completion of the compare-and-swap instruction. Heavily
	* threaded cpu implementations like Niagara can compound this
	* problem even further.
	*
	* When an atomic operation fails and needs to be retried, we spin a
	* certain number of times. At each subsequent failure of the same
	* operation we double the spin count, realizing an exponential
	* backoff.
	*
	* When we spin, we try to use an operation that will cause the
	* current cpu strand to block, and therefore make the core fully
	* available to any other runnable strands. There are two
	* options, based upon cpu capabilities.
	*
	* On all cpus prior to SPARC-T4 we do three dummy reads of the
	* condition code register. Each read blocks the strand for something
	* between 40 and 50 cpu cycles.
	*
	* For SPARC-T4 and later we have a special "pause" instruction
	* available. This is implemented using writes to register %asr27.
	* The cpu will block the number of cycles written into the register,
	* unless a disrupting trap happens first. SPARC-T4 specifically
	* implements pause with a granularity of 8 cycles. Each strand has
	* an internal pause counter which decrements every 8 cycles. So the
	* chip shifts the %asr27 value down by 3 bits, and writes the result
	* into the pause counter. If a value smaller than 8 is written, the
	* chip blocks for 1 cycle.
	*
	* To achieve the same amount of backoff as the three %ccr reads give
	* on earlier chips, we shift the backoff value up by 7 bits. (Three
	* %ccr reads block for about 128 cycles, 1 << 7 == 128) We write the
	* whole amount we want to block into the pause register, rather than
	* loop writing 128 each time.
	*/

	#define BACKOFF_LIMIT (4 * 1024)

	#ifdef CONFIG_SMP

	#define BACKOFF_SETUP(reg) \
	mov 1, reg

	#define BACKOFF_LABEL(spin_label, continue_label) \
	spin_label

	#define BACKOFF_SPIN(reg, tmp, label) \
	mov reg, tmp; \
	88: rd %ccr, %g0; \
	rd %ccr, %g0; \
	rd %ccr, %g0; \
	.section .pause_3insn_patch,"ax";\
	.word 88b; \
	sllx tmp, 7, tmp; \
	wr tmp, 0, %asr27; \
	clr tmp; \
	.previous; \
	brnz,pt tmp, 88b; \
	sub tmp, 1, tmp; \
	set BACKOFF_LIMIT, tmp; \
	cmp reg, tmp; \
	bg,pn %xcc, label; \
	nop; \
	ba,pt %xcc, label; \
	sllx reg, 1, reg;

	#else

	#define BACKOFF_SETUP(reg)

	#define BACKOFF_LABEL(spin_label, continue_label) \
	continue_label

	#define BACKOFF_SPIN(reg, tmp, label)

	#endif

	#endif /* _SPARC64_BACKOFF_H */