include/asm-mips/hazards.h - pub/scm/linux/kernel/git/tglx/history - Git at Google

 /*
  * This file is subject to the terms and conditions of the GNU General Public
  * License.  See the file "COPYING" in the main directory of this archive
  * for more details.
  *
  * Copyright (C) 2003, 2004 Ralf Baechle
  */
 #ifndef _ASM_HAZARDS_H
 #define _ASM_HAZARDS_H

 #include <linux/config.h>

 #ifdef __ASSEMBLY__

 	.macro	_ssnop
 	sll	$0, $0, 1
 	.endm

 	.macro	_ehb
 	sll	$0, $0, 3
 	.endm

 /*
  * RM9000 hazards.  When the JTLB is updated by tlbwi or tlbwr, a subsequent
  * use of the JTLB for instructions should not occur for 4 cpu cycles and use
  * for data translations should not occur for 3 cpu cycles.
  */
 #ifdef CONFIG_CPU_RM9000

 	.macro	mtc0_tlbw_hazard
 	.set	push
 	.set	mips32
 	_ssnop; _ssnop; _ssnop; _ssnop
 	.set	pop
 	.endm

 	.macro	tlbw_eret_hazard
 	.set	push
 	.set	mips32
 	_ssnop; _ssnop; _ssnop; _ssnop
 	.set	pop
 	.endm

 #else

 /*
  * The taken branch will result in a two cycle penalty for the two killed
  * instructions on R4000 / R4400.  Other processors only have a single cycle
  * hazard so this is nice trick to have an optimal code for a range of
  * processors.
  */
 	.macro	mtc0_tlbw_hazard
 	b	. + 8
 	.endm

 	.macro	tlbw_eret_hazard
 	.endm
 #endif

 /*
  * mtc0->mfc0 hazard
  * The 24K has a 2 cycle mtc0/mfc0 execution hazard.
  * It is a MIPS32R2 processor so ehb will clear the hazard.
  */

 #ifdef CONFIG_CPU_MIPSR2
 /*
  * Use a macro for ehb unless explicit support for MIPSR2 is enabled
  */

 #define irq_enable_hazard
 	_ehb

 #define irq_disable_hazard
 	_ehb

 #elif defined(CONFIG_CPU_R10000) || defined(CONFIG_CPU_RM9000)

 /*
  * R10000 rocks - all hazards handled in hardware, so this becomes a nobrainer.
  */

 #define irq_enable_hazard

 #define irq_disable_hazard

 #else

 /*
  * Classic MIPS needs 1 - 3 nops or ssnops
  */
 #define irq_enable_hazard
 #define irq_disable_hazard						\
 	_ssnop; _ssnop; _ssnop

 #endif

 #else /* __ASSEMBLY__ */

 __asm__(
 	"	.macro	_ssnop					\n\t"
 	"	sll	$0, $2, 1				\n\t"
 	"	.endm						\n\t"
 	"							\n\t"
 	"	.macro	_ehb					\n\t"
 	"	sll	$0, $0, 3				\n\t"
 	"	.endm						\n\t");

 #ifdef CONFIG_CPU_RM9000
 /*
  * RM9000 hazards.  When the JTLB is updated by tlbwi or tlbwr, a subsequent
  * use of the JTLB for instructions should not occur for 4 cpu cycles and use
  * for data translations should not occur for 3 cpu cycles.
  */

 #define mtc0_tlbw_hazard()						\
 	__asm__ __volatile__(						\
 		".set\tmips32\n\t"					\
 		"_ssnop; _ssnop; _ssnop; _ssnop\n\t"			\
 		".set\tmips0")

 #define tlbw_use_hazard()						\
 	__asm__ __volatile__(						\
 		".set\tmips32\n\t"					\
 		"_ssnop; _ssnop; _ssnop; _ssnop\n\t"			\
 		".set\tmips0")
 #else

 /*
  * Overkill warning ...
  */
 #define mtc0_tlbw_hazard()						\
 	__asm__ __volatile__(						\
 		".set noreorder\n\t"					\
 		"nop; nop; nop; nop; nop; nop;\n\t"			\
 		".set reorder\n\t")

 #define tlbw_use_hazard()						\
 	__asm__ __volatile__(						\
 		".set noreorder\n\t"					\
 		"nop; nop; nop; nop; nop; nop;\n\t"			\
 		".set reorder\n\t")

 #endif

 /*
  * mtc0->mfc0 hazard
  * The 24K has a 2 cycle mtc0/mfc0 execution hazard.
  * It is a MIPS32R2 processor so ehb will clear the hazard.
  */

 #ifdef CONFIG_CPU_MIPSR2
 /*
  * Use a macro for ehb unless explicit support for MIPSR2 is enabled
  */
 __asm__(
 	"	.macro\tirq_enable_hazard			\n\t"
 	"	_ehb						\n\t"
 	"	.endm						\n\t"
 	"							\n\t"
 	"	.macro\tirq_disable_hazard			\n\t"
 	"	_ehb						\n\t"
 	"	.endm");

 #define irq_enable_hazard()						\
 	__asm__ __volatile__(						\
 	"_ehb\t\t\t\t# irq_enable_hazard")

 #define irq_disable_hazard()						\
 	__asm__ __volatile__(						\
 	"_ehb\t\t\t\t# irq_disable_hazard")

 #elif defined(CONFIG_CPU_R10000) || defined(CONFIG_CPU_RM9000)

 /*
  * R10000 rocks - all hazards handled in hardware, so this becomes a nobrainer.
  */

 __asm__(
 	"	.macro\tirq_enable_hazard			\n\t"
 	"	.endm						\n\t"
 	"							\n\t"
 	"	.macro\tirq_disable_hazard			\n\t"
 	"	.endm");

 #define irq_enable_hazard()	do { } while (0)
 #define irq_disable_hazard()	do { } while (0)

 #else

 /*
  * Default for classic MIPS processors.  Assume worst case hazards but don't
  * care about the irq_enable_hazard - sooner or later the hardware will
  * enable it and we don't care when exactly.
  */

 __asm__(
 	"	#						\n\t"
 	"	# There is a hazard but we do not care		\n\t"
 	"	#						\n\t"
 	"	.macro\tirq_enable_hazard			\n\t"
 	"	.endm						\n\t"
 	"							\n\t"
 	"	.macro\tirq_disable_hazard			\n\t"
 	"	_ssnop; _ssnop; _ssnop				\n\t"
 	"	.endm");

 #define irq_enable_hazard()	do { } while (0)
 #define irq_disable_hazard()						\
 	__asm__ __volatile__(						\
 	"_ssnop; _ssnop; _ssnop;\t\t# irq_disable_hazard")

 #endif

 #endif /* __ASSEMBLY__ */

 #endif /* _ASM_HAZARDS_H */
	/*
	* This file is subject to the terms and conditions of the GNU General Public
	* License. See the file "COPYING" in the main directory of this archive
	* for more details.
	*
	* Copyright (C) 2003, 2004 Ralf Baechle
	*/
	#ifndef _ASM_HAZARDS_H
	#define _ASM_HAZARDS_H

	#include <linux/config.h>

	#ifdef __ASSEMBLY__

	.macro _ssnop
	sll $0, $0, 1
	.endm

	.macro _ehb
	sll $0, $0, 3
	.endm

	/*
	* RM9000 hazards. When the JTLB is updated by tlbwi or tlbwr, a subsequent
	* use of the JTLB for instructions should not occur for 4 cpu cycles and use
	* for data translations should not occur for 3 cpu cycles.
	*/
	#ifdef CONFIG_CPU_RM9000

	.macro mtc0_tlbw_hazard
	.set push
	.set mips32
	_ssnop; _ssnop; _ssnop; _ssnop
	.set pop
	.endm

	.macro tlbw_eret_hazard
	.set push
	.set mips32
	_ssnop; _ssnop; _ssnop; _ssnop
	.set pop
	.endm

	#else

	/*
	* The taken branch will result in a two cycle penalty for the two killed
	* instructions on R4000 / R4400. Other processors only have a single cycle
	* hazard so this is nice trick to have an optimal code for a range of
	* processors.
	*/
	.macro mtc0_tlbw_hazard
	b . + 8
	.endm

	.macro tlbw_eret_hazard
	.endm
	#endif

	/*
	* mtc0->mfc0 hazard
	* The 24K has a 2 cycle mtc0/mfc0 execution hazard.
	* It is a MIPS32R2 processor so ehb will clear the hazard.
	*/

	#ifdef CONFIG_CPU_MIPSR2
	/*
	* Use a macro for ehb unless explicit support for MIPSR2 is enabled
	*/

	#define irq_enable_hazard
	_ehb

	#define irq_disable_hazard
	_ehb

	#elif defined(CONFIG_CPU_R10000) \|\| defined(CONFIG_CPU_RM9000)

	/*
	* R10000 rocks - all hazards handled in hardware, so this becomes a nobrainer.
	*/

	#define irq_enable_hazard

	#define irq_disable_hazard

	#else

	/*
	* Classic MIPS needs 1 - 3 nops or ssnops
	*/
	#define irq_enable_hazard
	#define irq_disable_hazard \
	_ssnop; _ssnop; _ssnop

	#endif

	#else /* __ASSEMBLY__ */

	__asm__(
	" .macro _ssnop \n\t"
	" sll $0, $2, 1 \n\t"
	" .endm \n\t"
	" \n\t"
	" .macro _ehb \n\t"
	" sll $0, $0, 3 \n\t"
	" .endm \n\t");

	#ifdef CONFIG_CPU_RM9000
	/*
	* RM9000 hazards. When the JTLB is updated by tlbwi or tlbwr, a subsequent
	* use of the JTLB for instructions should not occur for 4 cpu cycles and use
	* for data translations should not occur for 3 cpu cycles.
	*/

	#define mtc0_tlbw_hazard() \
	__asm__ __volatile__( \
	".set\tmips32\n\t" \
	"_ssnop; _ssnop; _ssnop; _ssnop\n\t" \
	".set\tmips0")

	#define tlbw_use_hazard() \
	__asm__ __volatile__( \
	".set\tmips32\n\t" \
	"_ssnop; _ssnop; _ssnop; _ssnop\n\t" \
	".set\tmips0")
	#else

	/*
	* Overkill warning ...
	*/
	#define mtc0_tlbw_hazard() \
	__asm__ __volatile__( \
	".set noreorder\n\t" \
	"nop; nop; nop; nop; nop; nop;\n\t" \
	".set reorder\n\t")

	#define tlbw_use_hazard() \
	__asm__ __volatile__( \
	".set noreorder\n\t" \
	"nop; nop; nop; nop; nop; nop;\n\t" \
	".set reorder\n\t")

	#endif

	/*
	* mtc0->mfc0 hazard
	* The 24K has a 2 cycle mtc0/mfc0 execution hazard.
	* It is a MIPS32R2 processor so ehb will clear the hazard.
	*/

	#ifdef CONFIG_CPU_MIPSR2
	/*
	* Use a macro for ehb unless explicit support for MIPSR2 is enabled
	*/
	__asm__(
	" .macro\tirq_enable_hazard \n\t"
	" _ehb \n\t"
	" .endm \n\t"
	" \n\t"
	" .macro\tirq_disable_hazard \n\t"
	" _ehb \n\t"
	" .endm");

	#define irq_enable_hazard() \
	__asm__ __volatile__( \
	"_ehb\t\t\t\t# irq_enable_hazard")

	#define irq_disable_hazard() \
	__asm__ __volatile__( \
	"_ehb\t\t\t\t# irq_disable_hazard")

	#elif defined(CONFIG_CPU_R10000) \|\| defined(CONFIG_CPU_RM9000)

	/*
	* R10000 rocks - all hazards handled in hardware, so this becomes a nobrainer.
	*/

	__asm__(
	" .macro\tirq_enable_hazard \n\t"
	" .endm \n\t"
	" \n\t"
	" .macro\tirq_disable_hazard \n\t"
	" .endm");

	#define irq_enable_hazard() do { } while (0)
	#define irq_disable_hazard() do { } while (0)

	#else

	/*
	* Default for classic MIPS processors. Assume worst case hazards but don't
	* care about the irq_enable_hazard - sooner or later the hardware will
	* enable it and we don't care when exactly.
	*/

	__asm__(
	" # \n\t"
	" # There is a hazard but we do not care \n\t"
	" # \n\t"
	" .macro\tirq_enable_hazard \n\t"
	" .endm \n\t"
	" \n\t"
	" .macro\tirq_disable_hazard \n\t"
	" _ssnop; _ssnop; _ssnop \n\t"
	" .endm");

	#define irq_enable_hazard() do { } while (0)
	#define irq_disable_hazard() \
	__asm__ __volatile__( \
	"_ssnop; _ssnop; _ssnop;\t\t# irq_disable_hazard")

	#endif

	#endif /* __ASSEMBLY__ */

	#endif /* _ASM_HAZARDS_H */