arch/powerpc/kernel/switch.S - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-or-later */
 #include <linux/objtool.h>
 #include <asm/asm-offsets.h>
 #include <asm/code-patching-asm.h>
 #include <asm/mmu.h>
 #include <asm/ppc_asm.h>
 #include <asm/kup.h>
 #include <asm/thread_info.h>

 .section ".text","ax",@progbits

 #ifdef CONFIG_PPC_BOOK3S_64
 /*
  * Cancel all explict user streams as they will have no use after context
  * switch and will stop the HW from creating streams itself
  */
 #define STOP_STREAMS		\
 	DCBT_BOOK3S_STOP_ALL_STREAM_IDS(r6)

 #define FLUSH_COUNT_CACHE	\
 1:	nop;			\
 	patch_site 1b, patch__call_flush_branch_caches1; \
 1:	nop;			\
 	patch_site 1b, patch__call_flush_branch_caches2; \
 1:	nop;			\
 	patch_site 1b, patch__call_flush_branch_caches3

 .macro nops number
 	.rept \number
 	nop
 	.endr
 .endm

 .balign 32
 .global flush_branch_caches
 flush_branch_caches:
 	/* Save LR into r9 */
 	mflr	r9

 	// Flush the link stack
 	.rept 64
 	ANNOTATE_INTRA_FUNCTION_CALL
 	bl	.+4
 	.endr
 	b	1f
 	nops	6

 	.balign 32
 	/* Restore LR */
 1:	mtlr	r9

 	// If we're just flushing the link stack, return here
 3:	nop
 	patch_site 3b patch__flush_link_stack_return

 	li	r9,0x7fff
 	mtctr	r9

 	PPC_BCCTR_FLUSH

 2:	nop
 	patch_site 2b patch__flush_count_cache_return

 	nops	3

 	.rept 278
 	.balign 32
 	PPC_BCCTR_FLUSH
 	nops	7
 	.endr

 	blr

 #ifdef CONFIG_PPC_64S_HASH_MMU
 .balign 32
 /*
  * New stack pointer in r8, old stack pointer in r1, must not clobber r3
  */
 pin_stack_slb:
 BEGIN_FTR_SECTION
 	clrrdi	r6,r8,28	/* get its ESID */
 	clrrdi	r9,r1,28	/* get current sp ESID */
 FTR_SECTION_ELSE
 	clrrdi	r6,r8,40	/* get its 1T ESID */
 	clrrdi	r9,r1,40	/* get current sp 1T ESID */
 ALT_MMU_FTR_SECTION_END_IFCLR(MMU_FTR_1T_SEGMENT)
 	clrldi.	r0,r6,2		/* is new ESID c00000000? */
 	cmpd	cr1,r6,r9	/* or is new ESID the same as current ESID? */
 	cror	eq,4*cr1+eq,eq
 	beq	2f		/* if yes, don't slbie it */

 	/* Bolt in the new stack SLB entry */
 	ld	r7,KSP_VSID(r4)	/* Get new stack's VSID */
 	oris	r0,r6,(SLB_ESID_V)@h
 	ori	r0,r0,(SLB_NUM_BOLTED-1)@l
 BEGIN_FTR_SECTION
 	li	r9,MMU_SEGSIZE_1T	/* insert B field */
 	oris	r6,r6,(MMU_SEGSIZE_1T << SLBIE_SSIZE_SHIFT)@h
 	rldimi	r7,r9,SLB_VSID_SSIZE_SHIFT,0
 END_MMU_FTR_SECTION_IFSET(MMU_FTR_1T_SEGMENT)

 	/* Update the last bolted SLB.  No write barriers are needed
 	 * here, provided we only update the current CPU's SLB shadow
 	 * buffer.
 	 */
 	ld	r9,PACA_SLBSHADOWPTR(r13)
 	li	r12,0
 	std	r12,SLBSHADOW_STACKESID(r9)	/* Clear ESID */
 	li	r12,SLBSHADOW_STACKVSID
 	STDX_BE	r7,r12,r9			/* Save VSID */
 	li	r12,SLBSHADOW_STACKESID
 	STDX_BE	r0,r12,r9			/* Save ESID */

 	/* No need to check for MMU_FTR_NO_SLBIE_B here, since when
 	 * we have 1TB segments, the only CPUs known to have the errata
 	 * only support less than 1TB of system memory and we'll never
 	 * actually hit this code path.
 	 */

 	isync
 	slbie	r6
 BEGIN_FTR_SECTION
 	slbie	r6		/* Workaround POWER5 < DD2.1 issue */
 END_FTR_SECTION_IFCLR(CPU_FTR_ARCH_207S)
 	slbmte	r7,r0
 	isync
 2:	blr
 	.size pin_stack_slb,.-pin_stack_slb
 #endif /* CONFIG_PPC_64S_HASH_MMU */

 #else
 #define STOP_STREAMS
 #define FLUSH_COUNT_CACHE
 #endif /* CONFIG_PPC_BOOK3S_64 */

 /*
  * do_switch_32/64 have the same calling convention as _switch, i.e., r3,r4
  * are prev and next thread_struct *, and returns prev task_struct * in r3.

  * This switches the stack, current, and does other task switch housekeeping.
  */
 .macro do_switch_32
 	tophys(r0,r4)
 	mtspr	SPRN_SPRG_THREAD,r0	/* Update current THREAD phys addr */
 	lwz	r1,KSP(r4)	/* Load new stack pointer */

 	/* save the old current 'last' for return value */
 	mr	r3,r2
 	addi	r2,r4,-THREAD	/* Update current */
 .endm

 .macro do_switch_64
 	ld	r8,KSP(r4)	/* Load new stack pointer */

 	kuap_check_amr r9, r10

 	FLUSH_COUNT_CACHE	/* Clobbers r9, ctr */

 	STOP_STREAMS		/* Clobbers r6 */

 	addi	r3,r3,-THREAD	/* old thread -> task_struct for return value */
 	addi	r6,r4,-THREAD	/* new thread -> task_struct */
 	std	r6,PACACURRENT(r13)	/* Set new task_struct to 'current' */
 #if defined(CONFIG_STACKPROTECTOR)
 	ld	r6, TASK_CANARY(r6)
 	std	r6, PACA_CANARY(r13)
 #endif
 	/* Set new PACAKSAVE */
 	clrrdi	r7,r8,THREAD_SHIFT	/* base of new stack */
 	addi	r7,r7,THREAD_SIZE-SWITCH_FRAME_SIZE
 	std	r7,PACAKSAVE(r13)

 #ifdef CONFIG_PPC_64S_HASH_MMU
 BEGIN_MMU_FTR_SECTION
 	bl	pin_stack_slb
 END_MMU_FTR_SECTION_IFCLR(MMU_FTR_TYPE_RADIX)
 #endif
 	/*
 	 * PMU interrupts in radix may come in here. They will use r1, not
 	 * PACAKSAVE, so this stack switch will not cause a problem. They
 	 * will store to the process stack, which may then be migrated to
 	 * another CPU. However the rq lock release on this CPU paired with
 	 * the rq lock acquire on the new CPU before the stack becomes
 	 * active on the new CPU, will order those stores.
 	 */
 	mr	r1,r8		/* start using new stack pointer */
 .endm

 /*
  * This routine switches between two different tasks.  The process
  * state of one is saved on its kernel stack.  Then the state
  * of the other is restored from its kernel stack.  The memory
  * management hardware is updated to the second process's state.
  * Finally, we can return to the second process.
  * On entry, r3 points to the THREAD for the current task, r4
  * points to the THREAD for the new task.
  *
  * This routine is always called with interrupts disabled.
  *
  * Note: there are two ways to get to the "going out" portion
  * of this code; either by coming in via the entry (_switch)
  * or via "fork" which must set up an environment equivalent
  * to the "_switch" path.  If you change this , you'll have to
  * change the fork code also.
  *
  * The code which creates the new task context is in 'copy_thread'
  * in arch/ppc/kernel/process.c
  *
  * Note: this uses SWITCH_FRAME_SIZE rather than USER_INT_FRAME_SIZE
  * because we don't need to leave the redzone ABI gap at the top of
  * the kernel stack.
  */
 _GLOBAL(_switch)
 	PPC_CREATE_STACK_FRAME(SWITCH_FRAME_SIZE)
 	PPC_STL		r1,KSP(r3)	/* Set old stack pointer */
 	SAVE_NVGPRS(r1)			/* volatiles are caller-saved -- Cort */
 	PPC_STL		r0,_NIP(r1)	/* Return to switch caller */
 	mfcr		r0
 	stw		r0,_CCR(r1)

 	/*
 	 * On SMP kernels, care must be taken because a task may be
 	 * scheduled off CPUx and on to CPUy. Memory ordering must be
 	 * considered.
 	 *
 	 * Cacheable stores on CPUx will be visible when the task is
 	 * scheduled on CPUy by virtue of the core scheduler barriers
 	 * (see "Notes on Program-Order guarantees on SMP systems." in
 	 * kernel/sched/core.c).
 	 *
 	 * Uncacheable stores in the case of involuntary preemption must
 	 * be taken care of. The smp_mb__after_spinlock() in __schedule()
 	 * is implemented as hwsync on powerpc, which orders MMIO too. So
 	 * long as there is an hwsync in the context switch path, it will
 	 * be executed on the source CPU after the task has performed
 	 * all MMIO ops on that CPU, and on the destination CPU before the
 	 * task performs any MMIO ops there.
 	 */

 	/*
 	 * The kernel context switch path must contain a spin_lock,
 	 * which contains larx/stcx, which will clear any reservation
 	 * of the task being switched.
 	 */

 #ifdef CONFIG_PPC32
 	do_switch_32
 #else
 	do_switch_64
 #endif

 	lwz	r0,_CCR(r1)
 	mtcrf	0xFF,r0
 	REST_NVGPRS(r1)		/* volatiles are destroyed -- Cort */
 	PPC_LL	r0,_NIP(r1)	/* Return to _switch caller in new task */
 	mtlr	r0
 	addi	r1,r1,SWITCH_FRAME_SIZE
 	blr
	/* SPDX-License-Identifier: GPL-2.0-or-later */
	#include <linux/objtool.h>
	#include <asm/asm-offsets.h>
	#include <asm/code-patching-asm.h>
	#include <asm/mmu.h>
	#include <asm/ppc_asm.h>
	#include <asm/kup.h>
	#include <asm/thread_info.h>

	.section ".text","ax",@progbits

	#ifdef CONFIG_PPC_BOOK3S_64
	/*
	* Cancel all explict user streams as they will have no use after context
	* switch and will stop the HW from creating streams itself
	*/
	#define STOP_STREAMS \
	DCBT_BOOK3S_STOP_ALL_STREAM_IDS(r6)

	#define FLUSH_COUNT_CACHE \
	1: nop; \
	patch_site 1b, patch__call_flush_branch_caches1; \
	1: nop; \
	patch_site 1b, patch__call_flush_branch_caches2; \
	1: nop; \
	patch_site 1b, patch__call_flush_branch_caches3

	.macro nops number
	.rept \number
	nop
	.endr
	.endm

	.balign 32
	.global flush_branch_caches
	flush_branch_caches:
	/* Save LR into r9 */
	mflr r9

	// Flush the link stack
	.rept 64
	ANNOTATE_INTRA_FUNCTION_CALL
	bl .+4
	.endr
	b 1f
	nops 6

	.balign 32
	/* Restore LR */
	1: mtlr r9

	// If we're just flushing the link stack, return here
	3: nop
	patch_site 3b patch__flush_link_stack_return

	li r9,0x7fff
	mtctr r9

	PPC_BCCTR_FLUSH

	2: nop
	patch_site 2b patch__flush_count_cache_return

	nops 3

	.rept 278
	.balign 32
	PPC_BCCTR_FLUSH
	nops 7
	.endr

	blr

	#ifdef CONFIG_PPC_64S_HASH_MMU
	.balign 32
	/*
	* New stack pointer in r8, old stack pointer in r1, must not clobber r3
	*/
	pin_stack_slb:
	BEGIN_FTR_SECTION
	clrrdi r6,r8,28 /* get its ESID */
	clrrdi r9,r1,28 /* get current sp ESID */
	FTR_SECTION_ELSE
	clrrdi r6,r8,40 /* get its 1T ESID */
	clrrdi r9,r1,40 /* get current sp 1T ESID */
	ALT_MMU_FTR_SECTION_END_IFCLR(MMU_FTR_1T_SEGMENT)
	clrldi. r0,r6,2 /* is new ESID c00000000? */
	cmpd cr1,r6,r9 /* or is new ESID the same as current ESID? */
	cror eq,4*cr1+eq,eq
	beq 2f /* if yes, don't slbie it */

	/* Bolt in the new stack SLB entry */
	ld r7,KSP_VSID(r4) /* Get new stack's VSID */
	oris r0,r6,(SLB_ESID_V)@h
	ori r0,r0,(SLB_NUM_BOLTED-1)@l
	BEGIN_FTR_SECTION
	li r9,MMU_SEGSIZE_1T /* insert B field */
	oris r6,r6,(MMU_SEGSIZE_1T << SLBIE_SSIZE_SHIFT)@h
	rldimi r7,r9,SLB_VSID_SSIZE_SHIFT,0
	END_MMU_FTR_SECTION_IFSET(MMU_FTR_1T_SEGMENT)

	/* Update the last bolted SLB. No write barriers are needed
	* here, provided we only update the current CPU's SLB shadow
	* buffer.
	*/
	ld r9,PACA_SLBSHADOWPTR(r13)
	li r12,0
	std r12,SLBSHADOW_STACKESID(r9) /* Clear ESID */
	li r12,SLBSHADOW_STACKVSID
	STDX_BE r7,r12,r9 /* Save VSID */
	li r12,SLBSHADOW_STACKESID
	STDX_BE r0,r12,r9 /* Save ESID */

	/* No need to check for MMU_FTR_NO_SLBIE_B here, since when
	* we have 1TB segments, the only CPUs known to have the errata
	* only support less than 1TB of system memory and we'll never
	* actually hit this code path.
	*/

	isync
	slbie r6
	BEGIN_FTR_SECTION
	slbie r6 /* Workaround POWER5 < DD2.1 issue */
	END_FTR_SECTION_IFCLR(CPU_FTR_ARCH_207S)
	slbmte r7,r0
	isync
	2: blr
	.size pin_stack_slb,.-pin_stack_slb
	#endif /* CONFIG_PPC_64S_HASH_MMU */

	#else
	#define STOP_STREAMS
	#define FLUSH_COUNT_CACHE
	#endif /* CONFIG_PPC_BOOK3S_64 */

	/*
	* do_switch_32/64 have the same calling convention as _switch, i.e., r3,r4
	* are prev and next thread_struct , and returns prev task_struct in r3.

	* This switches the stack, current, and does other task switch housekeeping.
	*/
	.macro do_switch_32
	tophys(r0,r4)
	mtspr SPRN_SPRG_THREAD,r0 /* Update current THREAD phys addr */
	lwz r1,KSP(r4) /* Load new stack pointer */

	/* save the old current 'last' for return value */
	mr r3,r2
	addi r2,r4,-THREAD /* Update current */
	.endm

	.macro do_switch_64
	ld r8,KSP(r4) /* Load new stack pointer */

	kuap_check_amr r9, r10

	FLUSH_COUNT_CACHE /* Clobbers r9, ctr */

	STOP_STREAMS /* Clobbers r6 */

	addi r3,r3,-THREAD /* old thread -> task_struct for return value */
	addi r6,r4,-THREAD /* new thread -> task_struct */
	std r6,PACACURRENT(r13) /* Set new task_struct to 'current' */
	#if defined(CONFIG_STACKPROTECTOR)
	ld r6, TASK_CANARY(r6)
	std r6, PACA_CANARY(r13)
	#endif
	/* Set new PACAKSAVE */
	clrrdi r7,r8,THREAD_SHIFT /* base of new stack */
	addi r7,r7,THREAD_SIZE-SWITCH_FRAME_SIZE
	std r7,PACAKSAVE(r13)

	#ifdef CONFIG_PPC_64S_HASH_MMU
	BEGIN_MMU_FTR_SECTION
	bl pin_stack_slb
	END_MMU_FTR_SECTION_IFCLR(MMU_FTR_TYPE_RADIX)
	#endif
	/*
	* PMU interrupts in radix may come in here. They will use r1, not
	* PACAKSAVE, so this stack switch will not cause a problem. They
	* will store to the process stack, which may then be migrated to
	* another CPU. However the rq lock release on this CPU paired with
	* the rq lock acquire on the new CPU before the stack becomes
	* active on the new CPU, will order those stores.
	*/
	mr r1,r8 /* start using new stack pointer */
	.endm

	/*
	* This routine switches between two different tasks. The process
	* state of one is saved on its kernel stack. Then the state
	* of the other is restored from its kernel stack. The memory
	* management hardware is updated to the second process's state.
	* Finally, we can return to the second process.
	* On entry, r3 points to the THREAD for the current task, r4
	* points to the THREAD for the new task.
	*
	* This routine is always called with interrupts disabled.
	*
	* Note: there are two ways to get to the "going out" portion
	* of this code; either by coming in via the entry (_switch)
	* or via "fork" which must set up an environment equivalent
	* to the "_switch" path. If you change this , you'll have to
	* change the fork code also.
	*
	* The code which creates the new task context is in 'copy_thread'
	* in arch/ppc/kernel/process.c
	*
	* Note: this uses SWITCH_FRAME_SIZE rather than USER_INT_FRAME_SIZE
	* because we don't need to leave the redzone ABI gap at the top of
	* the kernel stack.
	*/
	_GLOBAL(_switch)
	PPC_CREATE_STACK_FRAME(SWITCH_FRAME_SIZE)
	PPC_STL r1,KSP(r3) /* Set old stack pointer */
	SAVE_NVGPRS(r1) /* volatiles are caller-saved -- Cort */
	PPC_STL r0,_NIP(r1) /* Return to switch caller */
	mfcr r0
	stw r0,_CCR(r1)

	/*
	* On SMP kernels, care must be taken because a task may be
	* scheduled off CPUx and on to CPUy. Memory ordering must be
	* considered.
	*
	* Cacheable stores on CPUx will be visible when the task is
	* scheduled on CPUy by virtue of the core scheduler barriers
	* (see "Notes on Program-Order guarantees on SMP systems." in
	* kernel/sched/core.c).
	*
	* Uncacheable stores in the case of involuntary preemption must
	* be taken care of. The smp_mb__after_spinlock() in __schedule()
	* is implemented as hwsync on powerpc, which orders MMIO too. So
	* long as there is an hwsync in the context switch path, it will
	* be executed on the source CPU after the task has performed
	* all MMIO ops on that CPU, and on the destination CPU before the
	* task performs any MMIO ops there.
	*/

	/*
	* The kernel context switch path must contain a spin_lock,
	* which contains larx/stcx, which will clear any reservation
	* of the task being switched.
	*/

	#ifdef CONFIG_PPC32
	do_switch_32
	#else
	do_switch_64
	#endif

	lwz r0,_CCR(r1)
	mtcrf 0xFF,r0
	REST_NVGPRS(r1) /* volatiles are destroyed -- Cort */
	PPC_LL r0,_NIP(r1) /* Return to _switch caller in new task */
	mtlr r0
	addi r1,r1,SWITCH_FRAME_SIZE
	blr