include/asm-ia64/mca_asm.h - kernel/msm-4.9 - Gitiles

 /*
  * File:	mca_asm.h
  * Purpose:	Machine check handling specific defines
  *
  * Copyright (C) 1999 Silicon Graphics, Inc.
  * Copyright (C) Vijay Chander <vijay@engr.sgi.com>
  * Copyright (C) Srinivasa Thirumalachar <sprasad@engr.sgi.com>
  * Copyright (C) 2000 Hewlett-Packard Co.
  * Copyright (C) 2000 David Mosberger-Tang <davidm@hpl.hp.com>
  * Copyright (C) 2002 Intel Corp.
  * Copyright (C) 2002 Jenna Hall <jenna.s.hall@intel.com>
  * Copyright (C) 2005 Silicon Graphics, Inc
  * Copyright (C) 2005 Keith Owens <kaos@sgi.com>
  */
 #ifndef _ASM_IA64_MCA_ASM_H
 #define _ASM_IA64_MCA_ASM_H

 #define PSR_IC		13
 #define PSR_I		14
 #define	PSR_DT		17
 #define PSR_RT		27
 #define PSR_MC		35
 #define PSR_IT		36
 #define PSR_BN		44

 /*
  * This macro converts a instruction virtual address to a physical address
  * Right now for simulation purposes the virtual addresses are
  * direct mapped to physical addresses.
  *	1. Lop off bits 61 thru 63 in the virtual address
  */
 #define INST_VA_TO_PA(addr)							\
 	dep	addr	= 0, addr, 61, 3
 /*
  * This macro converts a data virtual address to a physical address
  * Right now for simulation purposes the virtual addresses are
  * direct mapped to physical addresses.
  *	1. Lop off bits 61 thru 63 in the virtual address
  */
 #define DATA_VA_TO_PA(addr)							\
 	tpa	addr	= addr
 /*
  * This macro converts a data physical address to a virtual address
  * Right now for simulation purposes the virtual addresses are
  * direct mapped to physical addresses.
  *	1. Put 0x7 in bits 61 thru 63.
  */
 #define DATA_PA_TO_VA(addr,temp)							\
 	mov	temp	= 0x7	;;							\
 	dep	addr	= temp, addr, 61, 3

 #define GET_THIS_PADDR(reg, var)		\
 	mov	reg = IA64_KR(PER_CPU_DATA);;	\
         addl	reg = THIS_CPU(var), reg

 /*
  * This macro jumps to the instruction at the given virtual address
  * and starts execution in physical mode with all the address
  * translations turned off.
  *	1.	Save the current psr
  *	2.	Make sure that all the upper 32 bits are off
  *
  *	3.	Clear the interrupt enable and interrupt state collection bits
  *		in the psr before updating the ipsr and iip.
  *
  *	4.	Turn off the instruction, data and rse translation bits of the psr
  *		and store the new value into ipsr
  *		Also make sure that the interrupts are disabled.
  *		Ensure that we are in little endian mode.
  *		[psr.{rt, it, dt, i, be} = 0]
  *
  *	5.	Get the physical address corresponding to the virtual address
  *		of the next instruction bundle and put it in iip.
  *		(Using magic numbers 24 and 40 in the deposint instruction since
  *		 the IA64_SDK code directly maps to lower 24bits as physical address
  *		 from a virtual address).
  *
  *	6.	Do an rfi to move the values from ipsr to psr and iip to ip.
  */
 #define  PHYSICAL_MODE_ENTER(temp1, temp2, start_addr, old_psr)				\
 	mov	old_psr = psr;								\
 	;;										\
 	dep	old_psr = 0, old_psr, 32, 32;						\
 											\
 	mov	ar.rsc = 0 ;								\
 	;;										\
 	srlz.d;										\
 	mov	temp2 = ar.bspstore;							\
 	;;										\
 	DATA_VA_TO_PA(temp2);								\
 	;;										\
 	mov	temp1 = ar.rnat;							\
 	;;										\
 	mov	ar.bspstore = temp2;							\
 	;;										\
 	mov	ar.rnat = temp1;							\
 	mov	temp1 = psr;								\
 	mov	temp2 = psr;								\
 	;;										\
 											\
 	dep	temp2 = 0, temp2, PSR_IC, 2;						\
 	;;										\
 	mov	psr.l = temp2;								\
 	;;										\
 	srlz.d;										\
 	dep	temp1 = 0, temp1, 32, 32;						\
 	;;										\
 	dep	temp1 = 0, temp1, PSR_IT, 1;						\
 	;;										\
 	dep	temp1 = 0, temp1, PSR_DT, 1;						\
 	;;										\
 	dep	temp1 = 0, temp1, PSR_RT, 1;						\
 	;;										\
 	dep	temp1 = 0, temp1, PSR_I, 1;						\
 	;;										\
 	dep	temp1 = 0, temp1, PSR_IC, 1;						\
 	;;										\
 	dep	temp1 = -1, temp1, PSR_MC, 1;						\
 	;;										\
 	mov	cr.ipsr = temp1;							\
 	;;										\
 	LOAD_PHYSICAL(p0, temp2, start_addr);						\
 	;;										\
 	mov	cr.iip = temp2;								\
 	mov	cr.ifs = r0;								\
 	DATA_VA_TO_PA(sp);								\
 	DATA_VA_TO_PA(gp);								\
 	;;										\
 	srlz.i;										\
 	;;										\
 	nop	1;									\
 	nop	2;									\
 	nop	1;									\
 	nop	2;									\
 	rfi;										\
 	;;

 /*
  * This macro jumps to the instruction at the given virtual address
  * and starts execution in virtual mode with all the address
  * translations turned on.
  *	1.	Get the old saved psr
  *
  *	2.	Clear the interrupt state collection bit in the current psr.
  *
  *	3.	Set the instruction translation bit back in the old psr
  *		Note we have to do this since we are right now saving only the
  *		lower 32-bits of old psr.(Also the old psr has the data and
  *		rse translation bits on)
  *
  *	4.	Set ipsr to this old_psr with "it" bit set and "bn" = 1.
  *
  *	5.	Reset the current thread pointer (r13).
  *
  *	6.	Set iip to the virtual address of the next instruction bundle.
  *
  *	7.	Do an rfi to move ipsr to psr and iip to ip.
  */

 #define VIRTUAL_MODE_ENTER(temp1, temp2, start_addr, old_psr)	\
 	mov	temp2 = psr;					\
 	;;							\
 	mov	old_psr = temp2;				\
 	;;							\
 	dep	temp2 = 0, temp2, PSR_IC, 2;			\
 	;;							\
 	mov	psr.l = temp2;					\
 	mov	ar.rsc = 0;					\
 	;;							\
 	srlz.d;							\
 	mov	r13 = ar.k6;					\
 	mov	temp2 = ar.bspstore;				\
 	;;							\
 	DATA_PA_TO_VA(temp2,temp1);				\
 	;;							\
 	mov	temp1 = ar.rnat;				\
 	;;							\
 	mov	ar.bspstore = temp2;				\
 	;;							\
 	mov	ar.rnat = temp1;				\
 	;;							\
 	mov	temp1 = old_psr;				\
 	;;							\
 	mov	temp2 = 1;					\
 	;;							\
 	dep	temp1 = temp2, temp1, PSR_IC, 1;		\
 	;;							\
 	dep	temp1 = temp2, temp1, PSR_IT, 1;		\
 	;;							\
 	dep	temp1 = temp2, temp1, PSR_DT, 1;		\
 	;;							\
 	dep	temp1 = temp2, temp1, PSR_RT, 1;		\
 	;;							\
 	dep	temp1 = temp2, temp1, PSR_BN, 1;		\
 	;;							\
 								\
 	mov     cr.ipsr = temp1;				\
 	movl	temp2 = start_addr;				\
 	;;							\
 	mov	cr.iip = temp2;					\
 	movl	gp = __gp					\
 	;;							\
 	DATA_PA_TO_VA(sp, temp1);				\
 	srlz.i;							\
 	;;							\
 	nop	1;						\
 	nop	2;						\
 	nop	1;						\
 	rfi							\
 	;;

 /*
  * The MCA and INIT stacks in struct ia64_mca_cpu look like normal kernel
  * stacks, except that the SAL/OS state and a switch_stack are stored near the
  * top of the MCA/INIT stack.  To support concurrent entry to MCA or INIT, as
  * well as MCA over INIT, each event needs its own SAL/OS state.  All entries
  * are 16 byte aligned.
  *
  *      +---------------------------+
  *      |          pt_regs          |
  *      +---------------------------+
  *      |        switch_stack       |
  *      +---------------------------+
  *      |        SAL/OS state       |
  *      +---------------------------+
  *      |    16 byte scratch area   |
  *      +---------------------------+ <-------- SP at start of C MCA handler
  *      |           .....           |
  *      +---------------------------+
  *      | RBS for MCA/INIT handler  |
  *      +---------------------------+
  *      | struct task for MCA/INIT  |
  *      +---------------------------+ <-------- Bottom of MCA/INIT stack
  */

 #define ALIGN16(x)			((x)&~15)
 #define MCA_PT_REGS_OFFSET		ALIGN16(KERNEL_STACK_SIZE-IA64_PT_REGS_SIZE)
 #define MCA_SWITCH_STACK_OFFSET		ALIGN16(MCA_PT_REGS_OFFSET-IA64_SWITCH_STACK_SIZE)
 #define MCA_SOS_OFFSET			ALIGN16(MCA_SWITCH_STACK_OFFSET-IA64_SAL_OS_STATE_SIZE)
 #define MCA_SP_OFFSET			ALIGN16(MCA_SOS_OFFSET-16)

 #endif /* _ASM_IA64_MCA_ASM_H */
	/*
	* File: mca_asm.h
	* Purpose: Machine check handling specific defines
	*
	* Copyright (C) 1999 Silicon Graphics, Inc.
	* Copyright (C) Vijay Chander <vijay@engr.sgi.com>
	* Copyright (C) Srinivasa Thirumalachar <sprasad@engr.sgi.com>
	* Copyright (C) 2000 Hewlett-Packard Co.
	* Copyright (C) 2000 David Mosberger-Tang <davidm@hpl.hp.com>
	* Copyright (C) 2002 Intel Corp.
	* Copyright (C) 2002 Jenna Hall <jenna.s.hall@intel.com>
	* Copyright (C) 2005 Silicon Graphics, Inc
	* Copyright (C) 2005 Keith Owens <kaos@sgi.com>
	*/
	#ifndef _ASM_IA64_MCA_ASM_H
	#define _ASM_IA64_MCA_ASM_H

	#define PSR_IC 13
	#define PSR_I 14
	#define PSR_DT 17
	#define PSR_RT 27
	#define PSR_MC 35
	#define PSR_IT 36
	#define PSR_BN 44

	/*
	* This macro converts a instruction virtual address to a physical address
	* Right now for simulation purposes the virtual addresses are
	* direct mapped to physical addresses.
	* 1. Lop off bits 61 thru 63 in the virtual address
	*/
	#define INST_VA_TO_PA(addr) \
	dep addr = 0, addr, 61, 3
	/*
	* This macro converts a data virtual address to a physical address
	* Right now for simulation purposes the virtual addresses are
	* direct mapped to physical addresses.
	* 1. Lop off bits 61 thru 63 in the virtual address
	*/
	#define DATA_VA_TO_PA(addr) \
	tpa addr = addr
	/*
	* This macro converts a data physical address to a virtual address
	* Right now for simulation purposes the virtual addresses are
	* direct mapped to physical addresses.
	* 1. Put 0x7 in bits 61 thru 63.
	*/
	#define DATA_PA_TO_VA(addr,temp) \
	mov temp = 0x7 ;; \
	dep addr = temp, addr, 61, 3

	#define GET_THIS_PADDR(reg, var) \
	mov reg = IA64_KR(PER_CPU_DATA);; \
	addl reg = THIS_CPU(var), reg

	/*
	* This macro jumps to the instruction at the given virtual address
	* and starts execution in physical mode with all the address
	* translations turned off.
	* 1. Save the current psr
	* 2. Make sure that all the upper 32 bits are off
	*
	* 3. Clear the interrupt enable and interrupt state collection bits
	* in the psr before updating the ipsr and iip.
	*
	* 4. Turn off the instruction, data and rse translation bits of the psr
	* and store the new value into ipsr
	* Also make sure that the interrupts are disabled.
	* Ensure that we are in little endian mode.
	* [psr.{rt, it, dt, i, be} = 0]
	*
	* 5. Get the physical address corresponding to the virtual address
	* of the next instruction bundle and put it in iip.
	* (Using magic numbers 24 and 40 in the deposint instruction since
	* the IA64_SDK code directly maps to lower 24bits as physical address
	* from a virtual address).
	*
	* 6. Do an rfi to move the values from ipsr to psr and iip to ip.
	*/
	#define PHYSICAL_MODE_ENTER(temp1, temp2, start_addr, old_psr) \
	mov old_psr = psr; \
	;; \
	dep old_psr = 0, old_psr, 32, 32; \
	\
	mov ar.rsc = 0 ; \
	;; \
	srlz.d; \
	mov temp2 = ar.bspstore; \
	;; \
	DATA_VA_TO_PA(temp2); \
	;; \
	mov temp1 = ar.rnat; \
	;; \
	mov ar.bspstore = temp2; \
	;; \
	mov ar.rnat = temp1; \
	mov temp1 = psr; \
	mov temp2 = psr; \
	;; \
	\
	dep temp2 = 0, temp2, PSR_IC, 2; \
	;; \
	mov psr.l = temp2; \
	;; \
	srlz.d; \
	dep temp1 = 0, temp1, 32, 32; \
	;; \
	dep temp1 = 0, temp1, PSR_IT, 1; \
	;; \
	dep temp1 = 0, temp1, PSR_DT, 1; \
	;; \
	dep temp1 = 0, temp1, PSR_RT, 1; \
	;; \
	dep temp1 = 0, temp1, PSR_I, 1; \
	;; \
	dep temp1 = 0, temp1, PSR_IC, 1; \
	;; \
	dep temp1 = -1, temp1, PSR_MC, 1; \
	;; \
	mov cr.ipsr = temp1; \
	;; \
	LOAD_PHYSICAL(p0, temp2, start_addr); \
	;; \
	mov cr.iip = temp2; \
	mov cr.ifs = r0; \
	DATA_VA_TO_PA(sp); \
	DATA_VA_TO_PA(gp); \
	;; \
	srlz.i; \
	;; \
	nop 1; \
	nop 2; \
	nop 1; \
	nop 2; \
	rfi; \
	;;

	/*
	* This macro jumps to the instruction at the given virtual address
	* and starts execution in virtual mode with all the address
	* translations turned on.
	* 1. Get the old saved psr
	*
	* 2. Clear the interrupt state collection bit in the current psr.
	*
	* 3. Set the instruction translation bit back in the old psr
	* Note we have to do this since we are right now saving only the
	* lower 32-bits of old psr.(Also the old psr has the data and
	* rse translation bits on)
	*
	* 4. Set ipsr to this old_psr with "it" bit set and "bn" = 1.
	*
	* 5. Reset the current thread pointer (r13).
	*
	* 6. Set iip to the virtual address of the next instruction bundle.
	*
	* 7. Do an rfi to move ipsr to psr and iip to ip.
	*/

	#define VIRTUAL_MODE_ENTER(temp1, temp2, start_addr, old_psr) \
	mov temp2 = psr; \
	;; \
	mov old_psr = temp2; \
	;; \
	dep temp2 = 0, temp2, PSR_IC, 2; \
	;; \
	mov psr.l = temp2; \
	mov ar.rsc = 0; \
	;; \
	srlz.d; \
	mov r13 = ar.k6; \
	mov temp2 = ar.bspstore; \
	;; \
	DATA_PA_TO_VA(temp2,temp1); \
	;; \
	mov temp1 = ar.rnat; \
	;; \
	mov ar.bspstore = temp2; \
	;; \
	mov ar.rnat = temp1; \
	;; \
	mov temp1 = old_psr; \
	;; \
	mov temp2 = 1; \
	;; \
	dep temp1 = temp2, temp1, PSR_IC, 1; \
	;; \
	dep temp1 = temp2, temp1, PSR_IT, 1; \
	;; \
	dep temp1 = temp2, temp1, PSR_DT, 1; \
	;; \
	dep temp1 = temp2, temp1, PSR_RT, 1; \
	;; \
	dep temp1 = temp2, temp1, PSR_BN, 1; \
	;; \
	\
	mov cr.ipsr = temp1; \
	movl temp2 = start_addr; \
	;; \
	mov cr.iip = temp2; \
	movl gp = __gp \
	;; \
	DATA_PA_TO_VA(sp, temp1); \
	srlz.i; \
	;; \
	nop 1; \
	nop 2; \
	nop 1; \
	rfi \
	;;

	/*
	* The MCA and INIT stacks in struct ia64_mca_cpu look like normal kernel
	* stacks, except that the SAL/OS state and a switch_stack are stored near the
	* top of the MCA/INIT stack. To support concurrent entry to MCA or INIT, as
	* well as MCA over INIT, each event needs its own SAL/OS state. All entries
	* are 16 byte aligned.
	*
	* +---------------------------+
	* \| pt_regs \|
	* +---------------------------+
	* \| switch_stack \|
	* +---------------------------+
	* \| SAL/OS state \|
	* +---------------------------+
	* \| 16 byte scratch area \|
	* +---------------------------+ <-------- SP at start of C MCA handler
	* \| ..... \|
	* +---------------------------+
	* \| RBS for MCA/INIT handler \|
	* +---------------------------+
	* \| struct task for MCA/INIT \|
	* +---------------------------+ <-------- Bottom of MCA/INIT stack
	*/

	#define ALIGN16(x) ((x)&~15)
	#define MCA_PT_REGS_OFFSET ALIGN16(KERNEL_STACK_SIZE-IA64_PT_REGS_SIZE)
	#define MCA_SWITCH_STACK_OFFSET ALIGN16(MCA_PT_REGS_OFFSET-IA64_SWITCH_STACK_SIZE)
	#define MCA_SOS_OFFSET ALIGN16(MCA_SWITCH_STACK_OFFSET-IA64_SAL_OS_STATE_SIZE)
	#define MCA_SP_OFFSET ALIGN16(MCA_SOS_OFFSET-16)

	#endif /* _ASM_IA64_MCA_ASM_H */