arch/xtensa/kernel/align.S - maze/linux - Git at Google

 /*
  * arch/xtensa/kernel/align.S
  *
  * Handle unalignment exceptions in kernel space.
  *
  * 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) 2001 - 2005 Tensilica, Inc.
  *
  * Rewritten by Chris Zankel <chris@zankel.net>
  *
  * Based on work from Joe Taylor <joe@tensilica.com, joetylr@yahoo.com>
  * and Marc Gauthier <marc@tensilica.com, marc@alimni.uwaterloo.ca>
  */

 #include <linux/linkage.h>
 #include <asm/current.h>
 #include <asm/asm-offsets.h>
 #include <asm/processor.h>

 #if XCHAL_UNALIGNED_LOAD_EXCEPTION || XCHAL_UNALIGNED_STORE_EXCEPTION

 /*  First-level exception handler for unaligned exceptions.
  *
  *  Note: This handler works only for kernel exceptions.  Unaligned user
  *        access should get a seg fault.
  */

 /* Big and little endian 16-bit values are located in
  * different halves of a register.  HWORD_START helps to
  * abstract the notion of extracting a 16-bit value from a
  * register.
  * We also have to define new shifting instructions because
  * lsb and msb are on 'opposite' ends in a register for
  * different endian machines.
  *
  * Assume a memory region in ascending address:
  *   	0 1 2 3|4 5 6 7
  *
  * When loading one word into a register, the content of that register is:
  *  LE	3 2 1 0, 7 6 5 4
  *  BE  0 1 2 3, 4 5 6 7
  *
  * Masking the bits of the higher/lower address means:
  *  LE  X X 0 0, 0 0 X X
  *  BE	0 0 X X, X X 0 0
  *
  * Shifting to higher/lower addresses, means:
  *  LE  shift left / shift right
  *  BE  shift right / shift left
  *
  * Extracting 16 bits from a 32 bit reg. value to higher/lower address means:
  *  LE  mask 0 0 X X / shift left
  *  BE  shift left / mask 0 0 X X
  */

 #define UNALIGNED_USER_EXCEPTION

 #if XCHAL_HAVE_BE

 #define HWORD_START	16
 #define	INSN_OP0	28
 #define	INSN_T		24
 #define	INSN_OP1	16

 .macro __src_b	r, w0, w1;	src	\r, \w0, \w1;	.endm
 .macro __ssa8	r;		ssa8b	\r;		.endm
 .macro __ssa8r	r;		ssa8l	\r;		.endm
 .macro __sh	r, s;		srl	\r, \s;		.endm
 .macro __sl	r, s;		sll	\r, \s;		.endm
 .macro __exth	r, s;		extui	\r, \s, 0, 16;	.endm
 .macro __extl	r, s;		slli	\r, \s, 16;	.endm

 #else

 #define HWORD_START	0
 #define	INSN_OP0	0
 #define	INSN_T		4
 #define	INSN_OP1	12

 .macro __src_b	r, w0, w1;	src	\r, \w1, \w0;	.endm
 .macro __ssa8	r;		ssa8l	\r;		.endm
 .macro __ssa8r	r;		ssa8b	\r;		.endm
 .macro __sh	r, s;		sll	\r, \s;		.endm
 .macro __sl	r, s;		srl	\r, \s;		.endm
 .macro __exth	r, s;		slli	\r, \s, 16;	.endm
 .macro __extl	r, s;		extui	\r, \s, 0, 16;	.endm

 #endif

 /*
  *	xxxx xxxx = imm8 field
  *	     yyyy = imm4 field
  *	     ssss = s field
  *	     tttt = t field
  *
  *	       		 16		    0
  *		          -------------------
  *	L32I.N		  yyyy ssss tttt 1000
  *	S32I.N	          yyyy ssss tttt 1001
  *
  *	       23			    0
  *		-----------------------------
  *	res	          0000           0010
  *	L16UI	xxxx xxxx 0001 ssss tttt 0010
  *	L32I	xxxx xxxx 0010 ssss tttt 0010
  *	XXX	          0011 ssss tttt 0010
  *	XXX	          0100 ssss tttt 0010
  *	S16I	xxxx xxxx 0101 ssss tttt 0010
  *	S32I	xxxx xxxx 0110 ssss tttt 0010
  *	XXX	          0111 ssss tttt 0010
  *	XXX	          1000 ssss tttt 0010
  *	L16SI	xxxx xxxx 1001 ssss tttt 0010
  *	XXX	          1010           0010
  *      **L32AI	xxxx xxxx 1011 ssss tttt 0010 unsupported
  *	XXX	          1100           0010
  *	XXX	          1101           0010
  *	XXX	          1110           0010
  *	**S32RI	xxxx xxxx 1111 ssss tttt 0010 unsupported
  *		-----------------------------
  *                           ^         ^    ^
  *    sub-opcode (NIBBLE_R) -+         |    |
  *       t field (NIBBLE_T) -----------+    |
  *  major opcode (NIBBLE_OP0) --------------+
  */

 #define OP0_L32I_N	0x8		/* load immediate narrow */
 #define OP0_S32I_N	0x9		/* store immediate narrow */
 #define OP1_SI_MASK	0x4		/* OP1 bit set for stores */
 #define OP1_SI_BIT	2		/* OP1 bit number for stores */

 #define OP1_L32I	0x2
 #define OP1_L16UI	0x1
 #define OP1_L16SI	0x9
 #define OP1_L32AI	0xb

 #define OP1_S32I	0x6
 #define OP1_S16I	0x5
 #define OP1_S32RI	0xf

 /*
  * Entry condition:
  *
  *   a0:	trashed, original value saved on stack (PT_AREG0)
  *   a1:	a1
  *   a2:	new stack pointer, original in DEPC
  *   a3:	dispatch table
  *   depc:	a2, original value saved on stack (PT_DEPC)
  *   excsave_1:	a3
  *
  *   PT_DEPC >= VALID_DOUBLE_EXCEPTION_ADDRESS: double exception, DEPC
  *	     <  VALID_DOUBLE_EXCEPTION_ADDRESS: regular exception
  */


 ENTRY(fast_unaligned)

 	/* Note: We don't expect the address to be aligned on a word
 	 *       boundary. After all, the processor generated that exception
 	 *       and it would be a hardware fault.
 	 */

 	/* Save some working register */

 	s32i	a4, a2, PT_AREG4
 	s32i	a5, a2, PT_AREG5
 	s32i	a6, a2, PT_AREG6
 	s32i	a7, a2, PT_AREG7
 	s32i	a8, a2, PT_AREG8

 	rsr	a0, DEPC
 	xsr	a3, EXCSAVE_1
 	s32i	a0, a2, PT_AREG2
 	s32i	a3, a2, PT_AREG3

 	/* Keep value of SAR in a0 */

 	rsr	a0, SAR
 	rsr	a8, EXCVADDR		# load unaligned memory address

 	/* Now, identify one of the following load/store instructions.
 	 *
 	 * The only possible danger of a double exception on the
 	 * following l32i instructions is kernel code in vmalloc
 	 * memory. The processor was just executing at the EPC_1
 	 * address, and indeed, already fetched the instruction.  That
 	 * guarantees a TLB mapping, which hasn't been replaced by
 	 * this unaligned exception handler that uses only static TLB
 	 * mappings. However, high-level interrupt handlers might
 	 * modify TLB entries, so for the generic case, we register a
 	 * TABLE_FIXUP handler here, too.
 	 */

 	/* a3...a6 saved on stack, a2 = SP */

 	/* Extract the instruction that caused the unaligned access. */

 	rsr	a7, EPC_1	# load exception address
 	movi	a3, ~3
 	and	a3, a3, a7	# mask lower bits

 	l32i	a4, a3, 0	# load 2 words
 	l32i	a5, a3, 4

 	__ssa8	a7
 	__src_b	a4, a4, a5	# a4 has the instruction

 	/* Analyze the instruction (load or store?). */

 	extui	a5, a4, INSN_OP0, 4	# get insn.op0 nibble

 #if XCHAL_HAVE_DENSITY
 	_beqi	a5, OP0_L32I_N, .Lload	# L32I.N, jump
 	addi	a6, a5, -OP0_S32I_N
 	_beqz	a6, .Lstore		# S32I.N, do a store
 #endif
 	/* 'store indicator bit' not set, jump */
 	_bbci.l	a4, OP1_SI_BIT + INSN_OP1, .Lload

 	/* Store: Jump to table entry to get the value in the source register.*/

 .Lstore:movi	a5, .Lstore_table	# table
 	extui	a6, a4, INSN_T, 4	# get source register
 	addx8	a5, a6, a5
 	jx	a5			# jump into table

 	/* Invalid instruction, CRITICAL! */
 .Linvalid_instruction_load:
 	j	.Linvalid_instruction

 	/* Load: Load memory address. */

 .Lload: movi	a3, ~3
 	and	a3, a3, a8		# align memory address

 	__ssa8	a8
 #ifdef UNALIGNED_USER_EXCEPTION
 	addi	a3, a3, 8
 	l32e	a5, a3, -8
 	l32e	a6, a3, -4
 #else
 	l32i	a5, a3, 0
 	l32i	a6, a3, 4
 #endif
 	__src_b	a3, a5, a6		# a3 has the data word

 #if XCHAL_HAVE_DENSITY
 	addi	a7, a7, 2		# increment PC (assume 16-bit insn)

 	extui	a5, a4, INSN_OP0, 4
 	_beqi	a5, OP0_L32I_N, 1f	# l32i.n: jump

 	addi	a7, a7, 1
 #else
 	addi	a7, a7, 3
 #endif

 	extui	a5, a4, INSN_OP1, 4
 	_beqi	a5, OP1_L32I, 1f	# l32i: jump

 	extui	a3, a3, 0, 16		# extract lower 16 bits
 	_beqi	a5, OP1_L16UI, 1f
 	addi	a5, a5, -OP1_L16SI
 	_bnez	a5, .Linvalid_instruction_load

 	/* sign extend value */

 	slli	a3, a3, 16
 	srai	a3, a3, 16

 	/* Set target register. */

 1:

 #if XCHAL_HAVE_LOOPS
 	rsr	a5, LEND		# check if we reached LEND
 	bne	a7, a5, 1f
 	rsr	a5, LCOUNT		# and LCOUNT != 0
 	beqz	a5, 1f
 	addi	a5, a5, -1		# decrement LCOUNT and set
 	rsr	a7, LBEG		# set PC to LBEGIN
 	wsr	a5, LCOUNT
 #endif

 1:	wsr	a7, EPC_1		# skip load instruction
 	extui	a4, a4, INSN_T, 4	# extract target register
 	movi	a5, .Lload_table
 	addx8	a4, a4, a5
 	jx	a4			# jump to entry for target register

 	.align	8
 .Lload_table:
 	s32i	a3, a2, PT_AREG0;	_j .Lexit;	.align 8
 	mov	a1, a3;			_j .Lexit;	.align 8 # fishy??
 	s32i	a3, a2, PT_AREG2;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG3;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG4;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG5;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG6;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG7;	_j .Lexit;	.align 8
 	s32i	a3, a2, PT_AREG8;	_j .Lexit;	.align 8
 	mov	a9, a3		;	_j .Lexit;	.align 8
 	mov	a10, a3		;	_j .Lexit;	.align 8
 	mov	a11, a3		;	_j .Lexit;	.align 8
 	mov	a12, a3		;	_j .Lexit;	.align 8
 	mov	a13, a3		;	_j .Lexit;	.align 8
 	mov	a14, a3		;	_j .Lexit;	.align 8
 	mov	a15, a3		;	_j .Lexit;	.align 8

 .Lstore_table:
 	l32i	a3, a2, PT_AREG0;	_j 1f;	.align 8
 	mov	a3, a1;			_j 1f;	.align 8	# fishy??
 	l32i	a3, a2, PT_AREG2;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG3;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG4;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG5;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG6;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG7;	_j 1f;	.align 8
 	l32i	a3, a2, PT_AREG8;	_j 1f;	.align 8
 	mov	a3, a9		;	_j 1f;	.align 8
 	mov	a3, a10		;	_j 1f;	.align 8
 	mov	a3, a11		;	_j 1f;	.align 8
 	mov	a3, a12		;	_j 1f;	.align 8
 	mov	a3, a13		;	_j 1f;	.align 8
 	mov	a3, a14		;	_j 1f;	.align 8
 	mov	a3, a15		;	_j 1f;	.align 8

 1: 	# a7: instruction pointer, a4: instruction, a3: value

 	movi	a6, 0			# mask: ffffffff:00000000

 #if XCHAL_HAVE_DENSITY
 	addi	a7, a7, 2		# incr. PC,assume 16-bit instruction

 	extui	a5, a4, INSN_OP0, 4	# extract OP0
 	addi	a5, a5, -OP0_S32I_N
 	_beqz	a5, 1f			# s32i.n: jump

 	addi	a7, a7, 1		# increment PC, 32-bit instruction
 #else
 	addi	a7, a7, 3		# increment PC, 32-bit instruction
 #endif

 	extui	a5, a4, INSN_OP1, 4	# extract OP1
 	_beqi	a5, OP1_S32I, 1f	# jump if 32 bit store
 	_bnei	a5, OP1_S16I, .Linvalid_instruction_store

 	movi	a5, -1
 	__extl	a3, a3			# get 16-bit value
 	__exth	a6, a5			# get 16-bit mask ffffffff:ffff0000

 	/* Get memory address */

 1:
 #if XCHAL_HAVE_LOOPS
 	rsr	a4, LEND		# check if we reached LEND
 	bne	a7, a4, 1f
 	rsr	a4, LCOUNT		# and LCOUNT != 0
 	beqz	a4, 1f
 	addi	a4, a4, -1		# decrement LCOUNT and set
 	rsr	a7, LBEG		# set PC to LBEGIN
 	wsr	a4, LCOUNT
 #endif

 1:	wsr	a7, EPC_1		# skip store instruction
 	movi	a4, ~3
 	and	a4, a4, a8		# align memory address

 	/* Insert value into memory */

 	movi	a5, -1			# mask: ffffffff:XXXX0000
 #ifdef UNALIGNED_USER_EXCEPTION
 	addi	a4, a4, 8
 #endif

 	__ssa8r a8
 	__src_b	a7, a5, a6		# lo-mask  F..F0..0 (BE) 0..0F..F (LE)
 	__src_b	a6, a6, a5		# hi-mask  0..0F..F (BE) F..F0..0 (LE)
 #ifdef UNALIGNED_USER_EXCEPTION
 	l32e	a5, a4, -8
 #else
 	l32i	a5, a4, 0		# load lower address word
 #endif
 	and	a5, a5, a7		# mask
 	__sh	a7, a3 			# shift value
 	or	a5, a5, a7		# or with original value
 #ifdef UNALIGNED_USER_EXCEPTION
 	s32e	a5, a4, -8
 	l32e	a7, a4, -4
 #else
 	s32i	a5, a4, 0		# store
 	l32i	a7, a4, 4		# same for upper address word
 #endif
 	__sl	a5, a3
 	and	a6, a7, a6
 	or	a6, a6, a5
 #ifdef UNALIGNED_USER_EXCEPTION
 	s32e	a6, a4, -4
 #else
 	s32i	a6, a4, 4
 #endif

 	/* Done. restore stack and return */

 .Lexit:
 	movi	a4, 0
 	rsr	a3, EXCSAVE_1
 	s32i	a4, a3, EXC_TABLE_FIXUP

 	/* Restore working register */

 	l32i	a8, a2, PT_AREG8
 	l32i	a7, a2, PT_AREG7
 	l32i	a6, a2, PT_AREG6
 	l32i	a5, a2, PT_AREG5
 	l32i	a4, a2, PT_AREG4
 	l32i	a3, a2, PT_AREG3

 	/* restore SAR and return */

 	wsr	a0, SAR
 	l32i	a0, a2, PT_AREG0
 	l32i	a2, a2, PT_AREG2
 	rfe

 	/* We cannot handle this exception. */

 	.extern _kernel_exception
 .Linvalid_instruction_store:
 .Linvalid_instruction:

 	/* Restore a4...a8 and SAR, set SP, and jump to default exception. */

 	l32i	a8, a2, PT_AREG8
 	l32i	a7, a2, PT_AREG7
 	l32i	a6, a2, PT_AREG6
 	l32i	a5, a2, PT_AREG5
 	l32i	a4, a2, PT_AREG4
 	wsr	a0, SAR
 	mov	a1, a2

 	rsr	a0, PS
         bbsi.l  a2, PS_UM_BIT, 1f     # jump if user mode

 	movi	a0, _kernel_exception
 	jx	a0

 1:	movi	a0, _user_exception
 	jx	a0


 #endif /* XCHAL_UNALIGNED_LOAD_EXCEPTION || XCHAL_UNALIGNED_STORE_EXCEPTION */
	/*
	* arch/xtensa/kernel/align.S
	*
	* Handle unalignment exceptions in kernel space.
	*
	* 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) 2001 - 2005 Tensilica, Inc.
	*
	* Rewritten by Chris Zankel <chris@zankel.net>
	*
	* Based on work from Joe Taylor <joe@tensilica.com, joetylr@yahoo.com>
	* and Marc Gauthier <marc@tensilica.com, marc@alimni.uwaterloo.ca>
	*/

	#include <linux/linkage.h>
	#include <asm/current.h>
	#include <asm/asm-offsets.h>
	#include <asm/processor.h>

	#if XCHAL_UNALIGNED_LOAD_EXCEPTION \|\| XCHAL_UNALIGNED_STORE_EXCEPTION

	/* First-level exception handler for unaligned exceptions.
	*
	* Note: This handler works only for kernel exceptions. Unaligned user
	* access should get a seg fault.
	*/

	/* Big and little endian 16-bit values are located in
	* different halves of a register. HWORD_START helps to
	* abstract the notion of extracting a 16-bit value from a
	* register.
	* We also have to define new shifting instructions because
	* lsb and msb are on 'opposite' ends in a register for
	* different endian machines.
	*
	* Assume a memory region in ascending address:
	* 0 1 2 3\|4 5 6 7
	*
	* When loading one word into a register, the content of that register is:
	* LE 3 2 1 0, 7 6 5 4
	* BE 0 1 2 3, 4 5 6 7
	*
	* Masking the bits of the higher/lower address means:
	* LE X X 0 0, 0 0 X X
	* BE 0 0 X X, X X 0 0
	*
	* Shifting to higher/lower addresses, means:
	* LE shift left / shift right
	* BE shift right / shift left
	*
	* Extracting 16 bits from a 32 bit reg. value to higher/lower address means:
	* LE mask 0 0 X X / shift left
	* BE shift left / mask 0 0 X X
	*/

	#define UNALIGNED_USER_EXCEPTION

	#if XCHAL_HAVE_BE

	#define HWORD_START 16
	#define INSN_OP0 28
	#define INSN_T 24
	#define INSN_OP1 16

	.macro __src_b r, w0, w1; src \r, \w0, \w1; .endm
	.macro __ssa8 r; ssa8b \r; .endm
	.macro __ssa8r r; ssa8l \r; .endm
	.macro __sh r, s; srl \r, \s; .endm
	.macro __sl r, s; sll \r, \s; .endm
	.macro __exth r, s; extui \r, \s, 0, 16; .endm
	.macro __extl r, s; slli \r, \s, 16; .endm

	#else

	#define HWORD_START 0
	#define INSN_OP0 0
	#define INSN_T 4
	#define INSN_OP1 12

	.macro __src_b r, w0, w1; src \r, \w1, \w0; .endm
	.macro __ssa8 r; ssa8l \r; .endm
	.macro __ssa8r r; ssa8b \r; .endm
	.macro __sh r, s; sll \r, \s; .endm
	.macro __sl r, s; srl \r, \s; .endm
	.macro __exth r, s; slli \r, \s, 16; .endm
	.macro __extl r, s; extui \r, \s, 0, 16; .endm

	#endif

	/*
	* xxxx xxxx = imm8 field
	* yyyy = imm4 field
	* ssss = s field
	* tttt = t field
	*
	* 16 0
	* -------------------
	* L32I.N yyyy ssss tttt 1000
	* S32I.N yyyy ssss tttt 1001
	*
	* 23 0
	* -----------------------------
	* res 0000 0010
	* L16UI xxxx xxxx 0001 ssss tttt 0010
	* L32I xxxx xxxx 0010 ssss tttt 0010
	* XXX 0011 ssss tttt 0010
	* XXX 0100 ssss tttt 0010
	* S16I xxxx xxxx 0101 ssss tttt 0010
	* S32I xxxx xxxx 0110 ssss tttt 0010
	* XXX 0111 ssss tttt 0010
	* XXX 1000 ssss tttt 0010
	* L16SI xxxx xxxx 1001 ssss tttt 0010
	* XXX 1010 0010
	* **L32AI xxxx xxxx 1011 ssss tttt 0010 unsupported
	* XXX 1100 0010
	* XXX 1101 0010
	* XXX 1110 0010
	* **S32RI xxxx xxxx 1111 ssss tttt 0010 unsupported
	* -----------------------------
	* ^ ^ ^
	* sub-opcode (NIBBLE_R) -+ \| \|
	* t field (NIBBLE_T) -----------+ \|
	* major opcode (NIBBLE_OP0) --------------+
	*/

	#define OP0_L32I_N 0x8 /* load immediate narrow */
	#define OP0_S32I_N 0x9 /* store immediate narrow */
	#define OP1_SI_MASK 0x4 /* OP1 bit set for stores */
	#define OP1_SI_BIT 2 /* OP1 bit number for stores */

	#define OP1_L32I 0x2
	#define OP1_L16UI 0x1
	#define OP1_L16SI 0x9
	#define OP1_L32AI 0xb

	#define OP1_S32I 0x6
	#define OP1_S16I 0x5
	#define OP1_S32RI 0xf

	/*
	* Entry condition:
	*
	* a0: trashed, original value saved on stack (PT_AREG0)
	* a1: a1
	* a2: new stack pointer, original in DEPC
	* a3: dispatch table
	* depc: a2, original value saved on stack (PT_DEPC)
	* excsave_1: a3
	*
	* PT_DEPC >= VALID_DOUBLE_EXCEPTION_ADDRESS: double exception, DEPC
	* < VALID_DOUBLE_EXCEPTION_ADDRESS: regular exception
	*/


	ENTRY(fast_unaligned)

	/* Note: We don't expect the address to be aligned on a word
	* boundary. After all, the processor generated that exception
	* and it would be a hardware fault.
	*/

	/* Save some working register */

	s32i a4, a2, PT_AREG4
	s32i a5, a2, PT_AREG5
	s32i a6, a2, PT_AREG6
	s32i a7, a2, PT_AREG7
	s32i a8, a2, PT_AREG8

	rsr a0, DEPC
	xsr a3, EXCSAVE_1
	s32i a0, a2, PT_AREG2
	s32i a3, a2, PT_AREG3

	/* Keep value of SAR in a0 */

	rsr a0, SAR
	rsr a8, EXCVADDR # load unaligned memory address

	/* Now, identify one of the following load/store instructions.
	*
	* The only possible danger of a double exception on the
	* following l32i instructions is kernel code in vmalloc
	* memory. The processor was just executing at the EPC_1
	* address, and indeed, already fetched the instruction. That
	* guarantees a TLB mapping, which hasn't been replaced by
	* this unaligned exception handler that uses only static TLB
	* mappings. However, high-level interrupt handlers might
	* modify TLB entries, so for the generic case, we register a
	* TABLE_FIXUP handler here, too.
	*/

	/* a3...a6 saved on stack, a2 = SP */

	/* Extract the instruction that caused the unaligned access. */

	rsr a7, EPC_1 # load exception address
	movi a3, ~3
	and a3, a3, a7 # mask lower bits

	l32i a4, a3, 0 # load 2 words
	l32i a5, a3, 4

	__ssa8 a7
	__src_b a4, a4, a5 # a4 has the instruction

	/* Analyze the instruction (load or store?). */

	extui a5, a4, INSN_OP0, 4 # get insn.op0 nibble

	#if XCHAL_HAVE_DENSITY
	_beqi a5, OP0_L32I_N, .Lload # L32I.N, jump
	addi a6, a5, -OP0_S32I_N
	_beqz a6, .Lstore # S32I.N, do a store
	#endif
	/* 'store indicator bit' not set, jump */
	_bbci.l a4, OP1_SI_BIT + INSN_OP1, .Lload

	/* Store: Jump to table entry to get the value in the source register.*/

	.Lstore:movi a5, .Lstore_table # table
	extui a6, a4, INSN_T, 4 # get source register
	addx8 a5, a6, a5
	jx a5 # jump into table

	/* Invalid instruction, CRITICAL! */
	.Linvalid_instruction_load:
	j .Linvalid_instruction

	/* Load: Load memory address. */

	.Lload: movi a3, ~3
	and a3, a3, a8 # align memory address

	__ssa8 a8
	#ifdef UNALIGNED_USER_EXCEPTION
	addi a3, a3, 8
	l32e a5, a3, -8
	l32e a6, a3, -4
	#else
	l32i a5, a3, 0
	l32i a6, a3, 4
	#endif
	__src_b a3, a5, a6 # a3 has the data word

	#if XCHAL_HAVE_DENSITY
	addi a7, a7, 2 # increment PC (assume 16-bit insn)

	extui a5, a4, INSN_OP0, 4
	_beqi a5, OP0_L32I_N, 1f # l32i.n: jump

	addi a7, a7, 1
	#else
	addi a7, a7, 3
	#endif

	extui a5, a4, INSN_OP1, 4
	_beqi a5, OP1_L32I, 1f # l32i: jump

	extui a3, a3, 0, 16 # extract lower 16 bits
	_beqi a5, OP1_L16UI, 1f
	addi a5, a5, -OP1_L16SI
	_bnez a5, .Linvalid_instruction_load

	/* sign extend value */

	slli a3, a3, 16
	srai a3, a3, 16

	/* Set target register. */

	1:

	#if XCHAL_HAVE_LOOPS
	rsr a5, LEND # check if we reached LEND
	bne a7, a5, 1f
	rsr a5, LCOUNT # and LCOUNT != 0
	beqz a5, 1f
	addi a5, a5, -1 # decrement LCOUNT and set
	rsr a7, LBEG # set PC to LBEGIN
	wsr a5, LCOUNT
	#endif

	1: wsr a7, EPC_1 # skip load instruction
	extui a4, a4, INSN_T, 4 # extract target register
	movi a5, .Lload_table
	addx8 a4, a4, a5
	jx a4 # jump to entry for target register

	.align 8
	.Lload_table:
	s32i a3, a2, PT_AREG0; _j .Lexit; .align 8
	mov a1, a3; _j .Lexit; .align 8 # fishy??
	s32i a3, a2, PT_AREG2; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG3; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG4; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG5; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG6; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG7; _j .Lexit; .align 8
	s32i a3, a2, PT_AREG8; _j .Lexit; .align 8
	mov a9, a3 ; _j .Lexit; .align 8
	mov a10, a3 ; _j .Lexit; .align 8
	mov a11, a3 ; _j .Lexit; .align 8
	mov a12, a3 ; _j .Lexit; .align 8
	mov a13, a3 ; _j .Lexit; .align 8
	mov a14, a3 ; _j .Lexit; .align 8
	mov a15, a3 ; _j .Lexit; .align 8

	.Lstore_table:
	l32i a3, a2, PT_AREG0; _j 1f; .align 8
	mov a3, a1; _j 1f; .align 8 # fishy??
	l32i a3, a2, PT_AREG2; _j 1f; .align 8
	l32i a3, a2, PT_AREG3; _j 1f; .align 8
	l32i a3, a2, PT_AREG4; _j 1f; .align 8
	l32i a3, a2, PT_AREG5; _j 1f; .align 8
	l32i a3, a2, PT_AREG6; _j 1f; .align 8
	l32i a3, a2, PT_AREG7; _j 1f; .align 8
	l32i a3, a2, PT_AREG8; _j 1f; .align 8
	mov a3, a9 ; _j 1f; .align 8
	mov a3, a10 ; _j 1f; .align 8
	mov a3, a11 ; _j 1f; .align 8
	mov a3, a12 ; _j 1f; .align 8
	mov a3, a13 ; _j 1f; .align 8
	mov a3, a14 ; _j 1f; .align 8
	mov a3, a15 ; _j 1f; .align 8

	1: # a7: instruction pointer, a4: instruction, a3: value

	movi a6, 0 # mask: ffffffff:00000000

	#if XCHAL_HAVE_DENSITY
	addi a7, a7, 2 # incr. PC,assume 16-bit instruction

	extui a5, a4, INSN_OP0, 4 # extract OP0
	addi a5, a5, -OP0_S32I_N
	_beqz a5, 1f # s32i.n: jump

	addi a7, a7, 1 # increment PC, 32-bit instruction
	#else
	addi a7, a7, 3 # increment PC, 32-bit instruction
	#endif

	extui a5, a4, INSN_OP1, 4 # extract OP1
	_beqi a5, OP1_S32I, 1f # jump if 32 bit store
	_bnei a5, OP1_S16I, .Linvalid_instruction_store

	movi a5, -1
	__extl a3, a3 # get 16-bit value
	__exth a6, a5 # get 16-bit mask ffffffff:ffff0000

	/* Get memory address */

	1:
	#if XCHAL_HAVE_LOOPS
	rsr a4, LEND # check if we reached LEND
	bne a7, a4, 1f
	rsr a4, LCOUNT # and LCOUNT != 0
	beqz a4, 1f
	addi a4, a4, -1 # decrement LCOUNT and set
	rsr a7, LBEG # set PC to LBEGIN
	wsr a4, LCOUNT
	#endif

	1: wsr a7, EPC_1 # skip store instruction
	movi a4, ~3
	and a4, a4, a8 # align memory address

	/* Insert value into memory */

	movi a5, -1 # mask: ffffffff:XXXX0000
	#ifdef UNALIGNED_USER_EXCEPTION
	addi a4, a4, 8
	#endif

	__ssa8r a8
	__src_b a7, a5, a6 # lo-mask F..F0..0 (BE) 0..0F..F (LE)
	__src_b a6, a6, a5 # hi-mask 0..0F..F (BE) F..F0..0 (LE)
	#ifdef UNALIGNED_USER_EXCEPTION
	l32e a5, a4, -8
	#else
	l32i a5, a4, 0 # load lower address word
	#endif
	and a5, a5, a7 # mask
	__sh a7, a3 # shift value
	or a5, a5, a7 # or with original value
	#ifdef UNALIGNED_USER_EXCEPTION
	s32e a5, a4, -8
	l32e a7, a4, -4
	#else
	s32i a5, a4, 0 # store
	l32i a7, a4, 4 # same for upper address word
	#endif
	__sl a5, a3
	and a6, a7, a6
	or a6, a6, a5
	#ifdef UNALIGNED_USER_EXCEPTION
	s32e a6, a4, -4
	#else
	s32i a6, a4, 4
	#endif

	/* Done. restore stack and return */

	.Lexit:
	movi a4, 0
	rsr a3, EXCSAVE_1
	s32i a4, a3, EXC_TABLE_FIXUP

	/* Restore working register */

	l32i a8, a2, PT_AREG8
	l32i a7, a2, PT_AREG7
	l32i a6, a2, PT_AREG6
	l32i a5, a2, PT_AREG5
	l32i a4, a2, PT_AREG4
	l32i a3, a2, PT_AREG3

	/* restore SAR and return */

	wsr a0, SAR
	l32i a0, a2, PT_AREG0
	l32i a2, a2, PT_AREG2
	rfe

	/* We cannot handle this exception. */

	.extern _kernel_exception
	.Linvalid_instruction_store:
	.Linvalid_instruction:

	/* Restore a4...a8 and SAR, set SP, and jump to default exception. */

	l32i a8, a2, PT_AREG8
	l32i a7, a2, PT_AREG7
	l32i a6, a2, PT_AREG6
	l32i a5, a2, PT_AREG5
	l32i a4, a2, PT_AREG4
	wsr a0, SAR
	mov a1, a2

	rsr a0, PS
	bbsi.l a2, PS_UM_BIT, 1f # jump if user mode

	movi a0, _kernel_exception
	jx a0

	1: movi a0, _user_exception
	jx a0


	#endif /* XCHAL_UNALIGNED_LOAD_EXCEPTION \|\| XCHAL_UNALIGNED_STORE_EXCEPTION */