arch/arm/kernel/phys2virt.S - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  *  Copyright (C) 1994-2002 Russell King
  *  Copyright (c) 2003, 2020 ARM Limited
  *  All Rights Reserved
  */

 #include <linux/init.h>
 #include <linux/linkage.h>
 #include <asm/assembler.h>
 #include <asm/page.h>

 #ifdef __ARMEB__
 #define LOW_OFFSET	0x4
 #define HIGH_OFFSET	0x0
 #else
 #define LOW_OFFSET	0x0
 #define HIGH_OFFSET	0x4
 #endif

 /*
  * __fixup_pv_table - patch the stub instructions with the delta between
  *                    PHYS_OFFSET and PAGE_OFFSET, which is assumed to be
  *                    2 MiB aligned.
  *
  * Called from head.S, which expects the following registers to be preserved:
  *   r1 = machine no, r2 = atags or dtb,
  *   r8 = phys_offset, r9 = cpuid, r10 = procinfo
  */
 	__HEAD
 ENTRY(__fixup_pv_table)
 	mov	r0, r8, lsr #PAGE_SHIFT	@ convert to PFN
 	str_l	r0, __pv_phys_pfn_offset, r3

 	adr_l	r0, __pv_offset
 	subs	r3, r8, #PAGE_OFFSET	@ PHYS_OFFSET - PAGE_OFFSET
 	mvn	ip, #0
 	strcc	ip, [r0, #HIGH_OFFSET]	@ save to __pv_offset high bits
 	str	r3, [r0, #LOW_OFFSET]	@ save to __pv_offset low bits

 	mov	r0, r3, lsr #21		@ constant for add/sub instructions
 	teq	r3, r0, lsl #21 	@ must be 2 MiB aligned
 	bne	0f

 	adr_l	r4, __pv_table_begin
 	adr_l	r5, __pv_table_end
 	b	__fixup_a_pv_table

 0:	mov	r0, r0			@ deadloop on error
 	b	0b
 ENDPROC(__fixup_pv_table)

 	.text
 __fixup_a_pv_table:
 	adr_l	r6, __pv_offset
 	ldr	r0, [r6, #HIGH_OFFSET]	@ pv_offset high word
 	ldr	r6, [r6, #LOW_OFFSET]	@ pv_offset low word
 	cmn	r0, #1
 #ifdef CONFIG_THUMB2_KERNEL
 	@
 	@ The Thumb-2 versions of the patchable sequences are
 	@
 	@ phys-to-virt:			movw	<reg>, #offset<31:21>
 	@				lsl	<reg>, #21
 	@				sub	<VA>, <PA>, <reg>
 	@
 	@ virt-to-phys (non-LPAE):	movw	<reg>, #offset<31:21>
 	@				lsl	<reg>, #21
 	@				add	<PA>, <VA>, <reg>
 	@
 	@ virt-to-phys (LPAE):		movw	<reg>, #offset<31:21>
 	@				lsl	<reg>, #21
 	@				adds	<PAlo>, <VA>, <reg>
 	@				mov	<PAhi>, #offset<39:32>
 	@				adc	<PAhi>, <PAhi>, #0
 	@
 	@ In the non-LPAE case, all patchable instructions are MOVW
 	@ instructions, where we need to patch in the offset into the
 	@ second halfword of the opcode (the 16-bit immediate is encoded
 	@ as imm4:i:imm3:imm8)
 	@
 	@       15       11 10  9           4 3    0  15  14  12 11 8 7    0
 	@      +-----------+---+-------------+------++---+------+----+------+
 	@ MOVW | 1 1 1 1 0 | i | 1 0 0 1 0 0 | imm4 || 0 | imm3 | Rd | imm8 |
 	@      +-----------+---+-------------+------++---+------+----+------+
 	@
 	@ In the LPAE case, we also need to patch in the high word of the
 	@ offset into the immediate field of the MOV instruction, or patch it
 	@ to a MVN instruction if the offset is negative. In this case, we
 	@ need to inspect the first halfword of the opcode, to check whether
 	@ it is MOVW or MOV/MVN, and to perform the MOV to MVN patching if
 	@ needed. The encoding of the immediate is rather complex for values
 	@ of i:imm3 != 0b0000, but fortunately, we never need more than 8 lower
 	@ order bits, which can be patched into imm8 directly (and i:imm3
 	@ cleared)
 	@
 	@      15       11 10  9        5         0  15  14  12 11 8 7    0
 	@     +-----------+---+---------------------++---+------+----+------+
 	@ MOV | 1 1 1 1 0 | i | 0 0 0 1 0 0 1 1 1 1 || 0 | imm3 | Rd | imm8 |
 	@ MVN | 1 1 1 1 0 | i | 0 0 0 1 1 0 1 1 1 1 || 0 | imm3 | Rd | imm8 |
 	@     +-----------+---+---------------------++---+------+----+------+
 	@
 	moveq	r0, #0x200000		@ set bit 21, mov to mvn instruction
 	lsrs	r3, r6, #29		@ isolate top 3 bits of displacement
 	ubfx	r6, r6, #21, #8		@ put bits 28:21 into the MOVW imm8 field
 	bfi	r6, r3, #12, #3		@ put bits 31:29 into the MOVW imm3 field
 	b	.Lnext
 .Lloop:	add	r7, r4
 	adds	r4, #4			@ clears Z flag
 #ifdef CONFIG_ARM_LPAE
 	ldrh	ip, [r7]
 ARM_BE8(rev16	ip, ip)
 	tst	ip, #0x200		@ MOVW has bit 9 set, MVN has it clear
 	bne	0f			@ skip to MOVW handling (Z flag is clear)
 	bic	ip, #0x20		@ clear bit 5 (MVN -> MOV)
 	orr	ip, ip, r0, lsr #16	@ MOV -> MVN if offset < 0
 ARM_BE8(rev16	ip, ip)
 	strh	ip, [r7]
 	@ Z flag is set
 0:
 #endif
 	ldrh	ip, [r7, #2]
 ARM_BE8(rev16	ip, ip)
 	and	ip, #0xf00		@ clear everything except Rd field
 	orreq	ip, r0			@ Z flag set -> MOV/MVN -> patch in high bits
 	orrne	ip, r6			@ Z flag clear -> MOVW -> patch in low bits
 ARM_BE8(rev16	ip, ip)
 	strh	ip, [r7, #2]
 #else
 #ifdef CONFIG_CPU_ENDIAN_BE8
 @ in BE8, we load data in BE, but instructions still in LE
 #define PV_BIT24	0x00000001
 #define PV_IMM8_MASK	0xff000000
 #define PV_IMMR_MSB	0x00080000
 #else
 #define PV_BIT24	0x01000000
 #define PV_IMM8_MASK	0x000000ff
 #define PV_IMMR_MSB	0x00000800
 #endif

 	@
 	@ The ARM versions of the patchable sequences are
 	@
 	@ phys-to-virt:			sub	<VA>, <PA>, #offset<31:24>, lsl #24
 	@				sub	<VA>, <PA>, #offset<23:16>, lsl #16
 	@
 	@ virt-to-phys (non-LPAE):	add	<PA>, <VA>, #offset<31:24>, lsl #24
 	@				add	<PA>, <VA>, #offset<23:16>, lsl #16
 	@
 	@ virt-to-phys (LPAE):		movw	<reg>, #offset<31:20>
 	@				adds	<PAlo>, <VA>, <reg>, lsl #20
 	@				mov	<PAhi>, #offset<39:32>
 	@				adc	<PAhi>, <PAhi>, #0
 	@
 	@ In the non-LPAE case, all patchable instructions are ADD or SUB
 	@ instructions, where we need to patch in the offset into the
 	@ immediate field of the opcode, which is emitted with the correct
 	@ rotation value. (The effective value of the immediate is imm12<7:0>
 	@ rotated right by [2 * imm12<11:8>] bits)
 	@
 	@      31   28 27      23 22  20 19  16 15  12 11    0
 	@      +------+-----------------+------+------+-------+
 	@  ADD | cond | 0 0 1 0 1 0 0 0 |  Rn  |  Rd  | imm12 |
 	@  SUB | cond | 0 0 1 0 0 1 0 0 |  Rn  |  Rd  | imm12 |
 	@  MOV | cond | 0 0 1 1 1 0 1 0 |  Rn  |  Rd  | imm12 |
 	@  MVN | cond | 0 0 1 1 1 1 1 0 |  Rn  |  Rd  | imm12 |
 	@      +------+-----------------+------+------+-------+
 	@
 	@ In the LPAE case, we use a MOVW instruction to carry the low offset
 	@ word, and patch in the high word of the offset into the immediate
 	@ field of the subsequent MOV instruction, or patch it to a MVN
 	@ instruction if the offset is negative. We can distinguish MOVW
 	@ instructions based on bits 23:22 of the opcode, and ADD/SUB can be
 	@ distinguished from MOV/MVN (all using the encodings above) using
 	@ bit 24.
 	@
 	@      31   28 27      23 22  20 19  16 15  12 11    0
 	@      +------+-----------------+------+------+-------+
 	@ MOVW | cond | 0 0 1 1 0 0 0 0 | imm4 |  Rd  | imm12 |
 	@      +------+-----------------+------+------+-------+
 	@
 	moveq	r0, #0x400000		@ set bit 22, mov to mvn instruction
 	mov	r3, r6, lsr #16		@ put offset bits 31-16 into r3
 	mov	r6, r6, lsr #24		@ put offset bits 31-24 into r6
 	and	r3, r3, #0xf0		@ only keep offset bits 23-20 in r3
 	b	.Lnext
 .Lloop:	ldr	ip, [r7, r4]
 #ifdef CONFIG_ARM_LPAE
 	tst	ip, #PV_BIT24		@ ADD/SUB have bit 24 clear
 	beq	1f
 ARM_BE8(rev	ip, ip)
 	tst	ip, #0xc00000		@ MOVW has bits 23:22 clear
 	bic	ip, ip, #0x400000	@ clear bit 22
 	bfc	ip, #0, #12		@ clear imm12 field of MOV[W] instruction
 	orreq	ip, ip, r6, lsl #4	@ MOVW -> mask in offset bits 31-24
 	orreq	ip, ip, r3, lsr #4	@ MOVW -> mask in offset bits 23-20
 	orrne	ip, ip, r0		@ MOV  -> mask in offset bits 7-0 (or bit 22)
 ARM_BE8(rev	ip, ip)
 	b	2f
 1:
 #endif
 	tst	ip, #PV_IMMR_MSB		@ rotation value >= 16 ?
 	bic	ip, ip, #PV_IMM8_MASK
 	orreq	ip, ip, r6 ARM_BE8(, lsl #24)	@ mask in offset bits 31-24
 	orrne	ip, ip, r3 ARM_BE8(, lsl #24)	@ mask in offset bits 23-20
 2:
 	str	ip, [r7, r4]
 	add	r4, r4, #4
 #endif

 .Lnext:
 	cmp	r4, r5
 	ldrcc	r7, [r4]		@ use branch for delay slot
 	bcc	.Lloop
 	ret	lr
 ENDPROC(__fixup_a_pv_table)

 ENTRY(fixup_pv_table)
 	stmfd	sp!, {r4 - r7, lr}
 	mov	r4, r0			@ r0 = table start
 	add	r5, r0, r1		@ r1 = table size
 	bl	__fixup_a_pv_table
 	ldmfd	sp!, {r4 - r7, pc}
 ENDPROC(fixup_pv_table)

 	.data
 	.align	2
 	.globl	__pv_phys_pfn_offset
 	.type	__pv_phys_pfn_offset, %object
 __pv_phys_pfn_offset:
 	.word	0
 	.size	__pv_phys_pfn_offset, . -__pv_phys_pfn_offset

 	.globl	__pv_offset
 	.type	__pv_offset, %object
 __pv_offset:
 	.quad	0
 	.size	__pv_offset, . -__pv_offset
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* Copyright (C) 1994-2002 Russell King
	* Copyright (c) 2003, 2020 ARM Limited
	* All Rights Reserved
	*/

	#include <linux/init.h>
	#include <linux/linkage.h>
	#include <asm/assembler.h>
	#include <asm/page.h>

	#ifdef __ARMEB__
	#define LOW_OFFSET 0x4
	#define HIGH_OFFSET 0x0
	#else
	#define LOW_OFFSET 0x0
	#define HIGH_OFFSET 0x4
	#endif

	/*
	* __fixup_pv_table - patch the stub instructions with the delta between
	* PHYS_OFFSET and PAGE_OFFSET, which is assumed to be
	* 2 MiB aligned.
	*
	* Called from head.S, which expects the following registers to be preserved:
	* r1 = machine no, r2 = atags or dtb,
	* r8 = phys_offset, r9 = cpuid, r10 = procinfo
	*/
	__HEAD
	ENTRY(__fixup_pv_table)
	mov r0, r8, lsr #PAGE_SHIFT @ convert to PFN
	str_l r0, __pv_phys_pfn_offset, r3

	adr_l r0, __pv_offset
	subs r3, r8, #PAGE_OFFSET @ PHYS_OFFSET - PAGE_OFFSET
	mvn ip, #0
	strcc ip, [r0, #HIGH_OFFSET] @ save to __pv_offset high bits
	str r3, [r0, #LOW_OFFSET] @ save to __pv_offset low bits

	mov r0, r3, lsr #21 @ constant for add/sub instructions
	teq r3, r0, lsl #21 @ must be 2 MiB aligned
	bne 0f

	adr_l r4, __pv_table_begin
	adr_l r5, __pv_table_end
	b __fixup_a_pv_table

	0: mov r0, r0 @ deadloop on error
	b 0b
	ENDPROC(__fixup_pv_table)

	.text
	__fixup_a_pv_table:
	adr_l r6, __pv_offset
	ldr r0, [r6, #HIGH_OFFSET] @ pv_offset high word
	ldr r6, [r6, #LOW_OFFSET] @ pv_offset low word
	cmn r0, #1
	#ifdef CONFIG_THUMB2_KERNEL
	@
	@ The Thumb-2 versions of the patchable sequences are
	@
	@ phys-to-virt: movw <reg>, #offset<31:21>
	@ lsl <reg>, #21
	@ sub <VA>, <PA>, <reg>
	@
	@ virt-to-phys (non-LPAE): movw <reg>, #offset<31:21>
	@ lsl <reg>, #21
	@ add <PA>, <VA>, <reg>
	@
	@ virt-to-phys (LPAE): movw <reg>, #offset<31:21>
	@ lsl <reg>, #21
	@ adds <PAlo>, <VA>, <reg>
	@ mov <PAhi>, #offset<39:32>
	@ adc <PAhi>, <PAhi>, #0
	@
	@ In the non-LPAE case, all patchable instructions are MOVW
	@ instructions, where we need to patch in the offset into the
	@ second halfword of the opcode (the 16-bit immediate is encoded
	@ as imm4:i:imm3:imm8)
	@
	@ 15 11 10 9 4 3 0 15 14 12 11 8 7 0
	@ +-----------+---+-------------+------++---+------+----+------+
	@ MOVW \| 1 1 1 1 0 \| i \| 1 0 0 1 0 0 \| imm4 \|\| 0 \| imm3 \| Rd \| imm8 \|
	@ +-----------+---+-------------+------++---+------+----+------+
	@
	@ In the LPAE case, we also need to patch in the high word of the
	@ offset into the immediate field of the MOV instruction, or patch it
	@ to a MVN instruction if the offset is negative. In this case, we
	@ need to inspect the first halfword of the opcode, to check whether
	@ it is MOVW or MOV/MVN, and to perform the MOV to MVN patching if
	@ needed. The encoding of the immediate is rather complex for values
	@ of i:imm3 != 0b0000, but fortunately, we never need more than 8 lower
	@ order bits, which can be patched into imm8 directly (and i:imm3
	@ cleared)
	@
	@ 15 11 10 9 5 0 15 14 12 11 8 7 0
	@ +-----------+---+---------------------++---+------+----+------+
	@ MOV \| 1 1 1 1 0 \| i \| 0 0 0 1 0 0 1 1 1 1 \|\| 0 \| imm3 \| Rd \| imm8 \|
	@ MVN \| 1 1 1 1 0 \| i \| 0 0 0 1 1 0 1 1 1 1 \|\| 0 \| imm3 \| Rd \| imm8 \|
	@ +-----------+---+---------------------++---+------+----+------+
	@
	moveq r0, #0x200000 @ set bit 21, mov to mvn instruction
	lsrs r3, r6, #29 @ isolate top 3 bits of displacement
	ubfx r6, r6, #21, #8 @ put bits 28:21 into the MOVW imm8 field
	bfi r6, r3, #12, #3 @ put bits 31:29 into the MOVW imm3 field
	b .Lnext
	.Lloop: add r7, r4
	adds r4, #4 @ clears Z flag
	#ifdef CONFIG_ARM_LPAE
	ldrh ip, [r7]
	ARM_BE8(rev16 ip, ip)
	tst ip, #0x200 @ MOVW has bit 9 set, MVN has it clear
	bne 0f @ skip to MOVW handling (Z flag is clear)
	bic ip, #0x20 @ clear bit 5 (MVN -> MOV)
	orr ip, ip, r0, lsr #16 @ MOV -> MVN if offset < 0
	ARM_BE8(rev16 ip, ip)
	strh ip, [r7]
	@ Z flag is set
	0:
	#endif
	ldrh ip, [r7, #2]
	ARM_BE8(rev16 ip, ip)
	and ip, #0xf00 @ clear everything except Rd field
	orreq ip, r0 @ Z flag set -> MOV/MVN -> patch in high bits
	orrne ip, r6 @ Z flag clear -> MOVW -> patch in low bits
	ARM_BE8(rev16 ip, ip)
	strh ip, [r7, #2]
	#else
	#ifdef CONFIG_CPU_ENDIAN_BE8
	@ in BE8, we load data in BE, but instructions still in LE
	#define PV_BIT24 0x00000001
	#define PV_IMM8_MASK 0xff000000
	#define PV_IMMR_MSB 0x00080000
	#else
	#define PV_BIT24 0x01000000
	#define PV_IMM8_MASK 0x000000ff
	#define PV_IMMR_MSB 0x00000800
	#endif

	@
	@ The ARM versions of the patchable sequences are
	@
	@ phys-to-virt: sub <VA>, <PA>, #offset<31:24>, lsl #24
	@ sub <VA>, <PA>, #offset<23:16>, lsl #16
	@
	@ virt-to-phys (non-LPAE): add <PA>, <VA>, #offset<31:24>, lsl #24
	@ add <PA>, <VA>, #offset<23:16>, lsl #16
	@
	@ virt-to-phys (LPAE): movw <reg>, #offset<31:20>
	@ adds <PAlo>, <VA>, <reg>, lsl #20
	@ mov <PAhi>, #offset<39:32>
	@ adc <PAhi>, <PAhi>, #0
	@
	@ In the non-LPAE case, all patchable instructions are ADD or SUB
	@ instructions, where we need to patch in the offset into the
	@ immediate field of the opcode, which is emitted with the correct
	@ rotation value. (The effective value of the immediate is imm12<7:0>
	@ rotated right by [2 * imm12<11:8>] bits)
	@
	@ 31 28 27 23 22 20 19 16 15 12 11 0
	@ +------+-----------------+------+------+-------+
	@ ADD \| cond \| 0 0 1 0 1 0 0 0 \| Rn \| Rd \| imm12 \|
	@ SUB \| cond \| 0 0 1 0 0 1 0 0 \| Rn \| Rd \| imm12 \|
	@ MOV \| cond \| 0 0 1 1 1 0 1 0 \| Rn \| Rd \| imm12 \|
	@ MVN \| cond \| 0 0 1 1 1 1 1 0 \| Rn \| Rd \| imm12 \|
	@ +------+-----------------+------+------+-------+
	@
	@ In the LPAE case, we use a MOVW instruction to carry the low offset
	@ word, and patch in the high word of the offset into the immediate
	@ field of the subsequent MOV instruction, or patch it to a MVN
	@ instruction if the offset is negative. We can distinguish MOVW
	@ instructions based on bits 23:22 of the opcode, and ADD/SUB can be
	@ distinguished from MOV/MVN (all using the encodings above) using
	@ bit 24.
	@
	@ 31 28 27 23 22 20 19 16 15 12 11 0
	@ +------+-----------------+------+------+-------+
	@ MOVW \| cond \| 0 0 1 1 0 0 0 0 \| imm4 \| Rd \| imm12 \|
	@ +------+-----------------+------+------+-------+
	@
	moveq r0, #0x400000 @ set bit 22, mov to mvn instruction
	mov r3, r6, lsr #16 @ put offset bits 31-16 into r3
	mov r6, r6, lsr #24 @ put offset bits 31-24 into r6
	and r3, r3, #0xf0 @ only keep offset bits 23-20 in r3
	b .Lnext
	.Lloop: ldr ip, [r7, r4]
	#ifdef CONFIG_ARM_LPAE
	tst ip, #PV_BIT24 @ ADD/SUB have bit 24 clear
	beq 1f
	ARM_BE8(rev ip, ip)
	tst ip, #0xc00000 @ MOVW has bits 23:22 clear
	bic ip, ip, #0x400000 @ clear bit 22
	bfc ip, #0, #12 @ clear imm12 field of MOV[W] instruction
	orreq ip, ip, r6, lsl #4 @ MOVW -> mask in offset bits 31-24
	orreq ip, ip, r3, lsr #4 @ MOVW -> mask in offset bits 23-20
	orrne ip, ip, r0 @ MOV -> mask in offset bits 7-0 (or bit 22)
	ARM_BE8(rev ip, ip)
	b 2f
	1:
	#endif
	tst ip, #PV_IMMR_MSB @ rotation value >= 16 ?
	bic ip, ip, #PV_IMM8_MASK
	orreq ip, ip, r6 ARM_BE8(, lsl #24) @ mask in offset bits 31-24
	orrne ip, ip, r3 ARM_BE8(, lsl #24) @ mask in offset bits 23-20
	2:
	str ip, [r7, r4]
	add r4, r4, #4
	#endif

	.Lnext:
	cmp r4, r5
	ldrcc r7, [r4] @ use branch for delay slot
	bcc .Lloop
	ret lr
	ENDPROC(__fixup_a_pv_table)

	ENTRY(fixup_pv_table)
	stmfd sp!, {r4 - r7, lr}
	mov r4, r0 @ r0 = table start
	add r5, r0, r1 @ r1 = table size
	bl __fixup_a_pv_table
	ldmfd sp!, {r4 - r7, pc}
	ENDPROC(fixup_pv_table)

	.data
	.align 2
	.globl __pv_phys_pfn_offset
	.type __pv_phys_pfn_offset, %object
	__pv_phys_pfn_offset:
	.word 0
	.size __pv_phys_pfn_offset, . -__pv_phys_pfn_offset

	.globl __pv_offset
	.type __pv_offset, %object
	__pv_offset:
	.quad 0
	.size __pv_offset, . -__pv_offset