码迷,mamicode.com
首页 > 其他好文 > 详细

OK6410开发板bootloader架构设计分析---嵌入式回归第五篇

时间:2016-04-29 19:48:10      阅读:195      评论:0      收藏:0      [点我收藏+]

标签:

在介绍bootloader嵌,先简要介绍一下汇编的相关知识!为后边的学习做铺垫!大学里面学习过汇编,之前汇编部分的视频也是一点一点的跟着国嵌的视频把代码撸出来一步一步的调试!相对学习起来还是比较容易的!比数据结构和算法简单的多了。

汇编语言介绍这一部分暂时就不写笔记了!写bootloader后边会用到比较多,这里只简单的挑一些重要的介绍一下。

ARM汇编分类:

1. ARM标准汇编:使用ARM公司的汇编器,适合在windows平台下使用,

2. GNU汇编:适合于GNU交叉编译工具链中的汇编器,适合Linux开发平台

bootloader在最开始的时候,并没有构建运行C语言的环境,所以一开始都是用汇编代码写的,到后边等构建好了C代码环境,就可以使用C来写了,这里汇编先只简要介绍一下!

汇编程序框架:(后边的bootloader也是按照这个格式写的)

.section    .data

    <初始化的数据>

.section    .bss

    <未初始化的数据>

.section    .text

.global    _start

_start:

    <汇编代码>

1. ARM汇编指令分类学习(指令比较多):

技术分享

2. ARM伪指令

伪指令本身并没有所对应的机器码,本身只是在编译的时候起作用,或者转化为其他的实际指令来运行

3. 协处理器访问指令:(这个比较重要,在bootloader中这个一般在关键点的地方用的很多)

技术分享

下边来开始慢慢一步一步来记录bootloader从0到有,从有到精通!不想当将军的士兵不是好厨师!

bootloader设计蓝图大纲

1. bootloader 的作用 (类似于windows的bios程序,主要做一些硬件的初始化工作)

2. bootloader 设计方法 (模仿)

3. bootloader代码工程建立 (通过sourceInsight )

ARM处理器启动流程:(这个还是datasheet说了算)

1. 启动方式:

2. 地址布局:

3. 启动流程:

技术分享

这里BL0里面芯片厂商已经给我们把程序固化好了!这里我们需要完成BL1和BL2的部分!

这是uboot源码里面顶层Makefile里面的一个关于6410的配置选项:这里有一个smdk6410 选项

<span style="font-size:24px;">smdk6410_config	:	unconfig
	@$(MKCONFIG) $(@:_config=) arm s3c64xx smdk6410 samsung s3c6410 </span>
同理我们可以在/board/samsung/目录下找到这个目录文件smdk6410 ,这里面存放的就是支持开发板的一些相关文件

技术分享

打开里面的链接器脚本u-boot.lds文件可以看到一些非常有用的信息:

/*
 * (C) Copyright 2002
 * Gary Jennejohn, DENX Software Engineering, <gj@denx.de>
 *
 * See file CREDITS for list of people who contributed to this
 * project.
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License as
 * published by the Free Software Foundation; either version 2 of
 * the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
 * MA 02111-1307 USA
 */

OUTPUT_FORMAT("elf32-littlearm", "elf32-littlearm", "elf32-littlearm")
/*OUTPUT_FORMAT("elf32-arm", "elf32-arm", "elf32-arm")*/
OUTPUT_ARCH(arm)
ENTRY(_start)
SECTIONS
{
	. = 0x00000000;

	. = ALIGN(4);
	.text      :
	{
	  cpu/s3c64xx/start.o	(.text)
	  cpu/s3c64xx/s3c6410/cpu_init.o	(.text)
	  cpu/s3c64xx/onenand_cp.o	(.text)
	  cpu/s3c64xx/nand_cp.o	(.text)
	  cpu/s3c64xx/movi.o (.text)
	  *(.text)
	  lib_arm/div0.o
	}

	. = ALIGN(4);
	.rodata : { *(.rodata) }

	. = ALIGN(4);
	.data : { *(.data) }

	. = ALIGN(4);
	.got : { *(.got) }

	__u_boot_cmd_start = .;
	.u_boot_cmd : { *(.u_boot_cmd) }
	__u_boot_cmd_end = .;

	. = ALIGN(4);
	.mmudata : { *(.mmudata) }

	. = ALIGN(4);
	__bss_start = .;
	.bss : { *(.bss) }
	_end = .;
}

可以看到位于代码段最前端的是cpu/s3c64xx/start.o文件,这里start.o对应的是start.S文件!可以在相应的目录下看到!

从上面的链接器脚本中可以看到 :ENTRY(_start) 所以整个程序的入口就是_start标号处,下面可以来看看start.S文件的内容:

/*
 *  armboot - Startup Code for S3C6400/ARM1176 CPU-core
 *
 *  Copyright (c) 2007	Samsung Electronics
 *
 *
 * See file CREDITS for list of people who contributed to this
 * project.
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License as
 * published by the Free Software Foundation; either version 2 of
 * the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.	 See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
 * MA 02111-1307 USA
 *
 * 2007-09-21 - Restructured codes by jsgood (jsgood.yang@samsung.com)
 * 2007-09-21 - Added moviNAND and OneNAND boot codes by jsgood (jsgood.yang@samsung.com)
 * Base codes by scsuh (sc.suh)
 */

#include <config.h>
#include <version.h>
#ifdef CONFIG_ENABLE_MMU
#include <asm/proc/domain.h>
#endif
#include <regs.h>

#ifndef CONFIG_ENABLE_MMU
#ifndef CFG_PHY_UBOOT_BASE
#define CFG_PHY_UBOOT_BASE	CFG_UBOOT_BASE
#endif
#endif

/*
 *************************************************************************
 *
 * Jump vector table as in table 3.1 in [1]
 *
 *************************************************************************
 */

.globl _start
_start: b	reset
	ldr	pc, _undefined_instruction
	ldr	pc, _software_interrupt
	ldr	pc, _prefetch_abort
	ldr	pc, _data_abort
	ldr	pc, _not_used
	ldr	pc, _irq
	ldr	pc, _fiq

_undefined_instruction:
	.word undefined_instruction
_software_interrupt:
	.word software_interrupt
_prefetch_abort:
	.word prefetch_abort
_data_abort:
	.word data_abort
_not_used:
	.word not_used
_irq:
	.word irq
_fiq:
	.word fiq
_pad:
	.word 0x12345678 /* now 16*4=64 */
.global _end_vect
_end_vect:

	.balignl 16,0xdeadbeef
/*
 *************************************************************************
 *
 * Startup Code (reset vector)
 *
 * do important init only if we don't start from memory!
 * setup Memory and board specific bits prior to relocation.
 * relocate armboot to ram
 * setup stack
 *
 *************************************************************************
 */

_TEXT_BASE:
	.word	TEXT_BASE

/*
 * Below variable is very important because we use MMU in U-Boot.
 * Without it, we cannot run code correctly before MMU is ON.
 * by scsuh.
 */
_TEXT_PHY_BASE:
	.word	CFG_PHY_UBOOT_BASE

.globl _armboot_start
_armboot_start:
	.word _start

/*
 * These are defined in the board-specific linker script.
 */
.globl _bss_start
_bss_start:
	.word __bss_start

.globl _bss_end
_bss_end:
	.word _end

#ifdef CONFIG_USE_IRQ
/* IRQ stack memory (calculated at run-time) */
.globl IRQ_STACK_START
IRQ_STACK_START:
	.word	0x0badc0de

/* IRQ stack memory (calculated at run-time) */
.globl FIQ_STACK_START
FIQ_STACK_START:
	.word 0x0badc0de
#endif

/*
 * the actual reset code
 */

reset:
	/*
	 * set the cpu to SVC32 mode
	 */
	mrs	r0,cpsr
	bic	r0,r0,#0x1f
	orr	r0,r0,#0xd3
	msr	cpsr,r0

/*
 *************************************************************************
 *
 * CPU_init_critical registers
 *
 * setup important registers
 * setup memory timing
 *
 *************************************************************************
 */
         /*
         * we do sys-critical inits only at reboot,
         * not when booting from ram!
         */
cpu_init_crit:
	/*
	 * flush v4 I/D caches
	 */
	mov	r0, #0
	mcr	p15, 0, r0, c7, c7, 0	/* flush v3/v4 cache */
	mcr	p15, 0, r0, c8, c7, 0	/* flush v4 TLB */

	/*
	 * disable MMU stuff and caches
	 */
	mrc	p15, 0, r0, c1, c0, 0
	bic	r0, r0, #0x00002300	@ clear bits 13, 9:8 (--V- --RS)
	bic	r0, r0, #0x00000087	@ clear bits 7, 2:0 (B--- -CAM)
	orr	r0, r0, #0x00000002	@ set bit 2 (A) Align
	orr	r0, r0, #0x00001000	@ set bit 12 (I) I-Cache
	mcr	p15, 0, r0, c1, c0, 0

	/* Peri port setup */
	ldr	r0, =0x70000000
	orr	r0, r0, #0x13
    	mcr	p15,0,r0,c15,c2,4       @ 256M(0x70000000-0x7fffffff)

#ifdef CONFIG_BOOT_ONENAND
	ldr	r0, =0x70000000		@ onenand controller setup
	orr	r0, r0, #0x100000
	ldr	r1, =0x4000
	orr	r1, r1, #0xe0
	str	r1, [r0]

#if defined(CONFIG_S3C6410) || defined(CONFIG_S3C6430)
	orr	r0, r0, #300		@ disable watchdog
	mov	r1, #1
	str	r1, [r0]

	mov	r1, #0x23000000		@ start buffer register
	orr	r1, r1, #0x30000
	orr	r1, r1, #0xc800
#else
	mov	r1, =0x20000000		@ start buffer register
	orr	r1, r1, #0xc30000
	orr	r1, r1, #0xc800
#endif

	sub	r0, r1, #0x0400		@ start address1 register

	ldr	r2, [r1, #0x84]		@ ecc bypass
	orr	r2, r2, #0x100
	str	r2, [r1, #0x84]

	mov	r3, #0x0		@ DFS, FBA
	str	r3, [r0, #0x00]
	str	r3, [r0, #0x04]		@ select dataram for DDP as 0

	mov	r4, #0x104		@ interrupt register
	mov	r5, #0x0002		@ FPA, FSA
	mov	r6, #0x0800		@ BSA

onenand_bl1_load:
	str	r5, [r0, #0x1c]		@ save FPA, FSA
	orr	r6, r6, #0x02		@ BSC
	str	r6, [r1, #0x00]		@ save BSA, BSC
	str	r3, [r1, r4]		@ clear interrupt
	str	r3, [r1, #0x80]		@ write load command

	mov	r7, #0x100		@ need small delay

onenand_wait_loop1:
	subs	r7, r7, #0x1
	bne	onenand_wait_loop1

	add	r5, r5, #0x2		@ next FPA, FSA
	sub	r6, r6, #0x2
	add	r6, r6, #0x200		@ next BSA
	cmp	r5, #0x8
	bne	onenand_bl1_load
#endif

	/*
	 * Go setup Memory and board specific bits prior to relocation.
	 */
	bl	lowlevel_init	/* go setup pll,mux,memory */

	/* when we already run in ram, we don't need to relocate U-Boot.
	 * and actually, memory controller must be configured before U-Boot
	 * is running in ram.
	 */
	
	 ldr	r0, =0xff000fff
	
	


	bic	r1, pc, r0		/* r0 <- current base addr of code */
	ldr	r2, _TEXT_BASE		/* r1 <- original base addr in ram */
	bic	r2, r2, r0		/* r0 <- current base addr of code */
	cmp     r1, r2                  /* compare r0, r1                  */
	beq     after_copy		/* r0 == r1 then skip flash copy   */

#ifdef CONFIG_BOOT_NOR			/* relocate U-Boot to RAM */
	adr	r0, _start		/* r0 <- current position of code   */
	ldr	r1, _TEXT_PHY_BASE	/* r1 <- destination                */
	ldr	r2, _armboot_start
	ldr	r3, _bss_start
	sub	r2, r3, r2		/* r2 <- size of armboot            */
	add	r2, r0, r2		/* r2 <- source end address         */

nor_copy_loop:
	ldmia	r0!, {r3-r10}		/* copy from source address [r0]    */
	stmia	r1!, {r3-r10}		/* copy to   target address [r1]    */
	cmp	r0, r2			/* until source end addreee [r2]    */
	ble	nor_copy_loop
	b	after_copy
#endif

#ifdef CONFIG_BOOT_NAND
	mov	r0, #0x1000
	bl	copy_from_nand
#endif

#ifdef CONFIG_BOOT_MOVINAND
	ldr	sp, _TEXT_PHY_BASE
	bl	movi_bl2_copy
	b	after_copy
#endif

#ifdef CONFIG_BOOT_ONENAND
	ldr	sp, =0x50000000		@ temporary stack

#ifdef CONFIG_S3C6400
	mov	r1, =0x20000000		@ start buffer register
	orr	r1, r1, #0xc30000
	orr	r1, r1, #0xc800
#else
	mov	r1, #0x23000000		@ start buffer register
	orr	r1, r1, #0x30000
	orr	r1, r1, #0xc800
#endif

	ldr	r2, [r1, #0x84]		@ ecc bypass
	orr	r2, r2, #0x100
	str	r2, [r1, #0x84]

	sub	r0, r1, #0x0400		@ start address1 register

	str	r3, [r0, #0x00]
	str	r3, [r0, #0x04]		@ select dataram for DDP as 0

	mov	r4, #0x104		@ interrupt register

	mov	r6, #0x0c00		@ fixed dataram1 sector number
	str	r6, [r1, #0x00]

	mov	r3, #0x0		@ DFS, FBA
	mov	r5, #0x0000		@ FPA, FSA
	ldr	r9, =CFG_PHY_UBOOT_BASE	@ destination

onenand_bl2_load:
	str	r3, [r0, #0x00]		@ save DFS, FBA
	str	r5, [r0, #0x1c]		@ save FPA, FSA

	mov	r7, #0x0		@ clear interrupt
	str	r7, [r1, r4]
	str	r7, [r1, #0x80]		@ write load command

	mov	r8, #0x1000
onenand_wait_loop2:
	subs	r8, r8, #0x1
	bne	onenand_wait_loop2

onenand_wait_int:			@ wait INT and RI
	ldr	r7, [r1, r4]
	mov	r8, #0x8000
	orr	r8, r8, #0x80
	tst	r7, r8
	beq	onenand_wait_int

	mov	r7, #0x0		@ clear interrupt
	str	r7, [r1, r4]

	mov	r8, #0xc00		@ source address (dataram1)
	mov	r10, #0x40		@ copy loop count (64 = 2048 / 32)

	stmia	sp, {r0-r7}		@ backup

onenand_copy_to_ram:
	ldmia	r8!, {r0-r7}
	stmia	r9!, {r0-r7}
	subs	r10, r10, #0x1
	bne	onenand_copy_to_ram

	ldmia	sp, {r0-r7}		@ restore

	add	r5, r5, #0x4		@ next FPA
	cmp	r5, #0x100		@ last FPA?
	bne	onenand_bl2_load

	/* next block */
	mov	r5, #0x0		@ reset FPA
	add	r3, r3, #0x1		@ next FBA
	cmp	r3, #0x2		@ last FBA?
	bne	onenand_bl2_load
	b	after_copy
#endif

#ifdef CONFIG_BOOT_ONENAND_IROM
	ldr	sp, _TEXT_PHY_BASE
	bl	onenand_bl2_copy
	b	after_copy
#endif

after_copy:
#ifdef CONFIG_ENABLE_MMU
enable_mmu:
	/* enable domain access */
	ldr	r5, =0x0000ffff
	mcr	p15, 0, r5, c3, c0, 0		@ load domain access register

	/* Set the TTB register */
	ldr	r0, _mmu_table_base
	ldr	r1, =CFG_PHY_UBOOT_BASE
	ldr	r2, =0xfff00000
	bic	r0, r0, r2
	orr	r1, r0, r1
	mcr	p15, 0, r1, c2, c0, 0

	/* Enable the MMU */
mmu_on:
	mrc	p15, 0, r0, c1, c0, 0
	orr	r0, r0, #1			/* Set CR_M to enable MMU */
	mcr	p15, 0, r0, c1, c0, 0
	nop
	nop
	nop
	nop
#endif

skip_hw_init:
	/* Set up the stack						    */
stack_setup:
#ifdef CONFIG_MEMORY_UPPER_CODE
	ldr	sp, =(CFG_UBOOT_BASE + CFG_UBOOT_SIZE - 0xc)
#else
	ldr	r0, _TEXT_BASE		/* upper 128 KiB: relocated uboot   */
	sub	r0, r0, #CFG_MALLOC_LEN	/* malloc area                      */
	sub	r0, r0, #CFG_GBL_DATA_SIZE /* bdinfo                        */
#ifdef CONFIG_USE_IRQ
	sub	r0, r0, #(CONFIG_STACKSIZE_IRQ+CONFIG_STACKSIZE_FIQ)
#endif
	sub	sp, r0, #12		/* leave 3 words for abort-stack    */

#endif

clear_bss:
	ldr	r0, _bss_start		/* find start of bss segment        */
	ldr	r1, _bss_end		/* stop here                        */
	mov 	r2, #0x00000000		/* clear                            */

clbss_l:
	str	r2, [r0]		/* clear loop...                    */
	add	r0, r0, #4
	cmp	r0, r1
	ble	clbss_l

	ldr	pc, _start_armboot

_start_armboot:
	.word start_armboot

#ifdef CONFIG_ENABLE_MMU
_mmu_table_base:
	.word mmu_table
#endif

/*
 * copy U-Boot to SDRAM and jump to ram (from NAND or OneNAND)
 * r0: size to be compared
 * Load 1'st 2blocks to RAM because U-boot's size is larger than 1block(128k) size
 */
	.globl copy_from_nand
copy_from_nand:
	mov	r10, lr		/* save return address */

	mov	r9, r0
	/* get ready to call C functions */
	ldr	sp, _TEXT_PHY_BASE	/* setup temp stack pointer */
	sub	sp, sp, #12
	mov	fp, #0			/* no previous frame, so fp=0 */
	mov	r9, #0x1000
	bl	copy_uboot_to_ram

3:	tst 	r0, #0x0
	bne	copy_failed

	ldr	r0, =0x0c000000
	ldr	r1, _TEXT_PHY_BASE
1:	ldr	r3, [r0], #4
	ldr	r4, [r1], #4
	teq	r3, r4
	bne	compare_failed	/* not matched */
	subs	r9, r9, #4
	bne	1b

4:	mov	lr, r10		/* all is OK */
	mov	pc, lr

copy_failed:
	nop			/* copy from nand failed */
	b	copy_failed

compare_failed:
	nop			/* compare failed */
	b	compare_failed

/*
 * we assume that cache operation is done before. (eg. cleanup_before_linux())
 * actually, we don't need to do anything about cache if not use d-cache in U-Boot
 * So, in this function we clean only MMU. by scsuh
 *
 * void	theLastJump(void *kernel, int arch_num, uint boot_params);
 */
#ifdef CONFIG_ENABLE_MMU
	.globl theLastJump
theLastJump:
	mov	r9, r0
	ldr	r3, =0xfff00000
	ldr	r4, _TEXT_PHY_BASE
	adr	r5, phy_last_jump
	bic	r5, r5, r3
	orr	r5, r5, r4
	mov	pc, r5
phy_last_jump:
	/*
	 * disable MMU stuff
	 */
	mrc	p15, 0, r0, c1, c0, 0
	bic	r0, r0, #0x00002300	/* clear bits 13, 9:8 (--V- --RS) */
	bic	r0, r0, #0x00000087	/* clear bits 7, 2:0 (B--- -CAM) */
	orr	r0, r0, #0x00000002	/* set bit 2 (A) Align */
	orr	r0, r0, #0x00001000	/* set bit 12 (I) I-Cache */
	mcr	p15, 0, r0, c1, c0, 0

	mcr	p15, 0, r0, c8, c7, 0	/* flush v4 TLB */

	mov	r0, #0
	mov	pc, r9
#endif
/*
 *************************************************************************
 *
 * Interrupt handling
 *
 *************************************************************************
 */
@
@ IRQ stack frame.
@
#define S_FRAME_SIZE	72

#define S_OLD_R0	68
#define S_PSR		64
#define S_PC		60
#define S_LR		56
#define S_SP		52

#define S_IP		48
#define S_FP		44
#define S_R10		40
#define S_R9		36
#define S_R8		32
#define S_R7		28
#define S_R6		24
#define S_R5		20
#define S_R4		16
#define S_R3		12
#define S_R2		8
#define S_R1		4
#define S_R0		0

#define MODE_SVC 0x13
#define I_BIT	 0x80

/*
 * use bad_save_user_regs for abort/prefetch/undef/swi ...
 * use irq_save_user_regs / irq_restore_user_regs for IRQ/FIQ handling
 */

	.macro	bad_save_user_regs
	sub	sp, sp, #S_FRAME_SIZE		@ carve out a frame on current user stack
	stmia	sp, {r0 - r12}			@ Save user registers (now in svc mode) r0-r12

	ldr	r2, _armboot_start
	sub	r2, r2, #(CFG_MALLOC_LEN)
	sub	r2, r2, #(CFG_GBL_DATA_SIZE+8)	@ set base 2 words into abort stack
	ldmia	r2, {r2 - r3}			@ get values for "aborted" pc and cpsr (into parm regs)
	add	r0, sp, #S_FRAME_SIZE		@ grab pointer to old stack

	add	r5, sp, #S_SP
	mov	r1, lr
	stmia	r5, {r0 - r3}			@ save sp_SVC, lr_SVC, pc, cpsr
	mov	r0, sp				@ save current stack into r0 (param register)
	.endm

	.macro	irq_save_user_regs
	sub	sp, sp, #S_FRAME_SIZE
	stmia	sp, {r0 - r12}			@ Calling r0-r12
	add	r8, sp, #S_PC			@ !!!! R8 NEEDS to be saved !!!! a reserved stack spot would be good.
	stmdb	r8, {sp, lr}^			@ Calling SP, LR
	str	lr, [r8, #0]			@ Save calling PC
	mrs	r6, spsr
	str	r6, [r8, #4]			@ Save CPSR
	str	r0, [r8, #8]			@ Save OLD_R0
	mov	r0, sp
	.endm

	.macro	irq_restore_user_regs
	ldmia	sp, {r0 - lr}^			@ Calling r0 - lr
	mov	r0, r0
	ldr	lr, [sp, #S_PC]			@ Get PC
	add	sp, sp, #S_FRAME_SIZE
	subs	pc, lr, #4			@ return & move spsr_svc into cpsr
	.endm

	.macro get_bad_stack
	ldr	r13, _armboot_start		@ setup our mode stack (enter in banked mode)
	sub	r13, r13, #(CFG_MALLOC_LEN)	@ move past malloc pool
	sub	r13, r13, #(CFG_GBL_DATA_SIZE+8) @ move to reserved a couple spots for abort stack

	str	lr, [r13]			@ save caller lr in position 0 of saved stack
	mrs	lr, spsr			@ get the spsr
	str	lr, [r13, #4]			@ save spsr in position 1 of saved stack

	mov	r13, #MODE_SVC			@ prepare SVC-Mode
	@ msr	spsr_c, r13
	msr	spsr, r13			@ switch modes, make sure moves will execute
	mov	lr, pc				@ capture return pc
	movs	pc, lr				@ jump to next instruction & switch modes.
	.endm

	.macro get_bad_stack_swi
	sub	r13, r13, #4			@ space on current stack for scratch reg.
	str	r0, [r13]			@ save R0's value.
	ldr	r0, _armboot_start		@ get data regions start
	sub	r0, r0, #(CFG_MALLOC_LEN)	@ move past malloc pool
	sub	r0, r0, #(CFG_GBL_DATA_SIZE+8)	@ move past gbl and a couple spots for abort stack
	str	lr, [r0]			@ save caller lr in position 0 of saved stack
	mrs	r0, spsr			@ get the spsr
	str	lr, [r0, #4]			@ save spsr in position 1 of saved stack
	ldr	r0, [r13]			@ restore r0
	add	r13, r13, #4			@ pop stack entry
	.endm

	.macro get_irq_stack			@ setup IRQ stack
	ldr	sp, IRQ_STACK_START
	.endm

	.macro get_fiq_stack			@ setup FIQ stack
	ldr	sp, FIQ_STACK_START
	.endm

/*
 * exception handlers
 */
	.align	5
undefined_instruction:
	get_bad_stack
	bad_save_user_regs
	bl	do_undefined_instruction

	.align	5
software_interrupt:
	get_bad_stack_swi
	bad_save_user_regs
	bl	do_software_interrupt

	.align	5
prefetch_abort:
	get_bad_stack
	bad_save_user_regs
	bl	do_prefetch_abort

	.align	5
data_abort:
	get_bad_stack
	bad_save_user_regs
	bl	do_data_abort

	.align	5
not_used:
	get_bad_stack
	bad_save_user_regs
	bl	do_not_used

#ifdef CONFIG_USE_IRQ

	.align	5
irq:
	get_irq_stack
	irq_save_user_regs
	bl	do_irq
	irq_restore_user_regs

	.align	5
fiq:
	get_fiq_stack
	/* someone ought to write a more effiction fiq_save_user_regs */
	irq_save_user_regs
	bl	do_fiq
	irq_restore_user_regs

#else

	.align	5
irq:
	get_bad_stack
	bad_save_user_regs
	bl	do_irq

	.align	5
fiq:
	get_bad_stack
	bad_save_user_regs
	bl	do_fiq

#endif
	.align 5
.global arm1136_cache_flush
arm1136_cache_flush:
		mcr	p15, 0, r1, c7, c5, 0	@ invalidate I cache
		mov	pc, lr			@ back to caller

#if defined(CONFIG_INTEGRATOR) && defined(CONFIG_ARCH_CINTEGRATOR)
/* Use the IntegratorCP function from board/integratorcp/platform.S */
#elif defined(CONFIG_S3C64XX)
/* For future usage of S3C64XX*/
#else
	.align	5
.globl reset_cpu
reset_cpu:
	ldr	r1, rstctl	/* get addr for global reset reg */
	mov	r3, #0x2	/* full reset pll+mpu */
	str	r3, [r1]	/* force reset */
	mov	r0, r0
_loop_forever:
	b	_loop_forever
rstctl:
	.word	PM_RSTCTRL_WKUP

#endif
全部都是汇编代码,而且还有点长!其实整个学下来相比数据结构和算法感觉还是简单多了!从上面的代码中可以找到_start标号处,那就是程序开始执行的入口处!下面就可以用sourceInsight来分析源码了!

下面的基本上是对照着uboot源码里面的ok6410 start.S源码分析整个start过程的工作流程图!对比着上面的代码和注释结合起来看可以看到也不是那么复杂!在把里面的各个知识点逐个击破!



技术分享

技术分享

技术分享




OK6410开发板bootloader架构设计分析---嵌入式回归第五篇

标签:

原文地址:http://blog.csdn.net/coding__madman/article/details/51175191

(0)
(0)
   
举报
评论 一句话评论(0
登录后才能评论!
© 2014 mamicode.com 版权所有  联系我们:gaon5@hotmail.com
迷上了代码!