【系统移植】uboot详细分析
uboot使用
uboot控制台,倒计时
命令: 调试,操作一些硬件
setenv printenv saveenv
nand erase
nand write
tftp 20008000 zImage
help : uboot可以提供哪些命令
setenv == set == sete == seten
nand erase
nand write
tftp 20008000 zImage
help : uboot可以提供哪些命令
setenv == set == sete == seten
环境变量: 为命令提供参数
serverip : tftp命令提供tftp服务器的地址
ipaddr : tftp命令提供tftp客户端(开发板)的地址
两个环境变量
uboot: 下载内核,并启动内核
bootcmd: 倒计时结束后,uboot应该自动做什么事情
set bootcmd tftp
20008000 zImage \; bootm
20008000
set serverip 192. 168. 7. 2
set ipaddr 192. 168. 7. 6
set ethaddr 00 : 22 : 23 : 24 : 25 :ee
set serverip 192. 168. 7. 2
set ipaddr 192. 168. 7. 6
set ethaddr 00 : 22 : 23 : 24 : 25 :ee
倒计时结束的时候,uboot会执行bootcmd中的内容:
tftp 20008000 zImage ; bootm 20008000
从tftp服务器(serverip)中将zImage文件(/tftpboot/)下载到开发板(ipaddr)中内存的20008000
set bootcmd tftp 20008000 zImage ; bootm 20008000
bootargs: 负责告诉内核文件系统在哪里(uboot传递给内核, 内核要用)
set bootargs init
=
/linuxrc console
=ttySAC0,
115200 root
=
/dev
/nfs nfsroot
=
192.
168.
7.
2
:
/opt
/filesystem ip
=
192.
168.
7.
6
root =xxxx : 根文件系统目录在哪里
/dev /nfs : 根文件系统目录在网络的远端
nfsroot =xxxx : 根文件系统目录在哪台机器的哪个文件路径
nfsroot = 192. 168. 7. 2 : /opt /filesystem
ip = 192. 168. 7. 6 : 系统登录的时候,静态分配一个ip
如果root = /dev /nfs
root = /dev /nfs + nfsroot =xxxx +ip =xx
如果root = /dev /mtdblock2(文件系统制作的时候会讲)
root = /dev /mtdblock2 + rootfstype =cramfs
console =ttySAC0, 115200 : 内核启动过程中,调试信息往哪里输出,printk
init = /linuxrc : 指定第一个init进程的可执行代码文件
/opt /filesystem == > host : /etc /exports
sudo vim /etc/exports
/opt /filesystem *(subtree_check,rw,no_root_squash,async)
/opt /fs100 /rootfs *(subtree_check,rw,no_root_squash,async)
root =xxxx : 根文件系统目录在哪里
/dev /nfs : 根文件系统目录在网络的远端
nfsroot =xxxx : 根文件系统目录在哪台机器的哪个文件路径
nfsroot = 192. 168. 7. 2 : /opt /filesystem
ip = 192. 168. 7. 6 : 系统登录的时候,静态分配一个ip
如果root = /dev /nfs
root = /dev /nfs + nfsroot =xxxx +ip =xx
如果root = /dev /mtdblock2(文件系统制作的时候会讲)
root = /dev /mtdblock2 + rootfstype =cramfs
console =ttySAC0, 115200 : 内核启动过程中,调试信息往哪里输出,printk
init = /linuxrc : 指定第一个init进程的可执行代码文件
/opt /filesystem == > host : /etc /exports
sudo vim /etc/exports
/opt /filesystem *(subtree_check,rw,no_root_squash,async)
/opt /fs100 /rootfs *(subtree_check,rw,no_root_squash,async)
启动内核:go/bootm
官方的uboot
zImage
: go
set bootcmd tftp 20008000 zImage \; go 20008000
uImage
: bootm(下载地址,不能是 20008000)
set bootcmd tftp 20800000 uImage \; bootm 20800000
下载地址的选用 :
go == > 可以是任何地址
bootm == > 20008000 +zImage的大小以上 == > 20800000
综合用法:
set bootcmd tftp 20800000 zImage \; go 20800000
set bootcmd tftp 20800000 uImage \; bootm 20800000
uboot1. 3. 4 :
zImage /uImage == >bootm
set bootcmd tftp 20800000 uImage \; bootm 20800000
: go
set bootcmd tftp 20008000 zImage \; go 20008000
uImage
: bootm(下载地址,不能是 20008000)
set bootcmd tftp 20800000 uImage \; bootm 20800000
下载地址的选用 :
go == > 可以是任何地址
bootm == > 20008000 +zImage的大小以上 == > 20800000
综合用法:
set bootcmd tftp 20800000 zImage \; go 20800000
set bootcmd tftp 20800000 uImage \; bootm 20800000
uboot1. 3. 4 :
zImage /uImage == >bootm
set bootcmd tftp 20800000 uImage \; bootm 20800000
uboot的连接脚本
所在路径:cpu/arm_cortexa8/u-boot.lds
OUTPUT_FORMAT(
"elf32-littlearm",
"elf32-littlearm",
"elf32-littlearm")
OUTPUT_ARCH(arm)
ENTRY(_start) // 入口函数
SECTIONS
{
. = 0x00000000; // 当前的起始位置0x0
. = ALIGN( 4);
.text(目标文件) :
{
cpu /arm_cortexa8 /start.o (.text) // 第一个文件的.text
*(.text)
}
. = ALIGN( 4); // 当前位置四字节对齐
.rodata : { *(SORT_BY_ALIGNMENT(SORT_BY_NAME(.rodata *))) }
. = ALIGN( 4);
.data : { *(.data) }
. = ALIGN( 4);
.got : { *(.got) }
__u_boot_cmd_start = .; // 用__u_boot_cmd_start记录当前的位置, 代码会用到,全局的
.u_boot_cmd : { *(.u_boot_cmd) } // 段数据
__u_boot_cmd_end = .; // 结束位置
. = ALIGN( 4);
__bss_start = .;
.bss : { *(.bss) }
_end = .;
}
OUTPUT_ARCH(arm)
ENTRY(_start) // 入口函数
SECTIONS
{
. = 0x00000000; // 当前的起始位置0x0
. = ALIGN( 4);
.text(目标文件) :
{
cpu /arm_cortexa8 /start.o (.text) // 第一个文件的.text
*(.text)
}
. = ALIGN( 4); // 当前位置四字节对齐
.rodata : { *(SORT_BY_ALIGNMENT(SORT_BY_NAME(.rodata *))) }
. = ALIGN( 4);
.data : { *(.data) }
. = ALIGN( 4);
.got : { *(.got) }
__u_boot_cmd_start = .; // 用__u_boot_cmd_start记录当前的位置, 代码会用到,全局的
.u_boot_cmd : { *(.u_boot_cmd) } // 段数据
__u_boot_cmd_end = .; // 结束位置
. = ALIGN( 4);
__bss_start = .;
.bss : { *(.bss) }
_end = .;
}
连接的基地址:
-Ttext 0x34800000==>board/samsung/smdkc100/config.mk
TEXT_BASE = 0x34800000
1,TEXT_BASE指定uboot的连接的起始位置
2,指定uboot重定位的位置(可以改成0x2ff00000)
uboot配置的详细说明
make smdkc100_config
vim Makefile
unconfig :
@ rm -f $(obj)include /config.h $(obj)include /config.mk \
$(obj)board / * /config.tmp $(obj)board / * / * /config.tmp \
$(obj)include /autoconf.mk $(obj)include /autoconf.mk.dep
MKCONFIG : = $(SRCTREE) /mkconfig == . /mkconfig shell脚本(可执行程序)
smdkc100_config : unconfig
@$(MKCONFIG) $(@ :_config =) arm arm_cortexa8 smdkc100 samsung s5pc1xx
. /mkconfig smdkc100 arm arm_cortexa8 smdkc100 samsung s5pc1xx
执行一个脚本: 传递了6个参数(控制源码的编译)
arm : 架构 == > lib_arm
smdkc100 : include /configs /smdkc100.h / / 开发板所有的宏的配置
arm_cortexa8 : arm名 == > cpu /arm_cortexa8
smdkc100 samsung : 开发板名 == > board /samsung /smdkc100
s5pc1xx :cpu == >cpu /arm_cortexa8 /s5pc1xx
$(@ :_config =) : $@ :_config = == >smdkc100_config :_config = / / _config替换成空,去掉
$(@ :_config =xxx) == = >smdkc100xxx
vim Makefile
unconfig :
@ rm -f $(obj)include /config.h $(obj)include /config.mk \
$(obj)board / * /config.tmp $(obj)board / * / * /config.tmp \
$(obj)include /autoconf.mk $(obj)include /autoconf.mk.dep
MKCONFIG : = $(SRCTREE) /mkconfig == . /mkconfig shell脚本(可执行程序)
smdkc100_config : unconfig
@$(MKCONFIG) $(@ :_config =) arm arm_cortexa8 smdkc100 samsung s5pc1xx
. /mkconfig smdkc100 arm arm_cortexa8 smdkc100 samsung s5pc1xx
执行一个脚本: 传递了6个参数(控制源码的编译)
arm : 架构 == > lib_arm
smdkc100 : include /configs /smdkc100.h / / 开发板所有的宏的配置
arm_cortexa8 : arm名 == > cpu /arm_cortexa8
smdkc100 samsung : 开发板名 == > board /samsung /smdkc100
s5pc1xx :cpu == >cpu /arm_cortexa8 /s5pc1xx
$(@ :_config =) : $@ :_config = == >smdkc100_config :_config = / / _config替换成空,去掉
$(@ :_config =xxx) == = >smdkc100xxx
uboot第一阶段启动流程
1,建立异常向量表
:
_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
2,
reset :
/*
* set the cpu to SVC32 mode, disable F, I
*/
mrs r0, cpsr
bic r0, r0, #0x1f
orr r0, r0, #0xd3
msr cpsr,r0
bl cpu_init_crit
|
/*
* Invalidate L1 I/D
*/
mov r0, # 0 @ set up for MCR
mcr p15, 0, r0, c8, c7, 0 @ invalidate TLBs
mcr p15, 0, r0, c7, c5, 0 @ invalidate icache
/*
* disable MMU stuff and caches
*/
mrc p15, 0, r0, c1, c0, 0
bic r0, r0, #0x00002000 @ clear bits 13 ( --V -)
bic r0, r0, #0x00000007 @ clear bits 2 : 0 ( -CAM)
orr r0, r0, #0x00000002 @ set bit 1 ( --A -) Align
orr r0, r0, #0x00000800 @ set bit 12 (Z -- -) BTB
mcr p15, 0, r0, c1, c0, 0
bl lowlevel_init //lowlevel_init.S (board\samsung\smdkc100):lowlevel_init:
|
/* Disable Watchdog */
ldr r0, =S5PC100_WATCHDOG_BASE @0xEA200000
orr r0, r0, #0x0
str r5, [r0]
/* setting SRAM */
ldr r0, =S5PC100_SROMC_BASE
ldr r1, =0x9
str r1, [r0]
/* S5PC100 has 3 groups of interrupt sources */
ldr r0, =S5PC100_VIC0_BASE @0xE4000000
ldr r1, =S5PC100_VIC1_BASE @0xE4000000
ldr r2, =S5PC100_VIC2_BASE @0xE4000000
/* Disable all interrupts (VIC0, VIC1 and VIC2) */
mvn r3, #0x0
str r3, [r0, #0x14] @INTENCLEAR
str r3, [r1, #0x14] @INTENCLEAR
str r3, [r2, #0x14] @INTENCLEAR
/* Set all interrupts as IRQ */
str r5, [r0, #0xc] @INTSELECT
str r5, [r1, #0xc] @INTSELECT
str r5, [r2, #0xc] @INTSELECT
/* Pending Interrupt Clear */
str r5, [r0, #0xf00] @INTADDRESS
str r5, [r1, #0xf00] @INTADDRESS
str r5, [r2, #0xf00] @INTADDRESS
bl uart_asm_init // 只是设置了gpio的功能,波特率的设置在第二阶段
# if 1 // 改动的部分
/* init system clock */
bl system_clock_init // 基本上没太大问题
bl mem_ctrl_asm_init
//mem_setup.S board\samsung\Smdkc100
// 内存的初始化比较复杂, 原厂会提供(1.3.4)
// 向FAE要
// 这部分代码运行有问题
1,mem_ctrl_asm_init
2,mem_setup.S需要被编译 < == =board\samsung\Smdkc100\Makefile
3,内存初始化代码应该在前 16k (反汇编)
修改cpu /arm_cotexa8 /u -boot.lds
_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
2,
reset :
/*
* set the cpu to SVC32 mode, disable F, I
*/
mrs r0, cpsr
bic r0, r0, #0x1f
orr r0, r0, #0xd3
msr cpsr,r0
bl cpu_init_crit
|
/*
* Invalidate L1 I/D
*/
mov r0, # 0 @ set up for MCR
mcr p15, 0, r0, c8, c7, 0 @ invalidate TLBs
mcr p15, 0, r0, c7, c5, 0 @ invalidate icache
/*
* disable MMU stuff and caches
*/
mrc p15, 0, r0, c1, c0, 0
bic r0, r0, #0x00002000 @ clear bits 13 ( --V -)
bic r0, r0, #0x00000007 @ clear bits 2 : 0 ( -CAM)
orr r0, r0, #0x00000002 @ set bit 1 ( --A -) Align
orr r0, r0, #0x00000800 @ set bit 12 (Z -- -) BTB
mcr p15, 0, r0, c1, c0, 0
bl lowlevel_init //lowlevel_init.S (board\samsung\smdkc100):lowlevel_init:
|
/* Disable Watchdog */
ldr r0, =S5PC100_WATCHDOG_BASE @0xEA200000
orr r0, r0, #0x0
str r5, [r0]
/* setting SRAM */
ldr r0, =S5PC100_SROMC_BASE
ldr r1, =0x9
str r1, [r0]
/* S5PC100 has 3 groups of interrupt sources */
ldr r0, =S5PC100_VIC0_BASE @0xE4000000
ldr r1, =S5PC100_VIC1_BASE @0xE4000000
ldr r2, =S5PC100_VIC2_BASE @0xE4000000
/* Disable all interrupts (VIC0, VIC1 and VIC2) */
mvn r3, #0x0
str r3, [r0, #0x14] @INTENCLEAR
str r3, [r1, #0x14] @INTENCLEAR
str r3, [r2, #0x14] @INTENCLEAR
/* Set all interrupts as IRQ */
str r5, [r0, #0xc] @INTSELECT
str r5, [r1, #0xc] @INTSELECT
str r5, [r2, #0xc] @INTSELECT
/* Pending Interrupt Clear */
str r5, [r0, #0xf00] @INTADDRESS
str r5, [r1, #0xf00] @INTADDRESS
str r5, [r2, #0xf00] @INTADDRESS
bl uart_asm_init // 只是设置了gpio的功能,波特率的设置在第二阶段
# if 1 // 改动的部分
/* init system clock */
bl system_clock_init // 基本上没太大问题
bl mem_ctrl_asm_init
//mem_setup.S board\samsung\Smdkc100
// 内存的初始化比较复杂, 原厂会提供(1.3.4)
// 向FAE要
// 这部分代码运行有问题
1,mem_ctrl_asm_init
2,mem_setup.S需要被编译 < == =board\samsung\Smdkc100\Makefile
3,内存初始化代码应该在前 16k (反汇编)
修改cpu /arm_cotexa8 /u -boot.lds
栈的初始化:
/* Set up the stack */
stack_setup:
ldr r0, _TEXT_BASE @ upper 128 KiB : relocated uboot
sub r0, r0, #CONFIG_SYS_MALLOC_LEN @ malloc area
sub r0, r0, #CONFIG_SYS_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
and sp, sp, # ~ 7 @ 8 byte alinged for (ldr /str)d
/* Set up the stack */
stack_setup:
ldr r0, _TEXT_BASE @ upper 128 KiB : relocated uboot
sub r0, r0, #CONFIG_SYS_MALLOC_LEN @ malloc area
sub r0, r0, #CONFIG_SYS_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
and sp, sp, # ~ 7 @ 8 byte alinged for (ldr /str)d
uboot代码的自我拷贝:
/* nand src offset : 0x0*/
mov r0, #0x0
/* ddr dst addr : 0x2ff00000*/
ldr r1, =0x2ff00000
/*size*/
ldr r2, =0x40000
bl copy2ddr
ddr的地址(重定位的目标地址) : 和uboot的链接的基地址要一样
board /samsung /smdkc100 /config.mk
TEXT_BASE =xxxx
/* nand src offset : 0x0*/
mov r0, #0x0
/* ddr dst addr : 0x2ff00000*/
ldr r1, =0x2ff00000
/*size*/
ldr r2, =0x40000
bl copy2ddr
ddr的地址(重定位的目标地址) : 和uboot的链接的基地址要一样
board /samsung /smdkc100 /config.mk
TEXT_BASE =xxxx
清bss端
/* Clear BSS (if any). Is below tx (watch load addr - need space) */
clear_bss:
ldr r0, _bss_start @ find start of bss segment
ldr r1, _bss_end @ stop here
mov r2, #0x00000000 @ clear value
clbss_l:
str r2, [r0] @ clear BSS location
cmp r0, r1 @ are we at the end yet
add r0, r0, #4 @ increment clear index pointer
bne clbss_l @ keep clearing till at end
clear_bss:
ldr r0, _bss_start @ find start of bss segment
ldr r1, _bss_end @ stop here
mov r2, #0x00000000 @ clear value
clbss_l:
str r2, [r0] @ clear BSS location
cmp r0, r1 @ are we at the end yet
add r0, r0, #4 @ increment clear index pointer
bne clbss_l @ keep clearing till at end
跳转到c阶段
ldr pc, _start_armboot @ jump to C code
ldr pc, _start_armboot @ jump to C code
_start_armboot: .word start_armboot
_start_armboot: .word start_armboot
//start_armboot它的值是在编译的时候就已经确定:0x2ff00000+offset==> 0x2ff00980
arm: 基本所有的指令都是位置无关(指令在哪里执行都可以)
有些代码是位置有关: ldr pc, _start_armboot (pc跳转的目标地址_start_armboot(0x2ff00980),和特定的位置相关)
ldr本身这条指令是位置无关,整个ldr pc, _start_armboot==>成为一个位置相关的指令
链接地址: 链接器为所有的指令做的排序, 肯定有有个基地址: 基地址+该指令的偏移量
运行地址: 指令实际加载的地址,运行时,指令存放地址
物理地址: 和硬件相关,数据手册中的地址都是物理地址, 硬件工程师为设备设定的值
虚拟地址: 一般和mmu相关
思路:
1,支持一种启动模式nand启动
a, 时钟和内存的初始化
1,mem_setup.S 被编译
b, 完成自拷贝的实现
nand_ops.c(读操作)
nand(0x0) --> ddr(TEXT_BASE)
board/samsung/smdkc100/config.mk
c,第一阶段的代码必须全部在前16k
u-boot.lds
d, 熟悉一下第一阶段的启动流程代码
uboot第二阶段代码
lib_arm/Board.c
void start_armboot (void)
为什么总是去看smkdc100.h
#
include
<common.h
>
|
# include <config.h >
|
# define CONFIG_BOARDDIR board /samsung /smdkc100
# include <config_defaults.h >
# include <configs /smdkc100.h >
# include < asm /config.h >
|
# include <config.h >
|
# define CONFIG_BOARDDIR board /samsung /smdkc100
# include <config_defaults.h >
# include <configs /smdkc100.h >
# include < asm /config.h >
先看主线流程
// 设置gd指针指向特定位置
gd = (gd_t *)(_armboot_start - CONFIG_SYS_MALLOC_LEN - sizeof(gd_t));
// gd指针指向的空间,清零
memset (( void *)gd, 0, sizeof (gd_t));
gd - >bd = (bd_t *)(( char *)gd - sizeof(bd_t));
memset (gd - >bd, 0, sizeof (bd_t));
// 初始化序列
for (init_fnc_ptr = init_sequence; *init_fnc_ptr; ++init_fnc_ptr) {
if (( *init_fnc_ptr)() != 0) {
hang ();
}
}
// 堆的初始化
/* armboot_start is defined in the board-specific linker script */
mem_malloc_init (_armboot_start - CONFIG_SYS_MALLOC_LEN,
CONFIG_SYS_MALLOC_LEN);
# if defined(CONFIG_CMD_NAND) // CONFIG_CMD_NAND没有定义
puts ( "NAND: ");
nand_init(); /* go init the NAND */
# endif
// 环境变量的重定位
env_relocate ();
// 串口的初始化
serial_initialize();
// 无需关心
/* IP Address */
gd - >bd - >bi_ip_addr = getenv_IPaddr ( "ipaddr");
stdio_init (); /* get the devices list going. */
jumptable_init ();
console_init_r ();
// 中断的使能
/* enable exceptions */
enable_interrupts ();
/* Initialize from environment */
if ((s = getenv ( "loadaddr")) != NULL) {
load_addr = simple_strtoul (s, NULL, 16);
}
if ((s = getenv ( "bootfile")) != NULL) {
copy_filename (BootFile, s, sizeof (BootFile));
}
// 网卡的初始化
eth_initialize(gd - >bd);
//死循环
for (;;) {
main_loop ();
}
gd = (gd_t *)(_armboot_start - CONFIG_SYS_MALLOC_LEN - sizeof(gd_t));
// gd指针指向的空间,清零
memset (( void *)gd, 0, sizeof (gd_t));
gd - >bd = (bd_t *)(( char *)gd - sizeof(bd_t));
memset (gd - >bd, 0, sizeof (bd_t));
// 初始化序列
for (init_fnc_ptr = init_sequence; *init_fnc_ptr; ++init_fnc_ptr) {
if (( *init_fnc_ptr)() != 0) {
hang ();
}
}
// 堆的初始化
/* armboot_start is defined in the board-specific linker script */
mem_malloc_init (_armboot_start - CONFIG_SYS_MALLOC_LEN,
CONFIG_SYS_MALLOC_LEN);
# if defined(CONFIG_CMD_NAND) // CONFIG_CMD_NAND没有定义
puts ( "NAND: ");
nand_init(); /* go init the NAND */
# endif
// 环境变量的重定位
env_relocate ();
// 串口的初始化
serial_initialize();
// 无需关心
/* IP Address */
gd - >bd - >bi_ip_addr = getenv_IPaddr ( "ipaddr");
stdio_init (); /* get the devices list going. */
jumptable_init ();
console_init_r ();
// 中断的使能
/* enable exceptions */
enable_interrupts ();
/* Initialize from environment */
if ((s = getenv ( "loadaddr")) != NULL) {
load_addr = simple_strtoul (s, NULL, 16);
}
if ((s = getenv ( "bootfile")) != NULL) {
copy_filename (BootFile, s, sizeof (BootFile));
}
// 网卡的初始化
eth_initialize(gd - >bd);
//死循环
for (;;) {
main_loop ();
}
模块的方式
for (init_fnc_ptr
= init_sequence;
*init_fnc_ptr;
++init_fnc_ptr) {
if (( *init_fnc_ptr)() != 0) {
hang ();
}
}
arch_cpu_init,
board_init, // smdkc100开发板的整体的初始化
timer_init, // 定时器的初始化, timer4==>倒计时的间隔时间,产生一个10ms的间隔
env_init, // 环境变量的初步初始化 /* initialize environment */
init_baudrate, // 波特率的设置 /* initialze baudrate settings */
serial_init, // 串口的初始化 /* serial communications setup */
// 分水岭, 才能够使用printf去打印调试信息
console_init_f, /* stage 1 init of console */
display_banner, /* say that we are here */
print_cpuinfo, /* display cpu info (and speed) */
checkboard, /* display board info */
dram_init, /* configure available RAM banks */
display_dram_config
if (( *init_fnc_ptr)() != 0) {
hang ();
}
}
arch_cpu_init,
board_init, // smdkc100开发板的整体的初始化
timer_init, // 定时器的初始化, timer4==>倒计时的间隔时间,产生一个10ms的间隔
env_init, // 环境变量的初步初始化 /* initialize environment */
init_baudrate, // 波特率的设置 /* initialze baudrate settings */
serial_init, // 串口的初始化 /* serial communications setup */
// 分水岭, 才能够使用printf去打印调试信息
console_init_f, /* stage 1 init of console */
display_banner, /* say that we are here */
print_cpuinfo, /* display cpu info (and speed) */
checkboard, /* display board info */
dram_init, /* configure available RAM banks */
display_dram_config
环境变量处理:
COBJS
-$(CONFIG_ENV_IS_IN_NAND)
+= env_nand.o
环境变量的保存到哪个地方 : CONFIG_ENV_IS_IN_NAND
env_init
|
gd - >env_addr = (ulong) &default_environment[ 0]; //gd->env_addr指向默认的环境变量
gd - >env_valid = 1;
env_relocate ();
| //分配空间,128k
env_ptr = (env_t *)malloc (CONFIG_ENV_SIZE);
env_relocate_spec ();
| // 从nand中0x40000读取数据到malloc区域
ret = readenv(CONFIG_ENV_OFFSET, (u_char *) env_ptr);
if (ret) //如果读取失败,就使用默认的环境变量
return use_default();
//读取数据成功,此时还要crc校验一下,
if (crc32( 0, env_ptr - >data, ENV_SIZE) != env_ptr - >crc)
//如果校验失败,仍然使用默认的环境变量
return use_default();
|
puts ( "*** Warning - bad CRC or NAND, using default environment\n\n");
memset(env_ptr, 0, sizeof(env_t));
// 使用默认的环境变量
memcpy(env_ptr - >data, default_environment, sizeof(default_environment));
//CONFIG_ENV_OFFSET是可以控制env保存到nand中特定的位置
// 0x40000
readenv(CONFIG_ENV_OFFSET, (u_char *) env_ptr);
| // 0x40000 块大小 , malloc区域
char_ptr = &buf[amount_loaded];
nand_read( &nand_info[ 0], offset, &len, char_ptr)
| // mtd的架构
info - >read(info, ofs, *len, (size_t *)len, buf);
自己设定环境变量 : smdkc100.h
# define CONFIG_SERVERIP 192. 168. 7. 2
# define CONFIG_IPADDR 192. 168. 7. 6
# define CONFIG_ETHADDR 00 : 23 : 24 : 25 : 26 : 27
# define CONFIG_BOOTCOMMAND "tftp 20800000 zImage35 \; go 20800000"
# define CONFIG_BOOTARGS "root=/de/nfs nfsroot=192.168.7.2:/opt/filesystem ip=192.168.7.6 console=ttySAC0,115200 init=/linuxrc"
环境变量的保存到哪个地方 : CONFIG_ENV_IS_IN_NAND
env_init
|
gd - >env_addr = (ulong) &default_environment[ 0]; //gd->env_addr指向默认的环境变量
gd - >env_valid = 1;
env_relocate ();
| //分配空间,128k
env_ptr = (env_t *)malloc (CONFIG_ENV_SIZE);
env_relocate_spec ();
| // 从nand中0x40000读取数据到malloc区域
ret = readenv(CONFIG_ENV_OFFSET, (u_char *) env_ptr);
if (ret) //如果读取失败,就使用默认的环境变量
return use_default();
//读取数据成功,此时还要crc校验一下,
if (crc32( 0, env_ptr - >data, ENV_SIZE) != env_ptr - >crc)
//如果校验失败,仍然使用默认的环境变量
return use_default();
|
puts ( "*** Warning - bad CRC or NAND, using default environment\n\n");
memset(env_ptr, 0, sizeof(env_t));
// 使用默认的环境变量
memcpy(env_ptr - >data, default_environment, sizeof(default_environment));
//CONFIG_ENV_OFFSET是可以控制env保存到nand中特定的位置
// 0x40000
readenv(CONFIG_ENV_OFFSET, (u_char *) env_ptr);
| // 0x40000 块大小 , malloc区域
char_ptr = &buf[amount_loaded];
nand_read( &nand_info[ 0], offset, &len, char_ptr)
| // mtd的架构
info - >read(info, ofs, *len, (size_t *)len, buf);
自己设定环境变量 : smdkc100.h
# define CONFIG_SERVERIP 192. 168. 7. 2
# define CONFIG_IPADDR 192. 168. 7. 6
# define CONFIG_ETHADDR 00 : 23 : 24 : 25 : 26 : 27
# define CONFIG_BOOTCOMMAND "tftp 20800000 zImage35 \; go 20800000"
# define CONFIG_BOOTARGS "root=/de/nfs nfsroot=192.168.7.2:/opt/filesystem ip=192.168.7.6 console=ttySAC0,115200 init=/linuxrc"
插曲:函数指针
1,声明定义
int * fun( int a, int b);
int ( *fun)( int a, int b);
2,初始化
int add( int a, int b)
{
return a +b;
}
int sub( int a, int b)
{
return a -b;
}
//fun = add;
fun = sub;
3,调用
fun( 3, 4);
4,作用
a,产生api
b,用于抽象分层
struct stud{
int age;
int ( *func)( int a, int b);
}
app
查询 : a的名字
printf( "age = %d\n", p - >age);
p - >func( 3, 4);
== == == == == == == == == == == == == == == == == == == == == == == =
(核心层)链表 :
struct stud *p; (全局)
p = 链表头;
== == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == =
(特定数据层) struct stud a;
a.age = 30000;
a.func = add;
struct stud b;
b.age = 3;
b.func = sub;
int * fun( int a, int b);
int ( *fun)( int a, int b);
2,初始化
int add( int a, int b)
{
return a +b;
}
int sub( int a, int b)
{
return a -b;
}
//fun = add;
fun = sub;
3,调用
fun( 3, 4);
4,作用
a,产生api
b,用于抽象分层
struct stud{
int age;
int ( *func)( int a, int b);
}
app
查询 : a的名字
printf( "age = %d\n", p - >age);
p - >func( 3, 4);
== == == == == == == == == == == == == == == == == == == == == == == =
(核心层)链表 :
struct stud *p; (全局)
p = 链表头;
== == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == == =
(特定数据层) struct stud a;
a.age = 30000;
a.func = add;
struct stud b;
b.age = 3;
b.func = sub;
nandflash的初始化;
void
start_armboot (
void)
|
nand_init();
|Nand.c drivers\mtd\Nand 2677 2010 - 4 - 1
nand_init_chip( &nand_info[i], &nand_chip[i], base_address[i]);
|( struct mtd_info *mtd, struct nand_chip *nand,ulong base_addr)
mtd - >priv = nand;
board_nand_init(nand) // 初始化nand_chip对象
|
nand - >IO_ADDR_R = ( void __iomem *)NFDATA;
nand - >IO_ADDR_W = ( void __iomem *)NFDATA;
nand - >cmd_ctrl = s3c_nand_hwcontrol;
nand - >dev_ready = s3c_nand_device_ready;
nand - >select_chip = s3c_nand_select_chip;
nand - >options = 0;
nand_scan(mtd, maxchips) // 初始化struct nand_info
readenv
|
nand_read(
info - >read() // 谁给这个read函数指针初始化
- >read = xxx
初始化部分:
nand_scan
|
nand_scan_tail(mtd);
| //在这个地方给初始化了
mtd - >read = nand_read; // Nand_base.c drivers\mtd\Nand 81953 2010-4-1
|
struct nand_chip *chip = mtd - >priv;
nand_do_read_ops(mtd, from, &chip - >ops);
|
chip - >select_chip(mtd, chipnr); //select_chip在哪里初始化
nand_scan
|
nand_scan_ident(mtd, maxchips);
| // 片选在这个初始化了
chip - >select_chip = nand_select_chip;
| //chip实际就是struct nand_chip,
chip - >cmd_ctrl(mtd, NAND_CMD_NONE, 0 | NAND_CTRL_CHANGE);
|
s3c_nand_hwcontrol;
board_nand_init(nand) // 初始化nand_chip对象,
|
nand - >IO_ADDR_R = ( void __iomem *)NFDATA;
nand - >IO_ADDR_W = ( void __iomem *)NFDATA;
nand - >cmd_ctrl = s3c_nand_hwcontrol;
nand - >dev_ready = s3c_nand_device_ready;
nand - >select_chip = s3c_nand_select_chip;
nand - >options = 0;
|
nand_init();
|Nand.c drivers\mtd\Nand 2677 2010 - 4 - 1
nand_init_chip( &nand_info[i], &nand_chip[i], base_address[i]);
|( struct mtd_info *mtd, struct nand_chip *nand,ulong base_addr)
mtd - >priv = nand;
board_nand_init(nand) // 初始化nand_chip对象
|
nand - >IO_ADDR_R = ( void __iomem *)NFDATA;
nand - >IO_ADDR_W = ( void __iomem *)NFDATA;
nand - >cmd_ctrl = s3c_nand_hwcontrol;
nand - >dev_ready = s3c_nand_device_ready;
nand - >select_chip = s3c_nand_select_chip;
nand - >options = 0;
nand_scan(mtd, maxchips) // 初始化struct nand_info
readenv
|
nand_read(
info - >read() // 谁给这个read函数指针初始化
- >read = xxx
初始化部分:
nand_scan
|
nand_scan_tail(mtd);
| //在这个地方给初始化了
mtd - >read = nand_read; // Nand_base.c drivers\mtd\Nand 81953 2010-4-1
|
struct nand_chip *chip = mtd - >priv;
nand_do_read_ops(mtd, from, &chip - >ops);
|
chip - >select_chip(mtd, chipnr); //select_chip在哪里初始化
nand_scan
|
nand_scan_ident(mtd, maxchips);
| // 片选在这个初始化了
chip - >select_chip = nand_select_chip;
| //chip实际就是struct nand_chip,
chip - >cmd_ctrl(mtd, NAND_CMD_NONE, 0 | NAND_CTRL_CHANGE);
|
s3c_nand_hwcontrol;
board_nand_init(nand) // 初始化nand_chip对象,
|
nand - >IO_ADDR_R = ( void __iomem *)NFDATA;
nand - >IO_ADDR_W = ( void __iomem *)NFDATA;
nand - >cmd_ctrl = s3c_nand_hwcontrol;
nand - >dev_ready = s3c_nand_device_ready;
nand - >select_chip = s3c_nand_select_chip;
nand - >options = 0;
uboot命令处理的逻辑过程
struct
cmd_tbl_s {
char *name; /* Command Name */
int maxargs; /* maximum number of arguments */
int repeatable; /* autorepeat allowed? */
/* Implementation function */
int ( *cmd)( struct cmd_tbl_s *, int, int, char *[]);
char *usage; /* Usage message (short) */
char *help; /* Help message (long) */
};
typedef struct cmd_tbl_s cmd_tbl_t;
# define U_BOOT_CMD(name,maxargs,rep,cmd,usage,help) \
cmd_tbl_t __u_boot_cmd_##name Struct_Section = {#name, maxargs, rep, cmd, usage, help}
# define Struct_Section __attribute__ ((unused,section ( ".u_boot_cmd")))
U_BOOT_CMD(
tftpboot, 3, 1, do_tftpb,
"boot image via network using TFTP protocol",
"[loadAddress] [[hostIPaddr:]bootfilename]"
);
== = >展开 :
类型 变量名 设置属性
struct cmd_tbl_s __u_boot_cmd_tftpboot __attribute__ ((unused,section ( ".u_boot_cmd"))) ={
.name = "tftpboot",
.maxargs = 3,
.repeatable = 1,
.cmd = do_tftpb,
.usage = "boot image via network using TFTP protocol",
.help = "[loadAddress] [[hostIPaddr:]bootfilename]"
}
== = > 在uboot中新增一条命令 :
common/cmd_hello.c
# include <common.h >
# include <command.h >
int do_mycmd(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[])
{
printf( "in do_mycmd for uboot cmd test\n");
return 0;
}
U_BOOT_CMD(
mycmd, 3, 1, do_mycmd,
"this is a uboot cmd test",
"mycmd : no args"
);
common/Makefile
COBJS -$(CONFIG_CMD_HELLO) += cmd_hello.o
smdkc100.h
# define CONFIG_CMD_HELLO 1
char *name; /* Command Name */
int maxargs; /* maximum number of arguments */
int repeatable; /* autorepeat allowed? */
/* Implementation function */
int ( *cmd)( struct cmd_tbl_s *, int, int, char *[]);
char *usage; /* Usage message (short) */
char *help; /* Help message (long) */
};
typedef struct cmd_tbl_s cmd_tbl_t;
# define U_BOOT_CMD(name,maxargs,rep,cmd,usage,help) \
cmd_tbl_t __u_boot_cmd_##name Struct_Section = {#name, maxargs, rep, cmd, usage, help}
# define Struct_Section __attribute__ ((unused,section ( ".u_boot_cmd")))
U_BOOT_CMD(
tftpboot, 3, 1, do_tftpb,
"boot image via network using TFTP protocol",
"[loadAddress] [[hostIPaddr:]bootfilename]"
);
== = >展开 :
类型 变量名 设置属性
struct cmd_tbl_s __u_boot_cmd_tftpboot __attribute__ ((unused,section ( ".u_boot_cmd"))) ={
.name = "tftpboot",
.maxargs = 3,
.repeatable = 1,
.cmd = do_tftpb,
.usage = "boot image via network using TFTP protocol",
.help = "[loadAddress] [[hostIPaddr:]bootfilename]"
}
== = > 在uboot中新增一条命令 :
common/cmd_hello.c
# include <common.h >
# include <command.h >
int do_mycmd(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[])
{
printf( "in do_mycmd for uboot cmd test\n");
return 0;
}
U_BOOT_CMD(
mycmd, 3, 1, do_mycmd,
"this is a uboot cmd test",
"mycmd : no args"
);
common/Makefile
COBJS -$(CONFIG_CMD_HELLO) += cmd_hello.o
smdkc100.h
# define CONFIG_CMD_HELLO 1
uboot命令解析过程
mainloop:(一般不需要去修改)
s
= getenv (
"bootdelay");
//获取环境变量的值(字符串)
bootdelay = s ? ( int)simple_strtol(s, NULL, 10) : CONFIG_BOOTDELAY;
s = getenv ( "bootcmd"); //获取bootcmd中值==>"tftp 20008000 zImage ; go 20008000"
if (bootdelay > = 0 && s && !abortboot (bootdelay)) // 倒计时
run_command (s, 0);
|
分析字符串中命令 : 命令名 参数tftp 20008000 zImage
argc = > 3
argv ==argv[ 0] == "tftp"
argv[ 1] == "20008000"
argv[ 2] == "zImage"
argc = parse_line (finaltoken, argv);
cmd_tbl_t *cmdtp = find_cmd(argv[ 0]);
|
find_cmd_tbl(cmd, &__u_boot_cmd_start, len);
| // cmdtp为指针,执行.u_boot_cmd段的起始位置
for (cmdtp = table; cmdtp != table + table_len;cmdtp ++)
if (strncmp (cmd, cmdtp - >name, len)
return cmdtp;
(cmdtp - >cmd) (cmdtp, flag, argc, argv) // 执行命令的处理函数
倒计时被打断的时候 :
for (;;) {
len = readline (CONFIG_SYS_PROMPT);
rc = run_command (lastcommand, flag);
bootdelay = s ? ( int)simple_strtol(s, NULL, 10) : CONFIG_BOOTDELAY;
s = getenv ( "bootcmd"); //获取bootcmd中值==>"tftp 20008000 zImage ; go 20008000"
if (bootdelay > = 0 && s && !abortboot (bootdelay)) // 倒计时
run_command (s, 0);
|
分析字符串中命令 : 命令名 参数tftp 20008000 zImage
argc = > 3
argv ==argv[ 0] == "tftp"
argv[ 1] == "20008000"
argv[ 2] == "zImage"
argc = parse_line (finaltoken, argv);
cmd_tbl_t *cmdtp = find_cmd(argv[ 0]);
|
find_cmd_tbl(cmd, &__u_boot_cmd_start, len);
| // cmdtp为指针,执行.u_boot_cmd段的起始位置
for (cmdtp = table; cmdtp != table + table_len;cmdtp ++)
if (strncmp (cmd, cmdtp - >name, len)
return cmdtp;
(cmdtp - >cmd) (cmdtp, flag, argc, argv) // 执行命令的处理函数
倒计时被打断的时候 :
for (;;) {
len = readline (CONFIG_SYS_PROMPT);
rc = run_command (lastcommand, flag);
掌握:
1, 在uboot添加命令
2, 已知的命令对应的处理函数
nand 命令==> cmd_nand.c
do_nand
dm9000网卡:
void start_armboot (
void)
|
eth_initialize(gd - >bd); // 没有调用所有网卡的init方法
|
dm9000_initialize(bis) // 自己添加,将dm9000的对象初始化,并且设置mac地址,加入链表
eth_getenv_enetaddr_by_index(eth_number, env_enetaddr);
//从环境变量中获取,某个网卡的mac地址, mac从软件上设定的
// mac保存在env_enetaddr
eth_init(gd - >bd); // Eth.c Net 11013 2013-9-10
// 意味着链表中多有的节点都会执行其中的init方法
|
while循环 :
eth_current - >init(eth_current,bis) // 执行当前的节点的init方法
eth_try_another( 0);
|
eth_current = eth_current - >next;
1,dm9000 == >链表中
dm9000_initialize(bis) ;
2,执行dm9000的init方法
eth_init(gd - >bd);
COBJS -$(CONFIG_DRIVER_DM9000) += dm9000x.o
struct eth_device {
char name[NAMESIZE]; // 网卡名字
unsigned char enetaddr[ 6]; //网卡mac地址
int iobase; //网卡的物理地址
int state; //网卡状态
int ( *init) ( struct eth_device *, bd_t *); // 初始化方法
int ( *send) ( struct eth_device *, volatile void * packet, int length); // 发送
int ( *recv) ( struct eth_device *); //接收
void ( *halt) ( struct eth_device *); // 终止
struct eth_device *next;
void *priv;
};
int dm9000_initialize(bd_t *bis)
{
struct eth_device *dev = &(dm9000_info.netdev);
/* Load MAC address from EEPROM */
dm9000_get_enetaddr(dev);
dev - >init = dm9000_init;
dev - >halt = dm9000_halt;
dev - >send = dm9000_send;
dev - >recv = dm9000_rx;
sprintf(dev - >name, "dm9000");
eth_register(dev); // 将dm9000节点放到链表中
return 0;
}
|
eth_initialize(gd - >bd); // 没有调用所有网卡的init方法
|
dm9000_initialize(bis) // 自己添加,将dm9000的对象初始化,并且设置mac地址,加入链表
eth_getenv_enetaddr_by_index(eth_number, env_enetaddr);
//从环境变量中获取,某个网卡的mac地址, mac从软件上设定的
// mac保存在env_enetaddr
eth_init(gd - >bd); // Eth.c Net 11013 2013-9-10
// 意味着链表中多有的节点都会执行其中的init方法
|
while循环 :
eth_current - >init(eth_current,bis) // 执行当前的节点的init方法
eth_try_another( 0);
|
eth_current = eth_current - >next;
1,dm9000 == >链表中
dm9000_initialize(bis) ;
2,执行dm9000的init方法
eth_init(gd - >bd);
COBJS -$(CONFIG_DRIVER_DM9000) += dm9000x.o
struct eth_device {
char name[NAMESIZE]; // 网卡名字
unsigned char enetaddr[ 6]; //网卡mac地址
int iobase; //网卡的物理地址
int state; //网卡状态
int ( *init) ( struct eth_device *, bd_t *); // 初始化方法
int ( *send) ( struct eth_device *, volatile void * packet, int length); // 发送
int ( *recv) ( struct eth_device *); //接收
void ( *halt) ( struct eth_device *); // 终止
struct eth_device *next;
void *priv;
};
int dm9000_initialize(bd_t *bis)
{
struct eth_device *dev = &(dm9000_info.netdev);
/* Load MAC address from EEPROM */
dm9000_get_enetaddr(dev);
dev - >init = dm9000_init;
dev - >halt = dm9000_halt;
dev - >send = dm9000_send;
dev - >recv = dm9000_rx;
sprintf(dev - >name, "dm9000");
eth_register(dev); // 将dm9000节点放到链表中
return 0;
}
uboot是如何启动内核
1, 在0x20000100去存放内存的信息和bootargs的内容
2, 将r1=1826,告诉内核
bootm
--
>uImage
tftp 20800000 uImage \; bootm 20800000
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000+0x100
bootm == >do_bootm
|
将zImage拷贝到0x20008000
boot_fn = boot_os[images.os.os];
|
do_bootm_linux //Bootm.c (lib_arm):int do_bootm_linux
| //gd->bd->bi_arch_number = MACH_TYPE_SMDKC100; 1826
bd_t *bd = gd - >bd;
int machid = bd - >bi_arch_number;
void ( *theKernel)( int zero, int arch, uint params);
char *commandline = getenv ( "bootargs");
theKernel = ( void ( *)( int, int, uint))images - >ep; // 0x20008000
setup_start_tag (bd);t
setup_memory_tags (bd);
setup_commandline_tag (bd, commandline);
setup_end_tag (bd);
theKernel ( 0, machid, bd - >bi_boot_params);
tftp 20800000 uImage \; bootm 20800000
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000+0x100
bootm == >do_bootm
|
将zImage拷贝到0x20008000
boot_fn = boot_os[images.os.os];
|
do_bootm_linux //Bootm.c (lib_arm):int do_bootm_linux
| //gd->bd->bi_arch_number = MACH_TYPE_SMDKC100; 1826
bd_t *bd = gd - >bd;
int machid = bd - >bi_arch_number;
void ( *theKernel)( int zero, int arch, uint params);
char *commandline = getenv ( "bootargs");
theKernel = ( void ( *)( int, int, uint))images - >ep; // 0x20008000
setup_start_tag (bd);t
setup_memory_tags (bd);
setup_commandline_tag (bd, commandline);
setup_end_tag (bd);
theKernel ( 0, machid, bd - >bi_boot_params);
全局的数据:gd
DECLARE_GLOBAL_DATA_PTR;
# define DECLARE_GLOBAL_DATA_PTR register volatile gd_t *gd asm ( "r8")
某个.c中想使用gd变量 : 加上这句话
DECLARE_GLOBAL_DATA_PTR;
gd - >flags |= GD_FLG_RELOC;
board_init
|
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000 + 0x100
env_init
|
gd - >env_addr = (ulong) &default_environment[ 0];
gd - >env_valid = 1;
init_baudrate
|
gd - >bd - >bi_baudrate = gd - >baudrate = 115200;
serial_init == >drivers /serial /serial_s5pc1xx.c // 一般uboot对于串口的部分,都基本上是ok
int serial_init_dev( const int dev_index)
{
struct s5pc1xx_uart * const uart = s5pc1xx_get_base_uart(dev_index);
/* reset and enable FIFOs, set triggers to the maximum */
writel( 0, &uart - >ufcon);
writel( 0, &uart - >umcon);
/* 8N1 */
writel(0x3, &uart - >ulcon);
/* No interrupts, no DMA, pure polling */
writel(0x245, &uart - >ucon);
serial_setbrg_dev(dev_index);
return 0;
}
gd - >have_console = 1;
dram_init :
gd - >bd - >bi_dram[ 0].start = PHYS_SDRAM_1; //起始位置
gd - >bd - >bi_dram[ 0].size = get_ram_size(( long *)PHYS_SDRAM_1,PHYS_SDRAM_1_SIZE); // 计算内存大小
= 256 * 1024 * 1024
汇总:
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826, 机器id, uboot和内核达成的一个协议
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000 + 0x100
gd - >bd - >bi_baudrate = gd - >baudrate = 115200;
gd - >bd - >bi_dram[ 0].start = PHYS_SDRAM_1;
gd - >bd - >bi_dram[ 0].size = 256 * 1024 * 1024;
gd - >have_console = 1;
gd - >flags |= GD_FLG_RELOC;
gd - >bd - >bi_ip_addr = getenv_IPaddr ( "ipaddr");
# define DECLARE_GLOBAL_DATA_PTR register volatile gd_t *gd asm ( "r8")
某个.c中想使用gd变量 : 加上这句话
DECLARE_GLOBAL_DATA_PTR;
gd - >flags |= GD_FLG_RELOC;
board_init
|
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000 + 0x100
env_init
|
gd - >env_addr = (ulong) &default_environment[ 0];
gd - >env_valid = 1;
init_baudrate
|
gd - >bd - >bi_baudrate = gd - >baudrate = 115200;
serial_init == >drivers /serial /serial_s5pc1xx.c // 一般uboot对于串口的部分,都基本上是ok
int serial_init_dev( const int dev_index)
{
struct s5pc1xx_uart * const uart = s5pc1xx_get_base_uart(dev_index);
/* reset and enable FIFOs, set triggers to the maximum */
writel( 0, &uart - >ufcon);
writel( 0, &uart - >umcon);
/* 8N1 */
writel(0x3, &uart - >ulcon);
/* No interrupts, no DMA, pure polling */
writel(0x245, &uart - >ucon);
serial_setbrg_dev(dev_index);
return 0;
}
gd - >have_console = 1;
dram_init :
gd - >bd - >bi_dram[ 0].start = PHYS_SDRAM_1; //起始位置
gd - >bd - >bi_dram[ 0].size = get_ram_size(( long *)PHYS_SDRAM_1,PHYS_SDRAM_1_SIZE); // 计算内存大小
= 256 * 1024 * 1024
汇总:
gd - >bd - >bi_arch_number = MACH_TYPE_SMDKC100; // 1826, 机器id, uboot和内核达成的一个协议
gd - >bd - >bi_boot_params = PHYS_SDRAM_1 + 0x100; // 0x20000000 + 0x100
gd - >bd - >bi_baudrate = gd - >baudrate = 115200;
gd - >bd - >bi_dram[ 0].start = PHYS_SDRAM_1;
gd - >bd - >bi_dram[ 0].size = 256 * 1024 * 1024;
gd - >have_console = 1;
gd - >flags |= GD_FLG_RELOC;
gd - >bd - >bi_ip_addr = getenv_IPaddr ( "ipaddr");
串口的初始化
//串口的初始化, 将所有的串口设备做成对象 struct serial_device, 用链表连接起来
serial_initialize();
//将所有的外围设备全部做成对象 struct stdio_dev, 如果想要研究uboot中有lcd,研究这块
stdio_init (); /* get the devices list going. */
// 跳转表
jumptable_init ();
// 将stdin, out, err==> serial
console_init_r (); /* fully init console as a device */
/* enable exceptions */
enable_interrupts ();
serial_initialize();
//将所有的外围设备全部做成对象 struct stdio_dev, 如果想要研究uboot中有lcd,研究这块
stdio_init (); /* get the devices list going. */
// 跳转表
jumptable_init ();
// 将stdin, out, err==> serial
console_init_r (); /* fully init console as a device */
/* enable exceptions */
enable_interrupts ();
smdkc100所有平台数据的注册流程
static
int __init customize_machine(
void)
{
/* customizes platform devices, or adds new ones */
if (init_machine)
init_machine();
return 0;
}
arch_initcall(customize_machine);
smdkc100_machine_init
|
platform_add_devices(smdkc100_devices, ARRAY_SIZE(smdkc100_devices));
|
platform_device_register(devs[i]);
init /main.c
start_kernel
|
printk(KERN_NOTICE "%s", linux_banner);
setup_arch( &command_line); // 建立平台相关的数据,会到0x200000100去uboot存放数据
|
mdesc = setup_machine(machine_arch_type); // 获取machine描述
//struct machine_desc *mdesc===>mach-smdkc100.c==>MACHINE_START
mdesc - >boot_params; //获取0x20000100
tags = phys_to_virt(mdesc - >boot_params);
parse_tags(tags); // 获取bootargs, from就在这里初始化
strlcpy(boot_command_line, from, COMMAND_LINE_SIZE);
printk(KERN_NOTICE "Kernel command line: %s\n", boot_command_line);
{
/* customizes platform devices, or adds new ones */
if (init_machine)
init_machine();
return 0;
}
arch_initcall(customize_machine);
smdkc100_machine_init
|
platform_add_devices(smdkc100_devices, ARRAY_SIZE(smdkc100_devices));
|
platform_device_register(devs[i]);
init /main.c
start_kernel
|
printk(KERN_NOTICE "%s", linux_banner);
setup_arch( &command_line); // 建立平台相关的数据,会到0x200000100去uboot存放数据
|
mdesc = setup_machine(machine_arch_type); // 获取machine描述
//struct machine_desc *mdesc===>mach-smdkc100.c==>MACHINE_START
mdesc - >boot_params; //获取0x20000100
tags = phys_to_virt(mdesc - >boot_params);
parse_tags(tags); // 获取bootargs, from就在这里初始化
strlcpy(boot_command_line, from, COMMAND_LINE_SIZE);
printk(KERN_NOTICE "Kernel command line: %s\n", boot_command_line);
内核是如何去处理bootargs中的所有参数:
parse_args(
"Booting kernel", static_command_line, __start___param,__stop___param
- __start___param,
&unknown_bootoption);
用途 :
uboot想传递一个自定义的值给我们内核,内核如何处理 :
set bootargs myval = 56 init = /linuxrc console =ttySAC0, 115200 root = /dev /nfs nfsroot = 192. 168. 7. 2 : /opt /filesystem ip = 192. 168. 7. 6
在内核的任何地方 :
static int __init parse_myval( char *str)
{
int val = simple_strtoul(str, NULL, 10);
printk( "myval = %d\n", val);
return 0;
}
__setup( "myval=", parse_myval);
&unknown_bootoption);
用途 :
uboot想传递一个自定义的值给我们内核,内核如何处理 :
set bootargs myval = 56 init = /linuxrc console =ttySAC0, 115200 root = /dev /nfs nfsroot = 192. 168. 7. 2 : /opt /filesystem ip = 192. 168. 7. 6
在内核的任何地方 :
static int __init parse_myval( char *str)
{
int val = simple_strtoul(str, NULL, 10);
printk( "myval = %d\n", val);
return 0;
}
__setup( "myval=", parse_myval);
uboot上电完整内存使用
@成鹏致远
(blogs:http://lcw.cnblogs.com)
(email:[email protected])
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