[TI-Sitara]启动流程

时间:2023-03-09 17:14:40
[TI-Sitara]启动流程

前段时间在准备AM437x启动相关的一些事情,对MLO、SPL等事情也是有些糊涂,于是分享下面这篇文章

转自http://blog.****.net/psvoldemort/article/details/41861959

参考文件

1,AM335x ARM Cortex-A8 Microprocessors (MPUs) Technical Reference Manual.pdf;

2,am3359.pdf;

目录

  • 1.am335x的cpu上电后,会跳到哪个地址去执行?
  • 1.1.第一级 bootloader:
  • 1.2.第二级 bootloader:
  • 1.3.第三级 bootloader:
  • 2.第二级 bootloader:MLO(SPL)做了哪些事情?
  • 2.1.SPL内存重映射
  • 2.2.保存启动参数 bl    save_boot_params
  • 2.3.设置 CPU 为 SVC32 模式
  • 2.4.CPU的初始化
  • 2.5.执行 s_init() 函数,实现 CPU 的初始化
  • 2.6.使能第二级缓冲区
  • 2.7.关闭看门狗(WDT)
  • 2.8.给外设设置好 PLL 和 时钟频率等
  • 2.9.使能 32-KHz 频率的实时时钟
  • 2.10.使能UART0
  • 2.11.初始化 定时器
  • 2.12.初始化控制台,通过UART可以查看相关信息
  • 2.13.配置 DDR
  • 2.14.设置 internal RAM 内存空间的栈指针,调用 board_init_f()函数
  • 2.15.代码重定向
  • 2.16.清空 bss 段
  • 2.17.调用函数 board_init_r,用以完成 MLO(SPI)阶段的所有初始化,并跳转到 uboot.img 阶段
  • 3.第三级 bootloader:uboot.img 做了哪些事情?

1.am335x的cpu上电后,会跳到哪个地址去执行?

答:芯片到uboot启动流程 :Internal-ROM → MLO(SPL)→ uboot.img

AM335x 中bootloader被分成了 3 个部分

1.1.第一级 bootloader:

引导加载程序,板子上电后会自动执行这些代码,如选择哪种方式启动(NAND,SDcard,UART。。。),然后跳转转到第二级 bootloader。这些代码应该是存放在 176KB 的 ROM 中。

[TI-Sitara]启动流程

[TI-Sitara]启动流程

1.2.第二级 bootloader:

MLO(SPL),用以硬件初始化:关闭看门狗,关闭中断,设置 CPU 时钟频率、速度等操作。然后会跳转到第三级bootloader。MLO文件应该会被映射到 64 KB的 Internal SRAM 中。

[TI-Sitara]启动流程

1.3.第三级 bootloader:

uboot.img,C代码的入口。

[TI-Sitara]启动流程

其中第一级 bootloader 是板子固化的,第二级和第三级是通过编译 uboot 所得的。

[TI-Sitara]启动流程[TI-Sitara]启动流程

2.第二级 bootloader:MLO(SPL)做了哪些事情?

MLO(SPL)内存分布如下:

[TI-Sitara]启动流程

2.1.SPL内存重映射

< PATH : /arch/arm/cpu/armv7/omap-common/u-boot-spl.lds >

MEMORY { .sram : ORIGIN = CONFIG_SPL_TEXT_BASE,\

        LENGTH = CONFIG_SPL_MAX_SIZE }

MEMORY { .sdram : ORIGIN = CONFIG_SPL_BSS_START_ADDR, \

        LENGTH = CONFIG_SPL_BSS_MAX_SIZE }

OUTPUT_FORMAT("elf32-littlearm", "elf32-littlearm", "elf32-littlearm")

OUTPUT_ARCH(arm)

ENTRY(_start)

SECTIONS

{

    .text      :

    {

    __start = .;

      arch/arm/cpu/armv7/start.o    (.text)

      *(.text*)

    } >.sram

    . = ALIGN();

    .rodata : { *(SORT_BY_ALIGNMENT(.rodata*)) } >.sram

    . = ALIGN();

    .data : { *(SORT_BY_ALIGNMENT(.data*)) } >.sram

    . = ALIGN();

    __image_copy_end = .;

    _end = .;

    .bss :

    {

        . = ALIGN();

        __bss_start = .;

        *(.bss*)

        . = ALIGN();

        __bss_end__ = .;

    } >.sdram

}
<PATH : /include/configs/am335x_evm.h>

#define CONFIG_SPL_TEXT_BASE        0x402F0400

#define CONFIG_SPL_MAX_SIZE     (46 * 1024)

#define CONFIG_SPL_STACK        LOW_LEVEL_SRAM_STACK

#define CONFIG_SPL_BSS_START_ADDR   0x80000000

#define CONFIG_SPL_BSS_MAX_SIZE     0x80000     /* 512 KB */ <span style="font-size:16px;color:#003399;"><strong></strong></span>

2.2.保存启动参数 bl    save_boot_params 

<PATH : /arch/arm/cpu/armv7/start.S>

/*

 * the actual reset code

 */

reset:

    bl  save_boot_params
<PATH : /arch/arm/cpu/armv7/omap-common/lowlevel_init.S>

.global save_boot_params

save_boot_params:

    /*

     * See if the rom code passed pointer is valid:

     * It is not valid if it is not in non-secure SRAM

     * This may happen if you are booting with the help of

     * debugger

     */

    ldr     r2, =NON_SECURE_SRAM_START

    cmp r2, r0

    bgt 1f

    ldr r2, =NON_SECURE_SRAM_END

    cmp r2, r0

    blt 1f

    /*

     * store the boot params passed from rom code or saved

     * and passed by SPL

     */

    cmp r0, #

    beq 1f

    ldr r1, =boot_params

    str r0, [r1]
/*《PATH: /arch/arm/include/asm/arch-ti81xx/omap.h》

 * Non-secure SRAM Addresses

 * Non-secure RAM starts at 0x40300000 for GP devices. But we keep SRAM_BASE

 * at 0x40304000(EMU base) so that our code works for both EMU and GP

 */

#define NON_SECURE_SRAM_START   0x40304000

#define NON_SECURE_SRAM_END 0x4030E000

#define LOW_LEVEL_SRAM_STACK    0x4030B7FC
问题:这些参数是保存在哪里的?大概有哪些参数?

答:这些参数保存的内存地址为 64 KB 的 OCM RAM 中:

[TI-Sitara]启动流程

[TI-Sitara]启动流程

注:Dowloaded Image 区域:是用来保存 MLO(SPL) 文件的,其最大可达到 109 KB

[TI-Sitara]启动流程[TI-Sitara]启动流程

[TI-Sitara]启动流程[TI-Sitara]启动流程

2.3.设置 CPU 为 SVC32 模式

    <PATH :/arch/arm/cpu/armv7/start.S>

        /*

     * set the cpu to SVC32 mode

     */

    mrs r0, cpsr

    bic r0, r0, #0x1f

    orr r0, r0, #0xd3

    msr cpsr,r0
  • CPSR:程序状态寄存器(current program status register)(当前程序状态寄存器),在任何处理器模式下被访问。它包含了条件标志位、中断禁止位、当前处理器模式标志以及其他的一些控制和状态位。

CPSR在用户级编程时用于存储条件码。

  • SPSR:程序状态保存寄存器(saved program statusregister),每一种处理器模式下都有一个状态寄存器SPSR,SPSR用于保存CPSR的状态,以便异常返回后恢复异常发生时的工作状态。当特定的异常中断发生时,这个寄存器用于存放当前程序状态寄存器的内容。在异常中断退出时,可以用SPSR来恢复CPSR。由于用户模式和系统模式不是异常中断模式,所以他没有SPSR。当用户在用户模式或系统模式访问SPSR,将产生不可预知的后果。

详解:http://blog.chinaunix.net/uid-28458801-id-3487199.html

2.4.CPU的初始化

《PATH : /arch/arm/cpu/armv7/start.S》

    /* the mask ROM code should have PLL and others stable */

#ifndef CONFIG_SKIP_LOWLEVEL_INIT

    bl  cpu_init_crit

#endif


<PATH : /arch/arm/cpu/armv7/omap-common/lowlevel_init.S>


.globl lowlevel_init

lowlevel_init:

    /*

     * Setup a temporary stack

     */

    ldr sp, =LOW_LEVEL_SRAM_STACK

    /*

     * Save the old lr(passed in ip) and the current lr to stack

     */

    push    {ip, lr}

    /*

     * go setup pll, mux, memory

     */

    bl  s_init

    pop {ip, pc}








问题:CPU的初始化有哪些内容?


答:@b1@ 首先要设置堆栈区,因为将会调用 C函数来实现CPU的初始化


问题:这个堆栈在什么位置,其内存大小是多少?


答:




《PATH :/arch/arm/include/asm/arch-ti81xx/omap.h》

#define LOW_LEVEL_SRAM_STACK    0x4030B7FC<strong></strong>




[TI-Sitara]启动流程


[TI-Sitara]启动流程


2.5.执行 s_init() 函数,实现 CPU 的初始化




<PATH : /board/ti/am335x/evm.c>

/*

 * early system init of muxing and clocks.

 */

void s_init(void)

{

    /* Can be removed as A8 comes up with L2 enabled */

    l2_cache_enable();

    /* WDT1 is already running when the bootloader gets control

     * Disable it to avoid "random" resets

     */

    __raw_writel(0xAAAA, WDT_WSPR);

    while(__raw_readl(WDT_WWPS) != 0x0);

    __raw_writel(0x5555, WDT_WSPR);

    while(__raw_readl(WDT_WWPS) != 0x0);

#ifdef CONFIG_SPL_BUILD

    /* Setup the PLLs and the clocks for the peripherals */

    pll_init();

    /* Enable RTC32K clock */

    rtc32k_enable();

    /* UART softreset */

    u32 regVal;

    u32 uart_base = DEFAULT_UART_BASE;

    enable_uart0_pin_mux();

    /* IA Motor Control Board has default console on UART3*/

    /* XXX: This is before we've probed / set board_id */

    if (board_id == IA_BOARD) {

        uart_base = UART3_BASE;

    }

    regVal = __raw_readl(uart_base + UART_SYSCFG_OFFSET);

    regVal |= UART_RESET;

    __raw_writel(regVal, (uart_base + UART_SYSCFG_OFFSET) );

    while ((__raw_readl(uart_base + UART_SYSSTS_OFFSET) &

            UART_CLK_RUNNING_MASK) != UART_CLK_RUNNING_MASK);

    /* Disable smart idle */

    regVal = __raw_readl((uart_base + UART_SYSCFG_OFFSET));

    regVal |= UART_SMART_IDLE_EN;

    __raw_writel(regVal, (uart_base + UART_SYSCFG_OFFSET));

    /* Initialize the Timer */

    init_timer();

    preloader_console_init();

    printf("\nlocation /board/ti/am335x\n");        //@@

/*@@*/

//  led();

/*@@*/

    config_am335x_ddr();

#endif

}




2.6.使能第二级缓冲区




/* Can be removed as A8 comes up with L2 enabled */

l2_cache_enable();

<PATH : /arch/arm/cpu/armv7/ti81xx/cache.S>

l2_cache_enable:

    push    {r0, r1, r2, lr}

    mrc , , r3, cr1, cr0,

    orr r3, r3, #

    mcr , , r3, cr1, cr0,

    pop {r1, r2, r3, pc}




[TI-Sitara]启动流程


2.7.关闭看门狗(WDT)




/* WDT1 is already running when the bootloader gets control

 * Disable it to avoid "random" resets

 */

__raw_writel(0xAAAA, WDT_WSPR);

while(__raw_readl(WDT_WWPS) != 0x0);

__raw_writel(0x5555, WDT_WSPR);

while(__raw_readl(WDT_WWPS) != 0x0);










<PATH : /arch/arm/include/asm/arch-ti81xx/cpu.h>

#define WDT_WSPR    (WDT_BASE + 0x048)

<PATH : /arch/arm/include/asm/arch-ti81xx/hardware.h>

/* Watchdog Timer */

#ifdef CONFIG_AM335X

#define WDT_BASE            0x44E35000

#else

#define WDT_BASE            0x480C2000

#endif








[TI-Sitara]启动流程[TI-Sitara]启动流程


[TI-Sitara]启动流程


2.8.给外设设置好 PLL 和 时钟频率等




/* Setup the PLLs and the clocks for the peripherals */

pll_init();

<PATH : /board/ti/am335x/pll.c>

/*

 * Configure the PLL/PRCM for necessary peripherals

 */

void pll_init()

{

    mpu_pll_config(MPUPLL_M_500);

    core_pll_config();

    per_pll_config();

    ddr_pll_config();

    /* Enable the required interconnect clocks */

    interface_clocks_enable();

    /* Enable power domain transition */

    power_domain_transition_enable();

    /* Enable the required peripherals */

    per_clocks_enable();

}




[TI-Sitara]启动流程


2.9.使能 32-KHz 频率的实时时钟




/* Enable RTC32K clock */

rtc32k_enable();

 《PATH : /board/ti/am335x/evm.c》

static void rtc32k_enable(void)

{

    /* Unlock the rtc's registers */

    __raw_writel(0x83e70b13, (AM335X_RTC_BASE + RTC_KICK0_REG));

    __raw_writel(0x95a4f1e0, (AM335X_RTC_BASE + RTC_KICK1_REG));

    /* Enable the RTC 32K OSC */

    __raw_writel(0x48, (AM335X_RTC_BASE + RTC_OSC_REG));

}

<PATH : /arch/arm/include/asm/arch-ti81xx/hardware.h>

/* RTC base address */

#define AM335X_RTC_BASE            0x44E3E000

<PATH : /board/ti/am335x/evm.c>

#define RTC_KICK0_REG        0x6c

#define RTC_KICK1_REG        0x70

#define RTC_OSC_REG        0x54




[TI-Sitara]启动流程


2.10.使能UART0




  /* UART softreset */

    u32 regVal;

    u32 uart_base = DEFAULT_UART_BASE;

    enable_uart0_pin_mux();

    /* IA Motor Control Board has default console on UART3*/

    /* XXX: This is before we've probed / set board_id */

    if (board_id == IA_BOARD) {

        uart_base = UART3_BASE;

    }

    regVal = __raw_readl(uart_base + UART_SYSCFG_OFFSET);

    regVal |= UART_RESET;

    __raw_writel(regVal, (uart_base + UART_SYSCFG_OFFSET) );

    while ((__raw_readl(uart_base + UART_SYSSTS_OFFSET) &

            UART_CLK_RUNNING_MASK) != UART_CLK_RUNNING_MASK);

    /* Disable smart idle */

    regVal = __raw_readl((uart_base + UART_SYSCFG_OFFSET));

    regVal |= UART_SMART_IDLE_EN;

    __raw_writel(regVal, (uart_base + UART_SYSCFG_OFFSET));

<PATH : /arch/arm/include/asm/arch-ti81xx/cpu.h>

#ifdef CONFIG_AM335X

#define DEFAULT_UART_BASE       UART0_BASE

#endif

<PATH : /arch/arm/include/asm/arch-ti81xx/hardware.h>

#ifdef CONFIG_AM335X

#define UART0_BASE          0x44E09000

#else

#define UART0_BASE          0x48020000

#endif




[TI-Sitara]启动流程


2.11.初始化 定时器




/* Initialize the Timer */

init_timer();

<PATH : /board/ti/am335x/evm.c>

static void init_timer(void)

{

    /* Reset the Timer */

    __raw_writel(0x2, (DM_TIMER2_BASE + TSICR_REG));

    /* Wait until the reset is done */

    while (__raw_readl(DM_TIMER2_BASE + TIOCP_CFG_REG) & );

    /* Start the Timer */

    __raw_writel(0x1, (DM_TIMER2_BASE + TCLR_REG));

}

<PATH : /arch/arm/include/asm/arch-ti81xx/hardware.h>

/* DM Timer base addresses */

#define DM_TIMER0_BASE          0x4802C000

#define DM_TIMER1_BASE          0x4802E000

#define DM_TIMER2_BASE          0x48040000

#define DM_TIMER3_BASE          0x48042000

#define DM_TIMER4_BASE          0x48044000

#define DM_TIMER5_BASE          0x48046000

#define DM_TIMER6_BASE          0x48048000

#define DM_TIMER7_BASE          0x4804A000




[TI-Sitara]启动流程[TI-Sitara]启动流程


2.12.初始化控制台,通过UART可以查看相关信息




preloader_console_init();

《PATH : /arch/arm/cpu/armv7/omap-common/spl.c》

/* This requires UART clocks to be enabled */

void preloader_console_init(void)

{

    const char *u_boot_rev = U_BOOT_VERSION;

    char rev_string_buffer[];

    gd = &gdata;

    gd->bd = &bdata;

    gd->flags |= GD_FLG_RELOC;

    gd->baudrate = CONFIG_BAUDRATE;

    serial_init();      /* serial communications setup */

    /* Avoid a second "U-Boot" coming from this string */

    u_boot_rev = &u_boot_rev[];

    printf("\nU-Boot SPL %s (%s - %s)\n", u_boot_rev, U_BOOT_DATE,

        U_BOOT_TIME);

    omap_rev_string(rev_string_buffer);

    printf("Texas Instruments %s\n", rev_string_buffer);

} 




2.13.配置 DDR




   config_am335x_ddr();

《PATH :》

/*  void DDR2_EMIF_Config(void); */

static void config_am335x_ddr(void)

{

    int data_macro_0 = ;

    int data_macro_1 = ;

    enable_ddr_clocks();

    config_vtp();

    Cmd_Macro_Config();

    Data_Macro_Config(data_macro_0);

    Data_Macro_Config(data_macro_1);

    __raw_writel(PHY_RANK0_DELAY, DATA0_RANK0_DELAYS_0);

    __raw_writel(PHY_RANK0_DELAY, DATA1_RANK0_DELAYS_0);

    __raw_writel(DDR_IOCTRL_VALUE, DDR_CMD0_IOCTRL);

    __raw_writel(DDR_IOCTRL_VALUE, DDR_CMD1_IOCTRL);

    __raw_writel(DDR_IOCTRL_VALUE, DDR_CMD2_IOCTRL);

    __raw_writel(DDR_IOCTRL_VALUE, DDR_DATA0_IOCTRL);

    __raw_writel(DDR_IOCTRL_VALUE, DDR_DATA1_IOCTRL);

    __raw_writel(__raw_readl(DDR_IO_CTRL) & 0xefffffff, DDR_IO_CTRL);

    __raw_writel(__raw_readl(DDR_CKE_CTRL) | 0x00000001, DDR_CKE_CTRL);

    config_emif_ddr2();

}

《PATH : /arm/include/asm/arch-ti81xx/cpu.h》

#define DATA0_RANK0_DELAYS_0        (DDR_PHY_BASE_ADDR + 0x134)

#define DATA1_RANK0_DELAYS_0        (DDR_PHY_BASE_ADDR + 0x1D8)

/* DDR offsets */

#define DDR_PHY_BASE_ADDR       0x44E12000

#define DDR_IO_CTRL         0x44E10E04

#define DDR_CKE_CTRL            0x44E1131C

#define CONTROL_BASE_ADDR       0x44E10000




[TI-Sitara]启动流程


2.14.设置 internal RAM 内存空间的栈指针,调用 board_init_f()函数




/* Set stackpointer in internal RAM to call board_init_f */

call_board_init_f:

    ldr sp, =(CONFIG_SYS_INIT_SP_ADDR)

    bic sp, sp, # /* 8-byte alignment for ABI compliance */

    ldr r0,=0x00000000

    bl  board_init_f






#define CONFIG_SYS_INIT_SP_ADDR     (CONFIG_SYS_INIT_RAM_ADDR + \

                     CONFIG_SYS_INIT_RAM_SIZE - \

                     GENERATED_GBL_DATA_SIZE)

#define CONFIG_SYS_INIT_RAM_ADDR    SRAM0_START

#define CONFIG_SYS_INIT_RAM_SIZE    SRAM0_SIZE

#ifdef CONFIG_AM335X

#define SRAM0_START         0x402F0400

#else

#define SRAM0_START         0x40300000

#endif

#if defined(CONFIG_AM335X) || defined(CONFIG_TI814X)

#define SRAM0_SIZE          (0x1B400) /* 109 KB */

#define SRAM_GPMC_STACK_SIZE        (0x40)

#endif

#define GENERATED_GBL_DATA_SIZE (128) /* (sizeof(struct global_data) + 15) & ~15 */ 







void board_init_f(ulong dummy)

{

    /*

     * We call relocate_code() with relocation target same as the

     * CONFIG_SYS_SPL_TEXT_BASE. This will result in relocation getting

     * skipped. Instead, only .bss initialization will happen. That's

     * all we need

     */

    debug(">>board_init_f()\n");

    relocate_code(CONFIG_SPL_STACK, &gdata, CONFIG_SPL_TEXT_BASE);

}

#define CONFIG_SPL_TEXT_BASE        0x402F0400

#define CONFIG_SPL_MAX_SIZE     (46 * 1024)

#define CONFIG_SPL_STACK        LOW_LEVEL_SRAM_STACK

#define LOW_LEVEL_SRAM_STACK    0x4030B7FC 







/*

 * void relocate_code (addr_sp, gd, addr_moni)

 *

 * This "function" does not return, instead it continues in RAM

 * after relocating the monitor code.

 *

 */

    .globl  relocate_code

relocate_code:

    mov r4, r0  /* save addr_sp */

    mov r5, r1  /* save addr of gd */

    mov r6, r2  /* save addr of destination 0x402F0400*/</path>




2.15.代码重定位


代码重定向,它首先检测自己(MLO)是否已经在内存中:


如果是直接跳到下面的堆栈初始化代码 clear_bss。


如果不是就将自己从Nor Flash中拷贝到内存中。


Nor Flash 和Nand Flash 本质区别就在于是否进行代码拷贝,也就是下面代码所表述:无论
是Nor Flash 还是Nand Flash,核心思想就是将 uboot 代码搬运到内存中去运行,但是没有拷
贝bss 后面这段代码,只拷贝bss 前面的代码,bss 代码是放置全局变量的。Bss 段代码是为
了清零,拷贝过去再清零重复操作。




    /* Set up the stack                         */

stack_setup:

    mov sp, r4

    adr r0, _start

    cmp r0, r6

    moveq   r9, #      /* no relocation. relocation offset(r9) = 0 */

    beq clear_bss       /* skip relocation */

    mov r1, r6          /* r1 <- scratch for copy_loop */

    ldr r3, _image_copy_end_ofs

    add r2, r0, r3      /* r2 <- source end address      */

copy_loop:                              /* 自拷贝 */

    ldmia   r0!, {r9-r10}       /* copy from source address [r0]    */

    stmia   r1!, {r9-r10}       /* copy to   target address [r1]    */

    cmp r0, r2          /* until source end address [r2]    */

    blo copy_loop

    @a6@ 清空 bss 段




2.16.清空 bss 段




clear_bss:

    ldr r0, _bss_start_ofs

    ldr r1, _bss_end_ofs

    mov r4, r6          /* reloc addr */

    add r0, r0, r4

    add r1, r1, r4

    mov r2, #0x00000000     /* clear                */

clbss_l:str r2, [r0]        /* clear loop...            */

    add r0, r0, #

    cmp r0, r1

    bne clbss_l

/*

 * These are defined in the board-specific linker script.

 */

.globl _bss_start_ofs

_bss_start_ofs:

    .word __bss_start - _start          /* __bss_start = 0x80000000 */




2.17.调用函数 board_init_r,用以完成 MLO(SPI)阶段的所有初始化,并跳转到 uboot.img 阶段




/*

 * We are done. Do not return, instead branch to second part of board

 * initialization, now running from RAM.

 */

jump_2_ram:

/*

 * If I-cache is enabled invalidate it

 */

#ifndef CONFIG_SYS_ICACHE_OFF

    mcr p15, , r0, c7, c5,    @ invalidate icache

    mcr     p15, , r0, c7, c10,   @ DSB

    mcr     p15, , r0, c7, c5,    @ ISB

#endif

    ldr r0, _board_init_r_ofs

    adr r1, _start

    add lr, r0, r1

    add lr, lr, r9

    /* setup parameters for board_init_r */

    mov r0, r5      /* gd_t */

    mov r1, r6      /* dest_addr */

    /* jump to it ... */

    mov pc, lr

_board_init_r_ofs:

    .word board_init_r - _start






《PATH : /arch/arm/cpu/armv7/omap-common/spl.c 》

void board_init_r(gd_t *id, ulong dummy)

{

    u32 boot_device;

    debug(">>spl:board_init_r()\n");

    timer_init();

    i2c_init(CONFIG_SYS_I2C_SPEED, CONFIG_SYS_I2C_SLAVE);

#ifdef CONFIG_SPL_BOARD_INIT

    spl_board_init();

#endif

    boot_device = omap_boot_device();

    debug("boot device - %d\n", boot_device);

    switch (boot_device) {

#ifdef CONFIG_SPL_MMC_SUPPORT

    case BOOT_DEVICE_MMC1:

    case BOOT_DEVICE_MMC2:

        spl_mmc_load_image();

        break;

#endif

#ifdef CONFIG_SPL_NAND_SUPPORT

    case BOOT_DEVICE_NAND:

        spl_nand_load_image();

        break;

#endif

#ifdef CONFIG_SPL_YMODEM_SUPPORT

    case BOOT_DEVICE_UART:

        spl_ymodem_load_image();

        break;

#endif

    default:

        printf("SPL: Un-supported Boot Device - %d!!!\n", boot_device);

        hang();

        break;

    }

    switch (spl_image.os) {

    case IH_OS_U_BOOT:

        debug("Jumping to U-Boot\n");

        jump_to_image_no_args();

        break;

    default:

        puts("Unsupported OS image.. Jumping nevertheless..\n");

        jump_to_image_no_args();

    }

}




3,第三级 bootloader:uboot.img 做了哪些事情?


uboot.img 内存分布如下:


[TI-Sitara]启动流程[TI-Sitara]启动流程


访问 /arch/arm/lib/board.c 中 的 board_init_f() 函数


在 uboot.img 运行过程中,有两个非常重要的结构体:gd_t 和 bd_t 。


其中 gd_t :global_data 数据结构的定义,位于:/arch/arm/include/asm/global_data.h 中。


其成员主要是一些全局的系统初始化参数。


其中 bd_t :bd_info 数据结构的定义,位于:/arch/arm/include/asm/u-boot.h 中。


其成员是开发板的相关参数。




/*

 * The following data structure is placed in some memory which is

 * available very early after boot (like DPRAM on MPC8xx/MPC82xx, or

 * some locked parts of the data cache) to allow for a minimum set of

 * global variables during system initialization (until we have set

 * up the memory controller so that we can use RAM).

 *

 * Keep it *SMALL* and remember to set GENERATED_GBL_DATA_SIZE > sizeof(gd_t)

 */

typedef struct  global_data {

    bd_t        *bd;

    unsigned long   flags;

    unsigned long   baudrate;

    unsigned long   have_console;   /* serial_init() was called */

    unsigned long   env_addr;   /* Address  of Environment struct */

    unsigned long   env_valid;  /* Checksum of Environment valid? */

    unsigned long   fb_base;    /* base address of frame buffer */

#ifdef CONFIG_FSL_ESDHC

    unsigned long   sdhc_clk;

#endif

#ifdef CONFIG_AT91FAMILY

    /* "static data" needed by at91's clock.c */

    unsigned long   cpu_clk_rate_hz;

    unsigned long   main_clk_rate_hz;

    unsigned long   mck_rate_hz;

    unsigned long   plla_rate_hz;

    unsigned long   pllb_rate_hz;

    unsigned long   at91_pllb_usb_init;

#endif

#ifdef CONFIG_ARM

    /* "static data" needed by most of timer.c on ARM platforms */

    unsigned long   timer_rate_hz;

    unsigned long   tbl;

    unsigned long   tbu;

    unsigned long long  timer_reset_value;

    unsigned long   lastinc;

#endif

#ifdef CONFIG_IXP425

    unsigned long   timestamp;

#endif

    unsigned long   relocaddr;  /* Start address of U-Boot in RAM */

    phys_size_t ram_size;   /* RAM size */

    unsigned long   mon_len;    /* monitor len */

    unsigned long   irq_sp;     /* irq stack pointer */

    unsigned long   start_addr_sp;  /* start_addr_stackpointer */

    unsigned long   reloc_off;

#if !(defined(CONFIG_SYS_ICACHE_OFF) && defined(CONFIG_SYS_DCACHE_OFF))

    unsigned long   tlb_addr;

#endif

    void        **jt;       /* jump table */

    char        env_buf[];    /* buffer for getenv() before reloc. */

} gd_t;

#define DECLARE_GLOBAL_DATA_PTR     register volatile gd_t *gd asm ("r8")

typedef struct bd_info {

    int         bi_baudrate;    /* serial console baudrate */

    unsigned long   bi_ip_addr; /* IP Address */

    ulong           bi_arch_number; /* unique id for this board */

    ulong           bi_boot_params; /* where this board expects params */

    struct              /* RAM configuration */

    {

    ulong start;

    ulong size;

    }           bi_dram[CONFIG_NR_DRAM_BANKS];

} bd_t;




其中 DECLARE_GLOBAL_DATA_PTR 宏定义在系统初始化过程中会被频繁调用,


的作用是,声明gd这么一个全局的指针,这个指针指向gd_t结构体类型,并且这个gd指针是保存在ARM的r8这个寄存器里面的。


uboot.img 第一个运行的文件还是 start.o,其在运行访问的 board_init_f() 函数定义在 /arch/arm/lib/board.c 中:




void board_init_f(ulong bootflag)

{

    bd_t *bd;

    init_fnc_t **init_fnc_ptr;

    gd_t *id;

    ulong addr, addr_sp;

    /* Pointer is writable since we allocated a register for it */

    gd = (gd_t *) ((CONFIG_SYS_INIT_SP_ADDR) & ~0x07);

    /* compiler optimization barrier needed for GCC >= 3.4 */

    __asm__ __volatile__("": : :"memory");

    memset((void *)gd, , sizeof(gd_t));

        ...

}






#define CONFIG_SYS_INIT_RAM_ADDR    SRAM0_START

#define CONFIG_SYS_INIT_RAM_SIZE    SRAM0_SIZE

#define CONFIG_SYS_INIT_SP_ADDR     (CONFIG_SYS_INIT_RAM_ADDR + \

                     CONFIG_SYS_INIT_RAM_SIZE - \

                     GENERATED_GBL_DATA_SIZE)

#define SRAM0_START         0x402F0400

#define SRAM0_SIZE          (0x1B400) /* 109 KB */

#define GENERATED_GBL_DATA_SIZE (128) /* (sizeof(struct global_data) + 15) & ~15 */




因此,系统初始化参数将会被保存在 (保存 MLO(SPL)文件的内存空间的)末尾 2 KB 处。


通过计算的 gb 指针指向的内存空间地址为 gb = 0x4030B000


[TI-Sitara]启动流程


gb_t 结构体中某些元素的值是来自于 uboot.img's header,这个header的数据保存在内存的0x807FFFCO,大小为 64字节




/*

 * Legacy format image header,

 * all data in network byte order (aka natural aka bigendian).

 */

typedef struct image_header {

    uint32_t    ih_magic;   /* Image Header Magic Number    */

    uint32_t    ih_hcrc;    /* Image Header CRC Checksum    */

    uint32_t    ih_time;    /* Image Creation Timestamp */

    uint32_t    ih_size;    /* Image Data Size      */

    uint32_t    ih_load;    /* Data  Load  Address      */

    uint32_t    ih_ep;      /* Entry Point Address      */

    uint32_t    ih_dcrc;    /* Image Data CRC Checksum  */

    uint8_t     ih_os;      /* Operating System     */

    uint8_t     ih_arch;    /* CPU architecture     */

    uint8_t     ih_type;    /* Image Type           */

    uint8_t     ih_comp;    /* Compression Type     */

    uint8_t     ih_name[IH_NMLEN];  /* Image Name       */

} image_header_t;






/*

 * 8MB into the SDRAM to allow for SPL's bss at the beginning of SDRAM.

 * 64 bytes before this address should be set aside for u-boot.img's

 * header. That is 0x807FFFC0--0x80800000 should not be used for any

 * other needs.

 */

#define CONFIG_SYS_TEXT_BASE        0x80800000</path>






void board_init_f(ulong bootflag)

{

    bd_t *bd;

    init_fnc_t **init_fnc_ptr;

    gd_t *id;

    ulong addr, addr_sp;

    /* Pointer is writable since we allocated a register for it */

    gd = (gd_t *) ((CONFIG_SYS_INIT_SP_ADDR) & ~0x07);

    /* compiler optimization barrier needed for GCC >= 3.4 */

    __asm__ __volatile__("": : :"memory");

    memset((void *)gd, , sizeof(gd_t));

        ...

}


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