u-boot/arch/x86/cpu/start.S

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/* SPDX-License-Identifier: GPL-2.0+ */
/*
* U-Boot - x86 Startup Code
*
* This is always the first code to run from the U-Boot source. To spell it out:
*
* 1. When TPL (Tertiary Program Loader) is enabled, the boot flow is
* TPL->SPL->U-Boot and this file is used for TPL. Then start_from_tpl.S is used
* for SPL and start_from_spl.S is used for U-Boot proper.
*
* 2. When SPL (Secondary Program Loader) is enabled, but not TPL, the boot
* flow is SPL->U-Boot and this file is used for SPL. Then start_from_spl.S is
* used for U-Boot proper.
*
* 3. When neither TPL nor SPL is used, this file is used for U-Boot proper.
*
* (C) Copyright 2008-2011
* Graeme Russ, <graeme.russ@gmail.com>
*
* (C) Copyright 2002
* Daniel Engström, Omicron Ceti AB, <daniel@omicron.se>
*/
#include <config.h>
#include <asm/global_data.h>
#include <asm/post.h>
#include <asm/processor.h>
#include <asm/processor-flags.h>
#include <generated/generic-asm-offsets.h>
#include <generated/asm-offsets.h>
#include <linux/linkage.h>
.section .text.start
.code32
.globl _start
.type _start, @function
.globl _x86boot_start
_x86boot_start:
/*
* This is the fail-safe 32-bit bootstrap entry point.
*
* This code is used when booting from another boot loader like
* coreboot or EFI. So we repeat some of the same init found in
* start16.
*/
cli
cld
/* Turn off cache (this might require a 486-class CPU) */
movl %cr0, %eax
orl $(X86_CR0_NW | X86_CR0_CD), %eax
movl %eax, %cr0
wbinvd
/*
* Zero the BIST (Built-In Self Test) value since we don't have it.
* It must be 0 or the previous loader would have reported an error.
*/
movl $0, %ebp
jmp 1f
/* Add a way for tools to discover the _start entry point */
.align 4
.long 0x12345678
_start:
/* This is the 32-bit cold-reset entry point, coming from start16 */
/* Save BIST */
movl %eax, %ebp
1:
/* Save table pointer */
movl %ecx, %esi
#ifdef CONFIG_X86_LOAD_FROM_32_BIT
lgdt gdt_ptr2
#endif
/* Load the segment registers to match the GDT loaded in start16.S */
movl $(X86_GDT_ENTRY_32BIT_DS * X86_GDT_ENTRY_SIZE), %eax
movw %ax, %fs
movw %ax, %ds
movw %ax, %gs
movw %ax, %es
movw %ax, %ss
/* Clear the interrupt vectors */
lidt blank_idt_ptr
#ifdef CONFIG_USE_EARLY_BOARD_INIT
/*
* Critical early platform init - generally not used, we prefer init
* to happen later when we have a console, in case something goes
* wrong.
*/
jmp early_board_init
.globl early_board_init_ret
early_board_init_ret:
#endif
post_code(POST_START)
/* Initialise Cache-As-RAM */
jmp car_init
.globl car_init_ret
car_init_ret:
#ifdef CONFIG_USE_CAR
/*
* We now have CONFIG_SYS_CAR_SIZE bytes of Cache-As-RAM (or SRAM,
* or fully initialised SDRAM - we really don't care which)
* starting at CONFIG_SYS_CAR_ADDR to be used as a temporary stack
* and early malloc() area. The MRC requires some space at the top.
*
* Stack grows down from top of CAR. We have:
*
* top-> CONFIG_SYS_CAR_ADDR + CONFIG_SYS_CAR_SIZE
x86: ivybridge: Implement SDRAM init Implement SDRAM init using the Memory Reference Code (mrc.bin) provided in the board directory and the SDRAM SPD information in the device tree. This also needs the Intel Management Engine (me.bin) to work. Binary blobs everywhere: so far we have MRC, ME and microcode. SDRAM init works by setting up various parameters and calling the MRC. This in turn does some sort of magic to work out how much memory there is and the timing parameters to use. It also sets up the DRAM controllers. When the MRC returns, we use the information it provides to map out the available memory in U-Boot. U-Boot normally moves itself to the top of RAM. On x86 the RAM is not generally contiguous, and anyway some RAM may be above 4GB which doesn't work in 32-bit mode. So we relocate to the top of the largest block of RAM we can find below 4GB. Memory above 4GB is accessible with special functions (see physmem). It would be possible to build U-Boot in 64-bit mode but this wouldn't necessarily provide any more memory, since the largest block is often below 4GB. Anyway U-Boot doesn't need huge amounts of memory - even a very large ramdisk seldom exceeds 100-200MB. U-Boot has support for booting 64-bit kernels directly so this does not pose a limitation in that area. Also there are probably parts of U-Boot that will not work correctly in 64-bit mode. The MRC is one. There is some work remaining in this area. Since memory init is very slow (over 500ms) it is possible to save the parameters in SPI flash to speed it up next time. Suspend/resume support is not fully implemented, or at least it is not efficient. With this patch, link boots to a prompt. Signed-off-by: Simon Glass <sjg@chromium.org>
2014-11-13 05:42:28 +00:00
* MRC area
* global_data with x86 global descriptor table
* early malloc area
* stack
* bottom-> CONFIG_SYS_CAR_ADDR
*/
x86: ivybridge: Implement SDRAM init Implement SDRAM init using the Memory Reference Code (mrc.bin) provided in the board directory and the SDRAM SPD information in the device tree. This also needs the Intel Management Engine (me.bin) to work. Binary blobs everywhere: so far we have MRC, ME and microcode. SDRAM init works by setting up various parameters and calling the MRC. This in turn does some sort of magic to work out how much memory there is and the timing parameters to use. It also sets up the DRAM controllers. When the MRC returns, we use the information it provides to map out the available memory in U-Boot. U-Boot normally moves itself to the top of RAM. On x86 the RAM is not generally contiguous, and anyway some RAM may be above 4GB which doesn't work in 32-bit mode. So we relocate to the top of the largest block of RAM we can find below 4GB. Memory above 4GB is accessible with special functions (see physmem). It would be possible to build U-Boot in 64-bit mode but this wouldn't necessarily provide any more memory, since the largest block is often below 4GB. Anyway U-Boot doesn't need huge amounts of memory - even a very large ramdisk seldom exceeds 100-200MB. U-Boot has support for booting 64-bit kernels directly so this does not pose a limitation in that area. Also there are probably parts of U-Boot that will not work correctly in 64-bit mode. The MRC is one. There is some work remaining in this area. Since memory init is very slow (over 500ms) it is possible to save the parameters in SPI flash to speed it up next time. Suspend/resume support is not fully implemented, or at least it is not efficient. With this patch, link boots to a prompt. Signed-off-by: Simon Glass <sjg@chromium.org>
2014-11-13 05:42:28 +00:00
movl $(CONFIG_SYS_CAR_ADDR + CONFIG_SYS_CAR_SIZE - 4), %esp
#ifdef CONFIG_DCACHE_RAM_MRC_VAR_SIZE
subl $CONFIG_DCACHE_RAM_MRC_VAR_SIZE, %esp
#endif
#else
/*
* Instructions for FSP1, but not FSP2:
* U-Boot enters here twice. For the first time it comes from
* car_init_done() with esp points to a temporary stack and esi
* set to zero. For the second time it comes from fsp_init_done()
* with esi holding the HOB list address returned by the FSP.
*/
#endif
/* Set up global data */
mov %esp, %eax
call board_init_f_alloc_reserve
mov %eax, %esp
call board_init_f_init_reserve
#ifdef CONFIG_DEBUG_UART
call debug_uart_init
#endif
/* Get address of global_data */
mov %fs:0, %edx
#if defined(CONFIG_USE_HOB) && !defined(CONFIG_USE_CAR)
/* Store the HOB list if we have one */
test %esi, %esi
jz skip_hob
movl %esi, GD_HOB_LIST(%edx)
#ifdef CONFIG_HAVE_FSP
/*
* After fsp_init() returns, the stack has already been switched to a
* place within system memory as defined by CONFIG_FSP_TEMP_RAM_ADDR.
* Enlarge the size of malloc() pool before relocation since we have
* plenty of memory now.
*/
subl $CONFIG_FSP_SYS_MALLOC_F_LEN, %esp
movl %esp, GD_MALLOC_BASE(%edx)
#endif
skip_hob:
#else
/* Store table pointer */
movl %esi, GD_TABLE(%edx)
#endif
/* Store BIST */
movl %ebp, GD_BIST(%edx)
/* Set parameter to board_init_f() to boot flags */
post_code(POST_START_DONE)
xorl %eax, %eax
/* Enter, U-Boot! */
call board_init_f
/* indicate (lack of) progress */
movw $0x85, %ax
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jmp die
.globl board_init_f_r_trampoline
.type board_init_f_r_trampoline, @function
board_init_f_r_trampoline:
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/*
* SDRAM has been initialised, U-Boot code has been copied into
* RAM, BSS has been cleared and relocation adjustments have been
* made. It is now time to jump into the in-RAM copy of U-Boot
*
* %eax = Address of top of new stack
2011-02-12 04:11:58 +00:00
*/
/* Stack grows down from top of SDRAM */
2011-02-12 04:11:58 +00:00
movl %eax, %esp
/* See if we need to disable CAR */
call car_uninit
/* Re-enter U-Boot by calling board_init_f_r() */
call board_init_f_r
2011-02-12 04:11:58 +00:00
#ifdef CONFIG_TPL
.globl jump_to_spl
.type jump_to_spl, @function
jump_to_spl:
/* Reset stack to the top of CAR space */
movl $(CONFIG_SYS_CAR_ADDR + CONFIG_SYS_CAR_SIZE - 4), %esp
#ifdef CONFIG_DCACHE_RAM_MRC_VAR_SIZE
subl $CONFIG_DCACHE_RAM_MRC_VAR_SIZE, %esp
#endif
jmp *%eax
#endif
die:
hlt
jmp die
hlt
WEAK(car_uninit)
ret
ENDPROC(car_uninit)
blank_idt_ptr:
.word 0 /* limit */
.long 0 /* base */
.p2align 2 /* force 4-byte alignment */
/* Add a multiboot header so U-Boot can be loaded by GRUB2 */
multiboot_header:
/* magic */
.long 0x1badb002
/* flags */
.long (1 << 16)
/* checksum */
.long -0x1BADB002 - (1 << 16)
/* header addr */
.long multiboot_header - _x86boot_start + CONFIG_SYS_TEXT_BASE
/* load addr */
.long CONFIG_SYS_TEXT_BASE
/* load end addr */
.long 0
/* bss end addr */
.long 0
/* entry addr */
.long CONFIG_SYS_TEXT_BASE
#ifdef CONFIG_X86_LOAD_FROM_32_BIT
/*
* The following Global Descriptor Table is just enough to get us into
* 'Flat Protected Mode' - It will be discarded as soon as the final
* GDT is setup in a safe location in RAM
*/
gdt_ptr2:
.word 0x1f /* limit (31 bytes = 4 GDT entries - 1) */
.long gdt_rom2 /* base */
/* Some CPUs are picky about GDT alignment... */
.align 16
.globl gdt_rom2
gdt_rom2:
/*
* The GDT table ...
*
* Selector Type
* 0x00 NULL
* 0x08 Unused
* 0x10 32bit code
* 0x18 32bit data/stack
*/
/* The NULL Desciptor - Mandatory */
.word 0x0000 /* limit_low */
.word 0x0000 /* base_low */
.byte 0x00 /* base_middle */
.byte 0x00 /* access */
.byte 0x00 /* flags + limit_high */
.byte 0x00 /* base_high */
/* Unused Desciptor - (matches Linux) */
.word 0x0000 /* limit_low */
.word 0x0000 /* base_low */
.byte 0x00 /* base_middle */
.byte 0x00 /* access */
.byte 0x00 /* flags + limit_high */
.byte 0x00 /* base_high */
/*
* The Code Segment Descriptor:
* - Base = 0x00000000
* - Size = 4GB
* - Access = Present, Ring 0, Exec (Code), Readable
* - Flags = 4kB Granularity, 32-bit
*/
.word 0xffff /* limit_low */
.word 0x0000 /* base_low */
.byte 0x00 /* base_middle */
.byte 0x9b /* access */
.byte 0xcf /* flags + limit_high */
.byte 0x00 /* base_high */
/*
* The Data Segment Descriptor:
* - Base = 0x00000000
* - Size = 4GB
* - Access = Present, Ring 0, Non-Exec (Data), Writable
* - Flags = 4kB Granularity, 32-bit
*/
.word 0xffff /* limit_low */
.word 0x0000 /* base_low */
.byte 0x00 /* base_middle */
.byte 0x93 /* access */
.byte 0xcf /* flags + limit_high */
.byte 0x00 /* base_high */
#endif