u-boot/arch/x86/include/asm/u-boot-x86.h

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/* SPDX-License-Identifier: GPL-2.0+ */
/*
* (C) Copyright 2002
* Daniel Engström, Omicron Ceti AB, daniel@omicron.se.
*/
#ifndef _U_BOOT_I386_H_
#define _U_BOOT_I386_H_ 1
struct global_data;
extern char gdt_rom[];
/* cpu/.../cpu.c */
int arch_cpu_init(void);
/**
* x86_cpu_init_f() - Set up basic features of the x86 CPU
*
* 0 on success, -ve on error
*/
2011-02-12 04:11:35 +00:00
int x86_cpu_init_f(void);
/**
* x86_cpu_reinit_f() - Set up the CPU a second time
*
* Once cpu_init_f() has been called (e.g. in SPL) we should not call it
* again (e.g. in U-Boot proper) since it sets up the state from scratch.
* Call this function in later phases of U-Boot instead. It reads the CPU
* identify so that CPU functions can be used correctly, but does not change
* anything.
*
* Return: 0 (indicating success, to mimic cpu_init_f())
*/
int x86_cpu_reinit_f(void);
/**
* x86_cpu_init_tpl() - Do the minimum possible CPU init
*
* This just sets up the CPU features and figured out the identity
*
* Return: 0 (indicating success, to mimic cpu_init_f())
*/
int x86_cpu_init_tpl(void);
/**
* cpu_reinit_fpu() - Reinit the FPU if something is wrong with it
*
* The FSP-M code can leave registers in use in the FPU. This functions reinits
* it so that the FPU can be used safely
*/
void cpu_reinit_fpu(void);
int cpu_init_f(void);
void setup_gdt(struct global_data *id, u64 *gdt_addr);
/*
* Setup FSP execution environment GDT to use the one we used in
* arch/x86/cpu/start16.S and reload the segment registers.
*/
void setup_fsp_gdt(void);
int init_cache(void);
int cleanup_before_linux(void);
/* cpu/.../timer.c */
void timer_isr(void *);
typedef void (timer_fnc_t) (void);
int register_timer_isr (timer_fnc_t *isr_func);
unsigned long get_tbclk_mhz(void);
void timer_set_base(uint64_t base);
int i8254_init(void);
/* cpu/.../interrupts.c */
int cpu_init_interrupts(void);
int cleanup_before_linux(void);
int x86_cleanup_before_linux(void);
void x86_enable_caches(void);
void x86_disable_caches(void);
int x86_init_cache(void);
phys_addr_t board_get_usable_ram_top(phys_size_t total_size);
int default_print_cpuinfo(void);
/* Set up a UART which can be used with printch(), printhex8(), etc. */
int setup_internal_uart(int enable);
void isa_unmap_rom(u32 addr);
u32 isa_map_rom(u32 bus_addr, int size);
/* arch/x86/lib/... */
int video_bios_init(void);
/* arch/x86/lib/fsp1,2/... */
/**
* fsp_save_s3_stack() - save stack address to CMOS for next S3 boot
*
* At the end of pre-relocation phase, save the new stack address
* to CMOS and use it as the stack on next S3 boot for fsp_init()
* continuation function.
*
* @return: 0 if OK, -ve on error
*/
int fsp_save_s3_stack(void);
/**
* board_init_f_r_trampoline() - jump to relocated address with new stack
*
* @sp: New stack pointer to use
*/
void __noreturn board_init_f_r_trampoline(ulong sp);
/**
* board_init_f_r() - jump to relocated U-Boot
*
* This is used to jump from pre-relocation to post-relocation U-Boot. It
* enables the cache and jump to the new location.
*/
void __noreturn board_init_f_r(void);
/*
* board_init_f_r_trampoline64() - jump to relocated address with new stack
*
* This is the 64-bit version
*
* @new_gd: New global_data pointer to use
* @sp: New stack pointer to pass on to board_init_r()
*/
void __noreturn board_init_f_r_trampoline64(struct global_data *new_gd,
ulong sp);
int arch_misc_init(void);
/* Read the time stamp counter */
static inline notrace uint64_t rdtsc(void)
{
uint32_t high, low;
__asm__ __volatile__("rdtsc" : "=a" (low), "=d" (high));
return (((uint64_t)high) << 32) | low;
}
/* board/... */
void timer_set_tsc_base(uint64_t new_base);
uint64_t timer_get_tsc(void);
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
void quick_ram_check(void);
#define PCI_VGA_RAM_IMAGE_START 0xc0000
#endif /* _U_BOOT_I386_H_ */