/* SPDX-License-Identifier: GPL-2.0+ */ /* * (C) Copyright 2000-2009 * Wolfgang Denk, DENX Software Engineering, wd@denx.de. * * Copy the startup prototype, previously defined in common.h * Copyright (C) 2018, STMicroelectronics - All Rights Reserved */ #ifndef __INIT_H_ #define __INIT_H_ 1 #include #ifndef __ASSEMBLY__ /* put C only stuff in this section */ /* * Function Prototypes */ /* common/board_f.c */ void board_init_f(ulong dummy); /** * arch_cpu_init() - basic cpu-dependent setup for an architecture * * This is called after early malloc is available. It should handle any * CPU- or SoC- specific init needed to continue the init sequence. See * board_f.c for where it is called. If this is not provided, a default * version (which does nothing) will be used. * * Return: 0 on success, otherwise error */ int arch_cpu_init(void); /** * arch_cpu_init_dm() - init CPU after driver model is available * * This is called immediately after driver model is available before * relocation. This is similar to arch_cpu_init() but is able to reference * devices * * Return: 0 if OK, -ve on error */ int arch_cpu_init_dm(void); /** * mach_cpu_init() - SoC/machine dependent CPU setup * * This is called after arch_cpu_init(). It should handle any * SoC or machine specific init needed to continue the init sequence. See * board_f.c for where it is called. If this is not provided, a default * version (which does nothing) will be used. * * Return: 0 on success, otherwise error */ int mach_cpu_init(void); /** * arch_fsp_init() - perform firmware support package init * * Where U-Boot relies on binary blobs to handle part of the system init, this * function can be used to set up the blobs. This is used on some Intel * platforms. * * Return: 0 */ int arch_fsp_init(void); int dram_init(void); /** * dram_init_banksize() - Set up DRAM bank sizes * * This can be implemented by boards to set up the DRAM bank information in * gd->bd->bi_dram(). It is called just before relocation, after dram_init() * is called. * * If this is not provided, a default implementation will try to set up a * single bank. It will do this if CONFIG_NR_DRAM_BANKS and * CONFIG_SYS_SDRAM_BASE are set. The bank will have a start address of * CONFIG_SYS_SDRAM_BASE and the size will be determined by a call to * get_effective_memsize(). * * Return: 0 if OK, -ve on error */ int dram_init_banksize(void); /** * arch_reserve_stacks() - Reserve all necessary stacks * * This is used in generic board init sequence in common/board_f.c. Each * architecture could provide this function to tailor the required stacks. * * On entry gd->start_addr_sp is pointing to the suggested top of the stack. * The callee ensures gd->start_add_sp is 16-byte aligned, so architectures * require only this can leave it untouched. * * On exit gd->start_addr_sp and gd->irq_sp should be set to the respective * positions of the stack. The stack pointer(s) will be set to this later. * gd->irq_sp is only required, if the architecture needs it. * * Return: 0 if no error */ int arch_reserve_stacks(void); /** * init_cache_f_r() - Turn on the cache in preparation for relocation * * Return: 0 if OK, -ve on error */ int init_cache_f_r(void); #if !CONFIG_IS_ENABLED(CPU) /** * print_cpuinfo() - Display information about the CPU * * Return: 0 if OK, -ve on error */ int print_cpuinfo(void); #endif int timer_init(void); int reserve_mmu(void); int misc_init_f(void); #if defined(CONFIG_DTB_RESELECT) int embedded_dtb_select(void); #endif /* common/init/board_init.c */ extern ulong monitor_flash_len; /** * ulong board_init_f_alloc_reserve - allocate reserved area * @top: top of the reserve area, growing down. * * This function is called by each architecture very early in the start-up * code to allow the C runtime to reserve space on the stack for writable * 'globals' such as GD and the malloc arena. * * Return: bottom of reserved area */ ulong board_init_f_alloc_reserve(ulong top); /** * board_init_f_init_reserve - initialize the reserved area(s) * @base: top from which reservation was done * * This function is called once the C runtime has allocated the reserved * area on the stack. It must initialize the GD at the base of that area. */ void board_init_f_init_reserve(ulong base); struct global_data; /** * arch_setup_gd() - Set up the global_data pointer * @gd_ptr: Pointer to global data * * This pointer is special in some architectures and cannot easily be assigned * to. For example on x86 it is implemented by adding a specific record to its * Global Descriptor Table! So we we provide a function to carry out this task. * For most architectures this can simply be: * * gd = gd_ptr; */ void arch_setup_gd(struct global_data *gd_ptr); /* common/board_r.c */ void board_init_r(struct global_data *id, ulong dest_addr) __attribute__ ((noreturn)); int cpu_init_r(void); int last_stage_init(void); int mac_read_from_eeprom(void); int set_cpu_clk_info(void); int update_flash_size(int flash_size); int arch_early_init_r(void); void pci_init(void); int misc_init_r(void); #if defined(CONFIG_VID) int init_func_vid(void); #endif /* common/board_info.c */ int checkboard(void); int show_board_info(void); /** * Get the uppermost pointer that is valid to access * * Some systems may not map all of their address space. This function allows * boards to indicate what their highest support pointer value is for DRAM * access. * * @param total_size Size of U-Boot (unused?) */ ulong board_get_usable_ram_top(ulong total_size); int board_early_init_f(void); /* manipulate the U-Boot fdt before its relocation */ int board_fix_fdt(void *rw_fdt_blob); int board_late_init(void); int board_postclk_init(void); /* after clocks/timebase, before env/serial */ int board_early_init_r(void); #endif /* __ASSEMBLY__ */ /* Put only stuff here that the assembler can digest */ #endif /* __INIT_H_ */