/*- * Copyright (c) 1998 Michael Smith * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ #ifndef _BOOTSTRAP_H_ #define _BOOTSTRAP_H_ #include #include #include #include #include "readin.h" /* Commands and return values; nonzero return sets command_errmsg != NULL */ typedef int (bootblk_cmd_t)(int argc, char *argv[]); #define COMMAND_ERRBUFSZ (256) extern const char *command_errmsg; extern char command_errbuf[COMMAND_ERRBUFSZ]; #define CMD_OK 0 #define CMD_WARN 1 #define CMD_ERROR 2 #define CMD_CRIT 3 #define CMD_FATAL 4 /* interp.c */ void interact(void); void interp_emit_prompt(void); int interp_builtin_cmd(int argc, char *argv[]); /* Called by interp.c for interp_*.c embedded interpreters */ int interp_include(const char *); /* Execute commands from filename */ void interp_init(void); /* Initialize interpreater */ int interp_run(const char *); /* Run a single command */ /* interp_backslash.c */ char *backslash(const char *str); /* interp_parse.c */ int parse(int *argc, char ***argv, const char *str); /* boot.c */ void autoboot_maybe(void); int getrootmount(char *rootdev); /* misc.c */ char *unargv(int argc, char *argv[]); size_t strlenout(vm_offset_t str); char *strdupout(vm_offset_t str); void kern_bzero(vm_offset_t dest, size_t len); int kern_pread(readin_handle_t fd, vm_offset_t dest, size_t len, off_t off); void *alloc_pread(readin_handle_t fd, off_t off, size_t len); /* bcache.c */ void bcache_init(size_t nblks, size_t bsize); void bcache_add_dev(int); void *bcache_allocate(void); void bcache_free(void *); int bcache_strategy(void *devdata, int rw, daddr_t blk, size_t size, char *buf, size_t *rsize); /* * Disk block cache */ struct bcache_devdata { int (*dv_strategy)(void *, int, daddr_t, size_t, char *, size_t *); void *dv_devdata; void *dv_cache; }; /* * Modular console support. */ struct console { const char *c_name; const char *c_desc; int c_flags; #define C_PRESENTIN (1<<0) /* console can provide input */ #define C_PRESENTOUT (1<<1) /* console can provide output */ #define C_ACTIVEIN (1<<2) /* user wants input from console */ #define C_ACTIVEOUT (1<<3) /* user wants output to console */ #define C_WIDEOUT (1<<4) /* c_out routine groks wide chars */ /* set c_flags to match hardware */ void (* c_probe)(struct console *cp); /* reinit XXX may need more args */ int (* c_init)(int arg); /* emit c */ void (* c_out)(int c); /* wait for and return input */ int (* c_in)(void); /* return nonzero if input waiting */ int (* c_ready)(void); }; extern struct console *consoles[]; void cons_probe(void); bool cons_update_mode(bool); void autoload_font(bool); /* * Plug-and-play enumerator/configurator interface. */ struct pnphandler { const char *pp_name; /* handler/bus name */ void (*pp_enumerate)(void); /* enumerate PnP devices, add to chain */ }; struct pnpident { /* ASCII identifier, actual format varies with bus/handler */ char *id_ident; STAILQ_ENTRY(pnpident) id_link; }; struct pnpinfo { char *pi_desc; /* ASCII description, optional */ int pi_revision; /* optional revision (or -1) if not supported */ char *pi_module; /* module/args nominated to handle device */ int pi_argc; /* module arguments */ char **pi_argv; struct pnphandler *pi_handler; /* handler which detected this device */ STAILQ_HEAD(, pnpident) pi_ident; /* list of identifiers */ STAILQ_ENTRY(pnpinfo) pi_link; }; STAILQ_HEAD(pnpinfo_stql, pnpinfo); extern struct pnphandler *pnphandlers[]; /* provided by MD code */ void pnp_addident(struct pnpinfo *pi, char *ident); struct pnpinfo *pnp_allocinfo(void); void pnp_freeinfo(struct pnpinfo *pi); void pnp_addinfo(struct pnpinfo *pi); char *pnp_eisaformat(uint8_t *data); /* * < 0 - No ISA in system * == 0 - Maybe ISA, search for read data port * > 0 - ISA in system, value is read data port address */ extern int isapnp_readport; /* * Version information */ extern char bootprog_info[]; /* * Interpreter information */ extern const char bootprog_interp[]; #define INTERP_DEFINE(interpstr) \ const char bootprog_interp[] = "$Interpreter:" interpstr /* * Preloaded file metadata header. * * Metadata are allocated on our heap, and copied into kernel space * before executing the kernel. */ struct file_metadata { size_t md_size; uint16_t md_type; struct file_metadata *md_next; char md_data[1]; /* data are immediately appended */ }; struct preloaded_file; struct mod_depend; struct kernel_module { char *m_name; /* module name */ int m_version; /* module version */ /* char *m_args; */ /* arguments for the module */ struct preloaded_file *m_fp; struct kernel_module *m_next; }; /* * Preloaded file information. Depending on type, file can contain * additional units called 'modules'. * * At least one file (the kernel) must be loaded in order to boot. * The kernel is always loaded first. * * String fields (m_name, m_type) should be dynamically allocated. */ struct preloaded_file { char *f_name; /* file name */ char *f_type; /* verbose file type, eg 'ELF kernel', 'pnptable', etc. */ char *f_args; /* arguments for the file */ /* metadata that will be placed in the module directory */ struct file_metadata *f_metadata; int f_loader; /* index of the loader that read the file */ vm_offset_t f_addr; /* load address */ size_t f_size; /* file size */ struct kernel_module *f_modules; /* list of modules if any */ struct preloaded_file *f_next; /* next file */ #ifdef __amd64__ bool f_kernphys_relocatable; #endif }; struct file_format { /* * Load function must return EFTYPE if it can't handle * the module supplied */ int (*l_load)(char *, uint64_t, struct preloaded_file **); /* * Only a loader that will load a kernel (first module) * should have an exec handler */ int (*l_exec)(struct preloaded_file *); }; extern struct file_format *file_formats[]; /* supplied by consumer */ extern struct preloaded_file *preloaded_files; int mod_load(char *name, struct mod_depend *verinfo, int argc, char *argv[]); int mod_loadkld(const char *name, int argc, char *argv[]); void unload(void); struct preloaded_file *file_alloc(void); struct preloaded_file *file_findfile(const char *name, const char *type); struct file_metadata *file_findmetadata(struct preloaded_file *fp, int type); struct preloaded_file *file_loadraw(const char *name, char *type, int insert); void file_discard(struct preloaded_file *fp); void file_addmetadata(struct preloaded_file *, int, size_t, void *); int file_addmodule(struct preloaded_file *, char *, int, struct kernel_module **); void file_removemetadata(struct preloaded_file *fp); int file_addbuf(const char *name, const char *type, size_t len, void *buf); int tslog_init(void); int tslog_publish(void); vm_offset_t build_font_module(vm_offset_t); /* MI module loaders */ #ifdef __elfN /* Relocation types. */ #define ELF_RELOC_REL 1 #define ELF_RELOC_RELA 2 /* Relocation offset for some architectures */ extern uint64_t __elfN(relocation_offset); struct elf_file; typedef Elf_Addr (symaddr_fn)(struct elf_file *ef, Elf_Size symidx); int __elfN(loadfile)(char *, uint64_t, struct preloaded_file **); int __elfN(obj_loadfile)(char *, uint64_t, struct preloaded_file **); int __elfN(reloc)(struct elf_file *ef, symaddr_fn *symaddr, const void *reldata, int reltype, Elf_Addr relbase, Elf_Addr dataaddr, void *data, size_t len); int __elfN(loadfile_raw)(char *, uint64_t, struct preloaded_file **, int); int __elfN(load_modmetadata)(struct preloaded_file *, uint64_t); #endif /* * Support for commands */ struct bootblk_command { const char *c_name; const char *c_desc; bootblk_cmd_t *c_fn; }; #define COMMAND_SET(tag, key, desc, func) \ static bootblk_cmd_t func; \ static struct bootblk_command _cmd_ ## tag = { key, desc, func }; \ DATA_SET(Xcommand_set, _cmd_ ## tag) SET_DECLARE(Xcommand_set, struct bootblk_command); /* * The intention of the architecture switch is to provide a convenient * encapsulation of the interface between the bootstrap MI and MD code. * MD code may selectively populate the switch at runtime based on the * actual configuration of the target system. */ struct arch_switch { /* Automatically load modules as required by detected hardware */ int (*arch_autoload)(void); /* Locate the device for (name), return pointer to tail in (*path) */ int (*arch_getdev)(void **dev, const char *name, const char **path); /* * Copy from local address space to module address space, * similar to bcopy() */ ssize_t (*arch_copyin)(const void *, vm_offset_t, const size_t); /* * Copy to local address space from module address space, * similar to bcopy() */ ssize_t (*arch_copyout)(const vm_offset_t, void *, const size_t); /* Read from file to module address space, same semantics as read() */ ssize_t (*arch_readin)(readin_handle_t, vm_offset_t, const size_t); /* Perform ISA byte port I/O (only for systems with ISA) */ int (*arch_isainb)(int port); void (*arch_isaoutb)(int port, int value); /* * Interface to adjust the load address according to the "object" * being loaded. */ uint64_t (*arch_loadaddr)(u_int type, void *data, uint64_t addr); #define LOAD_ELF 1 /* data points to the ELF header. */ #define LOAD_RAW 2 /* data points to the file name. */ /* * Interface to inform MD code about a loaded (ELF) segment. This * can be used to flush caches and/or set up translations. */ #ifdef __elfN void (*arch_loadseg)(Elf_Ehdr *eh, Elf_Phdr *ph, uint64_t delta); #else void (*arch_loadseg)(void *eh, void *ph, uint64_t delta); #endif /* Probe ZFS pool(s), if needed. */ void (*arch_zfs_probe)(void); /* Return the hypervisor name/type or NULL if not virtualized. */ const char *(*arch_hypervisor)(void); /* For kexec-type loaders, get ksegment structure */ void (*arch_kexec_kseg_get)(int *nseg, void **kseg); }; extern struct arch_switch archsw; /* This must be provided by the MD code, but should it be in the archsw? */ void delay(int delay); void dev_cleanup(void); /* * nvstore API. */ typedef int (nvstore_getter_cb_t)(void *, const char *, void **); typedef int (nvstore_setter_cb_t)(void *, int, const char *, const void *, size_t); typedef int (nvstore_setter_str_cb_t)(void *, const char *, const char *, const char *); typedef int (nvstore_unset_cb_t)(void *, const char *); typedef int (nvstore_print_cb_t)(void *, void *); typedef int (nvstore_iterate_cb_t)(void *, int (*)(void *, void *)); typedef struct nvs_callbacks { nvstore_getter_cb_t *nvs_getter; nvstore_setter_cb_t *nvs_setter; nvstore_setter_str_cb_t *nvs_setter_str; nvstore_unset_cb_t *nvs_unset; nvstore_print_cb_t *nvs_print; nvstore_iterate_cb_t *nvs_iterate; } nvs_callbacks_t; int nvstore_init(const char *, nvs_callbacks_t *, void *); int nvstore_fini(const char *); void *nvstore_get_store(const char *); int nvstore_print(void *); int nvstore_get_var(void *, const char *, void **); int nvstore_set_var(void *, int, const char *, void *, size_t); int nvstore_set_var_from_string(void *, const char *, const char *, const char *); int nvstore_unset_var(void *, const char *); #ifndef CTASSERT #define CTASSERT(x) _Static_assert(x, "compile-time assertion failed") #endif #endif /* !_BOOTSTRAP_H_ */