/* Module manager. Uses hash.c */ /* ** Copyright 2001, Thomas Kurschel. All rights reserved. ** Distributed under the terms of the NewOS License. */ #include #include #include #include #include #include #include #include #include #include #include #include #include static bool modules_disable_user_addons = false; #define debug_level_flow 0 #define debug_level_error 1 #define debug_level_info 1 #define WAIT #define WAIT_ERROR #define MSG_PREFIX "MODULE -- " #define FUNC_NAME MSG_PREFIX __FUNCTION__ ": " #define SHOW_FLOW(seriousness, format, param...) \ do { if (debug_level_flow > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME, param ); WAIT \ }} while( 0 ) #define SHOW_FLOW0(seriousness, format) \ do { if (debug_level_flow > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME); WAIT \ }} while( 0 ) #define SHOW_ERROR(seriousness, format, param...) \ do { if (debug_level_error > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME, param ); WAIT_ERROR \ }} while( 0 ) #define SHOW_ERROR0(seriousness, format) \ do { if (debug_level_error > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME); WAIT_ERROR \ }} while( 0 ) #define SHOW_INFO(seriousness, format, param...) \ do { if (debug_level_info > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME, param ); WAIT \ }} while( 0 ) #define SHOW_INFO0(seriousness, format) \ do { if (debug_level_info > seriousness ) { \ dprintf( "%s"##format, FUNC_NAME); WAIT \ }} while( 0 ) typedef enum { MOD_QUERIED = 0, MOD_LOADED, MOD_INIT, MOD_RDY, MOD_UNINIT, MOD_ERROR } module_state; /* This represents the actual loaded module. The module is loaded and * may have more than one exported images, * i.e. the module foo may actually have module_info structures for foo and bar * To allow for this each module_info structure within the module loaded is represented * by a loaded_module_info structure. */ typedef struct loaded_module { struct loaded_module *next; struct loaded_module *prev; module_info **info; /* the module_info we use */ char *path; /* the full path for the module */ int ref_cnt; /* how many ref's to this file */ } loaded_module; struct loaded_module loaded_modules; /* This is used to keep a list of module and the file it's found * in. It's used when we do searches to record that a module_info for * a particular module is found in a particular file which covers us for * the case where we have a single file exporting a number of modules. */ typedef struct module { struct module *next; struct module *prev; struct loaded_module *module; char *name; char *file; int ref_cnt; module_info *ptr; /* will only be valid if ref_cnt > 0 */ int offset; /* this is the offset in the headers */ int state; /* state of module */ bool keep_loaded; } module; /* This is used to provide a list of modules we know about */ static struct module known_modules; #define INC_MOD_REF_COUNT(x) \ x->ref_cnt++; \ x->module->ref_cnt++; #define DEC_MOD_REF_COUNT(x) \ x->ref_cnt--; \ x->module->ref_cnt--; typedef struct module_iterator { char *prefix; int base_path_id; struct module_dir_iterator *base_dir; struct module_dir_iterator *cur_dir; int err; int module_pos; /* This is used to keep track of which module_info * within a module we're addressing. */ module_info **cur_header; char *cur_path; } module_iterator; typedef struct module_dir_iterator { struct module_dir_iterator *parent_dir; struct module_dir_iterator *sub_dir; char *name; int file; int hdr_prefix; } module_dir_iterator; /* XXX - These should really be in a header so they are system wide... */ /* These are GCC only, so we'll need PPC version eventually... */ struct quehead { struct quehead *qh_link; struct quehead *qh_rlink; }; __inline void insque(void *a, void *b) { struct quehead *element = (struct quehead *)a, *head = (struct quehead *)b; element->qh_link = head->qh_link; element->qh_rlink = head; head->qh_link = element; element->qh_link->qh_rlink = element; } __inline void remque(void *a) { struct quehead *element = (struct quehead *)a; element->qh_link->qh_rlink = element->qh_rlink; element->qh_rlink->qh_link = element->qh_link; element->qh_rlink = 0; } /* XXX locking scheme: there is a global lock only; having several locks * makes trouble if dependent modules get loaded concurrently -> * they have to wait for each other, i.e. we need one lock per module; * also we must detect circular references during init and not dead-lock */ static recursive_lock modules_lock; /* These are the standard paths that we look on for mdoules to load. * By default we only look on these plus the prefix, though we do search * below the prefix. * i.e. using media as the prefix will match * /boot/user-addons/media * /boot/addons/media * /boot/addons/media/encoders * but will NOT match * /boot/addons/kernel/media */ const char *const module_paths[] = { "/boot/user-addons", "/boot/addons" }; #define num_module_paths (sizeof( module_paths ) / sizeof( module_paths[0] )) /* the hash tables we use */ new_hash_table *module_files = NULL; new_hash_table *modules_list = NULL; /* load_module_file * Try to load the module file we've found into memory. * This may fail if all the symbols can't be resolved. * Returns 0 on success, -1 on failure. * * NB hdrs can be passed as a NULL if the modules ** header * pointer isn't required. * * Returns * NULL on failure * pointer to modules symbol on success */ static module_info **load_module_file(const char *path) { image_id file_image = elf_load_kspace(path, ""); loaded_module *lm; if (file_image < 0 ) { SHOW_FLOW( 3, "couldn't load image %s (%s)\n", path, strerror(file_image)); dprintf("load_module_file failed! returned %d\n", file_image); return NULL; } lm = (loaded_module*)kmalloc(sizeof(loaded_module)); if (!lm) return NULL; lm->info = (module_info**) elf_lookup_symbol(file_image, "modules"); if (!lm->info) { dprintf("Failed to load %s due to lack of 'modules' symbol\n", path); kfree(lm); return NULL; } lm->path = (char*)kmalloc(strlen(path) + 1); if (!lm->path) { kfree(lm); return NULL; } strcpy(lm->path, path); lm->ref_cnt = 0; recursive_lock_lock(&modules_lock); insque(lm, &loaded_modules); hash_set(module_files, path, strlen(path), lm); recursive_lock_unlock(&modules_lock); return lm->info; } static inline void unload_module_file(const char *path) { loaded_module *themod; dprintf("unload_mdoule_file: %s\n", path); // themod = (loaded_module*)hash_get(module_files, path, strlen(path)); if ((themod = (loaded_module*)hash_get(module_files, path, strlen(path))) == NULL) return; if (themod->ref_cnt != 0) { dprintf("Can't unload %s due to ref_cnt = %d\n", themod->path, themod->ref_cnt); return; } recursive_lock_lock(&modules_lock); remque(themod); hash_set(module_files, path, strlen(path), NULL); recursive_lock_unlock(&modules_lock); elf_unload_kspace(themod->path); kfree(themod); } /* simple_module_info() * Extract the information from the module_info structure pointed at * by mod and create the entries required for access to it's details. * * Returns * -1 if error * 0 if ok */ static int simple_module_info(module_info *mod, const char *file, int offset) { module *m; if (!mod->name) return -1; m = (module*)hash_get(modules_list, mod->name, strlen(mod->name)); if (m) { dprintf("Duplicate module name (%s) detected...ignoring\n", mod->name); return -1; } if ((m = (module*)kmalloc(sizeof(module))) == NULL) return -1; SHOW_FLOW(3, "simple_module_info(%s, %s)\n", mod->name, file); dprintf("simple_module_info: '%s'\n", mod->name); m->module = NULL; /* back pointer */ m->name = (char*)kmalloc(strlen(mod->name) + 1); if (!m->name) { kfree(m); return -1; } strcpy(m->name, mod->name); m->state = MOD_QUERIED; /* Record where the module_info can be found */ m->offset = offset; m->file = (char*)kstrdup(file); /* set the keep_loaded flag */ if (mod->flags & B_KEEP_LOADED) { dprintf("module %s wants to be kept loaded\n", m->name); m->keep_loaded = true; } recursive_lock_lock(&modules_lock); /* Insert into linked list */ insque(m, &known_modules); hash_set(modules_list, mod->name, strlen(mod->name), m); recursive_lock_unlock(&modules_lock); return 0; } /* recurse_check_file * Load the file filepath and check to see if we have a module within it * that matches module_wanted. * * NB module_wanted could be NULL if we're just scanning the modules. * * Return * -1 on error * 0 on no match * 1 on match */ static int recurse_check_file(const char *filepath, const char *module_wanted) { module_info **hdr = NULL, **chk; int i = 0, match = 0; if ((hdr = load_module_file(filepath)) == NULL) return -1; for (chk = hdr; *chk; chk++) { /* if simple_module_info returns 0 then we have found a new * module and added it to the hash table. The question is now * is this new module the one we're looking for? * module_wanted may be a NULL, which is why we check for it. */ if (simple_module_info((*chk), filepath, i++) == 0) { if (module_wanted && strcmp((*chk)->name, module_wanted) == 0) match = 1; } } /* If match != 1 then the modules we've found in the file don't match * the one we're looking for. Unload the module as we're not about to need * anything from it. */ if (match != 1) { // dprintf("unloading module file %s\n", filepath); unload_module_file(filepath); } return match; } /* recurse_directory * Enter the directory and try every entry, entering directories if * we encounter them. * * NB match can be NULL if we're just doing a scan of the modules * to build our cache. * * The recurse loop has these values * -1 for error * 0 for no match * 1 for match */ static int recurse_directory(const char *path, const char *match) { /* ToDo: should just use opendir(), readdir(), ... */ struct stat stat; int res = 0, dir; int bufferSize = sizeof(struct dirent) + SYS_MAX_NAME_LEN + 1; struct dirent *dirent; if ((dir = sys_open_dir(path)) < 0) return -1; dirent = kmalloc(bufferSize); if (!dirent) { sys_close(dir); return -1; } /* loop until we have a match or we run out of entries */ while (res <= 0) { char *newpath; size_t slen = 0; SHOW_FLOW(3, "scanning %s\n", path); if ((res = sys_read_dir(dir, dirent, bufferSize, 1)) <= 0) break; dirent->d_name[dirent->d_reclen] = '\0'; slen = strlen(path) + strlen(dirent->d_name) + 2; newpath = (char*)kmalloc(slen); strlcpy(newpath, path, slen); strlcat(newpath, "/", slen); strlcat(newpath, dirent->d_name, slen); if ((res = sys_read_stat(newpath, true, &stat)) != B_NO_ERROR) { kfree(newpath); break; } /* If we got here, we have either a file or a directory. * If it's a file, do we have the details on record? * If we don't, then load the file and record it's details. * If it matches our search path we'll return afterwards. */ if (S_ISREG(stat.st_mode)) { /* do we already know about this file? * If we do res = 0 and we'll just carry on, if * not, it's a new file so we need to read in the * file details via recurse_file_check() function. */ if (hash_get(module_files, newpath, strlen(newpath)) != NULL) res = 0; else res = recurse_check_file(newpath, match); } else if (S_ISDIR(stat.st_mode)) { res = recurse_directory(newpath, match); } kfree(newpath); } kfree(dirent); sys_close(dir); return res; } /* This is only called if we fail to find a module already in our cache...saves us * some extra checking here :) */ static module *search_module(const char *name) { int i, res = 0; SHOW_FLOW(3, "search_module(%s)\n", name); for (i = 0; i < (int)num_module_paths; ++i) { if ((res = recurse_directory(module_paths[i], name)) == 1) break; } if (res != 1) { return NULL; } return (module*)hash_get(modules_list, name, strlen(name)); } static inline int init_module(module *module) { int res = 0; switch(module->state) { case MOD_QUERIED: case MOD_LOADED: module->state = MOD_INIT; SHOW_FLOW( 3, "initing module %s... \n", module->name ); res = module->ptr->std_ops(B_MODULE_INIT); SHOW_FLOW(3, "...done (%s)\n", strerror(res)); if (!res ) module->state = MOD_RDY; else module->state = MOD_LOADED; break; case MOD_RDY: res = B_NO_ERROR; break; case MOD_INIT: SHOW_ERROR( 0, "circular reference to %s\n", module->name ); res = B_ERROR; break; case MOD_UNINIT: SHOW_ERROR( 0, "tried to load module %s which is currently unloading\n", module->name ); res = B_ERROR; break; case MOD_ERROR: SHOW_INFO( 0, "cannot load module %s because its earlier unloading failed\n", module->name ); res = B_ERROR; break; default: res = B_ERROR; } return res; } static inline int uninit_module(module *module) { switch( module->state ) { case MOD_QUERIED: case MOD_LOADED: return B_NO_ERROR; case MOD_INIT: panic( "Trying to unload module %s which is initializing\n", module->name ); return B_ERROR; case MOD_UNINIT: panic( "Trying to unload module %s which is un-initializing\n", module->name ); return B_ERROR; case MOD_RDY: { int res; module->state = MOD_UNINIT; SHOW_FLOW( 2, "uniniting module %s...\n", module->name ); res = module->ptr->std_ops(B_MODULE_UNINIT); SHOW_FLOW( 2, "...done (%s)\n", strerror( res )); if (res == B_NO_ERROR ) { module->state = MOD_LOADED; return 0; } SHOW_ERROR( 0, "Error unloading module %s (%i)\n", module->name, res ); } module->state = MOD_ERROR; module->keep_loaded = true; // fall through default: return B_ERROR; } } static int process_module_info(module_iterator *iter, char *buf, size_t *bufsize) { module *m = NULL; module_info **mod; int res = B_NO_ERROR; mod = iter->cur_header; if (!mod || !(*mod)) { res = EINVAL; } else { res = simple_module_info(*mod, iter->cur_path, iter->module_pos++); m = (module*)hash_get(modules_list, (*mod)->name, strlen((*mod)->name)); if (m) { strlcpy(buf, m->name, *bufsize); *bufsize = strlen(m->name); } } /* Deal with the header pointer! * Basically if we have a valid pointer (mod) and the next (++mod) is NOT null, * then we advance the cur_header pointer, otherwise we specify it as * NULL to make sure we don't have trouble :) */ if (mod && *(++mod) != NULL) iter->cur_header++; else iter->cur_header = NULL; return res; } static inline int module_create_dir_iterator( module_iterator *iter, int file, const char *name ) { module_dir_iterator *dir; /* if we're creating a dir_iterator, there is no way that the * cur_header value can be valid, so make sure and reset it * here. */ iter->cur_header = NULL; dir = (struct module_dir_iterator *)kmalloc( sizeof( *dir )); if (dir == NULL ) return ENOMEM; dir->name = (char *)kstrdup( name ); if (dir->name == NULL ) { kfree( dir ); return ENOMEM; } dir->file = file; dir->sub_dir = NULL; dir->parent_dir = iter->cur_dir; if (iter->cur_dir ) iter->cur_dir->sub_dir = dir; else iter->base_dir = dir; iter->cur_dir = dir; SHOW_FLOW( 3, "created dir iterator for %s\n", name ); return B_NO_ERROR; } static inline int module_enter_dir(module_iterator *iter, const char *path) { int dir; int res; dir = sys_open_dir(path); if (dir < 0 ) { SHOW_FLOW(3, "couldn't open directory %s (%s)\n", path, strerror(dir)); // there are so many errors for "not found" that we don't bother // and always assume that the directory suddenly disappeared return B_NO_ERROR; } res = module_create_dir_iterator(iter, dir, path); if (res != B_NO_ERROR) { sys_close(dir); return ENOMEM; } SHOW_FLOW(3, "entered directory %s\n", path); return B_NO_ERROR; } static inline void destroy_dir_iterator( module_iterator *iter ) { module_dir_iterator *dir; dir = iter->cur_dir; SHOW_FLOW( 3, "destroying directory iterator for sub-dir %s\n", dir->name ); if (dir->parent_dir ) dir->parent_dir->sub_dir = NULL; iter->cur_dir = dir->parent_dir; kfree(dir->name); kfree(dir); } static inline void module_leave_dir( module_iterator *iter ) { module_dir_iterator *parent_dir; SHOW_FLOW( 3, "leaving directory %s\n", iter->cur_dir->name ); parent_dir = iter->cur_dir->parent_dir; iter->cur_header = NULL; sys_close( iter->cur_dir->file ); destroy_dir_iterator( iter ); iter->cur_dir = parent_dir; } static void compose_path( char *path, module_iterator *iter, const char *name, bool full_path ) { module_dir_iterator *dir; if (full_path ) { strlcpy( path, iter->base_dir->name, SYS_MAX_PATH_LEN ); strlcat( path, "/", SYS_MAX_PATH_LEN ); } else { strlcpy( path, iter->prefix, SYS_MAX_PATH_LEN ); if (*iter->prefix ) strlcat( path, "/", SYS_MAX_PATH_LEN ); } for( dir = iter->base_dir->sub_dir; dir; dir = dir->sub_dir ) { strlcat( path, dir->name, SYS_MAX_PATH_LEN ); strlcat( path, "/", SYS_MAX_PATH_LEN ); } strlcat( path, name, SYS_MAX_PATH_LEN ); SHOW_FLOW( 3, "name: %s, %s -> %s\n", name, full_path ? "full path" : "relative path", path ); } /* module_traverse_directory * Logic as follows... * If we have a headers pointer, * - check if the next structure is NULL, if not process that module_info structure * - if it's null, close the file, NULL the headers pointer and fall through * * This function tries to find the next module filename and then set the headers * pointer in the cur_dir structure. */ static inline int module_traverse_dir(module_iterator *iter) { int res; struct stat stat; char name[SYS_MAX_NAME_LEN]; char path[SYS_MAX_PATH_LEN]; /* If (*iter->cur_header) != NULL we have another module within * the existing file to return, so just return. * Otherwise, actually find the next file to read. */ if (iter->cur_header) { if (*iter->cur_header == NULL) unload_module_file(iter->cur_path); else return B_NO_ERROR; } SHOW_FLOW( 3, "scanning %s\n", iter->cur_dir->name ); if ((res = sys_read(iter->cur_dir->file, name, 0, sizeof(name))) <= 0) { SHOW_FLOW(3, "got error: %s\n", strerror(res)); module_leave_dir(iter); return B_NO_ERROR; } SHOW_FLOW( 3, "got %s\n", name ); if (strcmp(name, ".") == 0 || strcmp(name, "..") == 0 ) return B_NO_ERROR; /* currently, sys_read returns an error if buffer is too small * I don't know the official specification, so it's always safe * to add a trailing end-of-string */ name[sizeof(name) - 1] = 0; compose_path(path, iter, name, true); /* As we're doing a new file, reset the pointers that might get * screwed up... */ iter->cur_header = NULL; iter->module_pos = 0; if ((res = sys_read_stat(path, true, &stat)) != B_NO_ERROR) return res; if (S_ISREG(stat.st_mode)) { module_info **hdrs = NULL; if ((hdrs = load_module_file(path)) != NULL) { iter->cur_header = hdrs; iter->cur_path = (char*)kstrdup(path); return B_NO_ERROR; } return EINVAL; /* not sure what we should return here */ } if (S_ISDIR(stat.st_mode)) return module_enter_dir(iter, path); SHOW_FLOW( 3, "entry %s not a file nor a directory - ignored\n", name ); return B_NO_ERROR; } /* module_enter_base_path * Basically try each of the directories we have listed as module paths, * trying each with the prefix we've been allocated. */ static inline int module_enter_base_path(module_iterator *iter) { char path[SYS_MAX_PATH_LEN]; ++iter->base_path_id; if (iter->base_path_id >= (int)num_module_paths ) { SHOW_FLOW0( 3, "no locations left\n" ); return ENOENT; } SHOW_FLOW(3, "trying base path (%s)\n", module_paths[iter->base_path_id]); if (iter->base_path_id == 0 && modules_disable_user_addons) { SHOW_FLOW0( 3, "ignoring user add-ons (they are disabled)\n" ); return B_NO_ERROR; } strcpy(path, module_paths[iter->base_path_id]); if (*iter->prefix) { strcat(path, "/"); strlcat(path, iter->prefix, sizeof(path)); } return module_enter_dir(iter, path); } /* open_module_list * This returns a pointer to a structure that can be used to * iterate through a list of all modules available under * a given prefix. * All paths will be searched and the returned list will * contain all modules available under the prefix. * The structure is then used by the read_next_module_name function * and MUST be freed or memory will be leaked. */ void *open_module_list(const char *prefix) { module_iterator *iter; SHOW_FLOW( 3, "prefix: %s\n", prefix ); iter = (module_iterator *)kmalloc(sizeof( module_iterator)); if (!iter) return NULL; iter->prefix = (char *)kstrdup( prefix ); if(iter->prefix == NULL) { kfree(iter); return NULL; } iter->base_path_id = -1; iter->base_dir = iter->cur_dir = NULL; iter->err = B_NO_ERROR; iter->module_pos = 0; return (void *)iter; } /* read_next_module_name * Return the next module name from the available list, using * a structure previously created by a call to open_module_list. * Returns 0 if a module was available. */ int read_next_module_name(void *cookie, char *buf, size_t *bufsize ) { module_iterator *iter = (module_iterator *)cookie; int res; *buf = '\0'; if(!iter) return EINVAL; res = iter->err; SHOW_FLOW0(3, "looking for next module\n"); while (res == B_NO_ERROR) { SHOW_FLOW0(3, "searching for module\n"); if (iter->cur_dir == NULL) { res = module_enter_base_path(iter); } else { if ((res = module_traverse_dir(iter)) == B_NO_ERROR) { /* By this point we should have a valid pointer to a module_info structure * in iter->cur_header */ if (process_module_info(iter, buf, bufsize) == B_NO_ERROR) break; } } } /* did we get something?? */ if (*buf == '\0') res = ENOENT; iter->err = res; SHOW_FLOW(3, "finished with status %s\n", strerror(iter->err)); return iter->err; } int close_module_list(void *cookie) { module_iterator *iter = (module_iterator *)cookie; SHOW_FLOW0( 3, "\n" ); if (!iter ) return EINVAL; while(iter->cur_dir) module_leave_dir(iter); kfree(iter->prefix); kfree(iter); return 0; } /* module_init * setup module structures and data for use */ int module_init( kernel_args *ka, module_info **sys_module_headers ) { SHOW_FLOW0( 0, "\n" ); recursive_lock_create( &modules_lock ); modules_list = hash_make(); module_files = hash_make(); if (modules_list == NULL || module_files == NULL) return ENOMEM; loaded_modules.next = loaded_modules.prev = &loaded_modules; known_modules.next = known_modules.prev = &known_modules; /* if (sys_module_headers) { if (register_module_image("", "(built-in)", 0, sys_module_headers) == NULL) return ENOMEM; } */ return B_NO_ERROR; } /* BeOS Compatibility... */ int get_module(const char *path, module_info **vec) { module *m = (module *)hash_get(modules_list, path, strlen(path)); loaded_module *lm; int res = B_NO_ERROR; *vec = NULL; dprintf("*** get_module: %s\n", path); /* If m == NULL we didn't find any record of the module * in our hash. We'll now call serach_mdoules which will do * scan of the possible directories that may contain it. */ if (!m) { m = search_module(path); if (!m) { dprintf("Search for %s failed.\n", path); return ENOENT; } } /* If we've got here then we basically have a pointer to the * module structure representing the requested module in m; */ recursive_lock_lock(&modules_lock); /* We now need to find the module_file structure. This should * be in memory if we have just run search_modules, but may not be * if we are used cached information. */ lm = (loaded_module*)hash_get(module_files, m->file, strlen(m->file)); if (!lm) { if (load_module_file(m->file) == NULL) return ENOENT; lm = (loaded_module*)hash_get(module_files, m->file, strlen(m->file)); if (!lm) return ENOENT; } /* We have the module file required in memory! */ m->ptr = lm->info[m->offset]; m->module = lm; INC_MOD_REF_COUNT(m); *vec = m->ptr; /* The state will be adjusted by the call to init_module */ recursive_lock_unlock(&modules_lock); if (res != B_NO_ERROR) { vec = NULL; return res; } /* Only run the init routine if we have ref_cnt == 1. This should * indicate that we have just been loaded. */ if (m->ref_cnt == 1) res = init_module(m); return res; } int put_module(const char *path) { module *m = (module *)hash_get(modules_list, path, strlen(path)); if (!m) { dprintf("We don't seem to have a reference to module %s\n", path); return EINVAL; } DEC_MOD_REF_COUNT(m); if (m->ref_cnt == 0) { /* We have no more references to this module. Next, do we need to * keep_loaded? If we do just return; */ if (m->keep_loaded == false) { /* so we should be OK to unload the actual module file, but just * check first if ir provides any other modules that are still in use. */ uninit_module(m); if (m->module->ref_cnt == 0) unload_module_file(m->file); } } return B_NO_ERROR; }