/* * Copyright 2002-2004, Axel Dörfler, axeld@pinc-software.de. * Distributed under the terms of the MIT License. * * Copyright 2001-2002, Travis Geiselbrecht. All rights reserved. * Distributed under the terms of the NewOS License. */ /* Team functions */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include //#define TRACE_TEAM #ifdef TRACE_TEAM # define TRACE(x) dprintf x #else # define TRACE(x) ; #endif struct team_key { team_id id; }; struct team_arg { uint32 arg_count; char **args; uint32 env_count; char **env; }; struct fork_arg { area_id user_stack_area; addr_t user_stack_base; size_t user_stack_size; addr_t user_local_storage; struct arch_fork_arg arch_info; }; // team list static void *team_hash = NULL; static team_id next_team_id = 1; static struct team *kernel_team = NULL; // some arbitrary chosen limits - should probably depend on the available // memory (the limit is not yet enforced) static int32 sMaxTeams = 2048; static int32 sUsedTeams = 1; spinlock team_spinlock = 0; static void insert_group_into_session(struct process_session *session, struct process_group *group); static void insert_team_into_group(struct process_group *group, struct team *team); static struct process_session *create_process_session(pid_t id); static struct process_group *create_process_group(pid_t id); static struct team *create_team_struct(const char *name, bool kernel); static void delete_team_struct(struct team *p); static int team_struct_compare(void *_p, const void *_key); static uint32 team_struct_hash(void *_p, const void *_key, uint32 range); static void free_strings_array(char **strings, int32 count); static status_t user_copy_strings_array(char * const *strings, int32 count, char ***_strings); static void _dump_team_info(struct team *p); static int dump_team_info(int argc, char **argv); static void _dump_team_info(struct team *p) { dprintf("TEAM: %p\n", p); dprintf("id: 0x%lx\n", p->id); dprintf("name: '%s'\n", p->name); dprintf("next: %p\n", p->next); dprintf("parent: %p\n", p->parent); dprintf("children: %p\n", p->children); dprintf("num_threads: %d\n", p->num_threads); dprintf("state: %d\n", p->state); dprintf("pending_signals: 0x%x\n", p->pending_signals); dprintf("io_context: %p\n", p->io_context); // dprintf("path: '%s'\n", p->path); dprintf("aspace: %p (id = %ld)\n", p->aspace, p->aspace->id); dprintf("kaspace: %p\n", p->kaspace); dprintf("main_thread: %p\n", p->main_thread); dprintf("thread_list: %p\n", p->thread_list); } static int dump_team_info(int argc, char **argv) { struct team *p; int id = -1; unsigned long num; struct hash_iterator i; if (argc < 2) { dprintf("team: not enough arguments\n"); return 0; } // if the argument looks like a hex number, treat it as such if (strlen(argv[1]) > 2 && argv[1][0] == '0' && argv[1][1] == 'x') { num = strtoul(argv[1], NULL, 16); if (num > vm_get_kernel_aspace()->virtual_map.base) { // XXX semi-hack _dump_team_info((struct team*)num); return 0; } else { id = num; } } // walk through the thread list, trying to match name or id hash_open(team_hash, &i); while ((p = hash_next(team_hash, &i)) != NULL) { if ((p->name && strcmp(argv[1], p->name) == 0) || p->id == id) { _dump_team_info(p); break; } } hash_close(team_hash, &i, false); return 0; } status_t team_init(kernel_args *args) { struct process_session *session; struct process_group *group; // create the team hash table team_hash = hash_init(15, offsetof(struct team, next), &team_struct_compare, &team_struct_hash); // create initial session and process groups session = create_process_session(1); if (session == NULL) panic("Could not create initial session.\n"); group = create_process_group(1); if (group == NULL) panic("Could not create initial process group.\n"); insert_group_into_session(session, group); // create the kernel team kernel_team = create_team_struct("kernel_team", true); if (kernel_team == NULL) panic("could not create kernel team!\n"); kernel_team->state = TEAM_STATE_NORMAL; insert_team_into_group(group, kernel_team); kernel_team->io_context = vfs_new_io_context(NULL); if (kernel_team->io_context == NULL) panic("could not create io_context for kernel team!\n"); // stick it in the team hash hash_insert(team_hash, kernel_team); // B_SYSTEM_TEAM is reserved next_team_id = B_SYSTEM_TEAM + 1; add_debugger_command("team", &dump_team_info, "list info about a particular team"); return 0; } int32 team_max_teams(void) { return sMaxTeams; } int32 team_used_teams(void) { return sUsedTeams; } /** Frees an array of strings in kernel space. * * \param strings strings array * \param count number of strings in array */ static void free_strings_array(char **strings, int32 count) { int32 i; if (strings == NULL) return; for (i = 0; i < count; i++) free(strings[i]); free(strings); } /** Copy an array of strings in kernel space * * \param strings strings array to be copied * \param count number of strings in array * \param kstrings pointer to the kernel copy * \return \c B_OK on success, or an appropriate error code on * failure. */ static status_t copy_strings_array(const char **in, int32 count, char ***_strings) { status_t status; char **strings; int32 i = 0; strings = (char **)malloc((count + 1) * sizeof(char *)); if (strings == NULL) return B_NO_MEMORY; for (; i < count; i++) { strings[i] = strdup(in[i]); if (strings[i] == NULL) { status = B_NO_MEMORY; goto error; } } strings[count] = NULL; *_strings = strings; return B_OK; error: free_strings_array(strings, i); return status; } /** Copy an array of strings from user space to kernel space * * \param strings userspace strings array * \param count number of strings in array * \param kstrings pointer to the kernel copy * \return \c B_OK on success, or an appropriate error code on * failure. */ static status_t user_copy_strings_array(char * const *userStrings, int32 count, char ***_strings) { char buffer[SYS_THREAD_STRING_LENGTH_MAX]; char **strings; status_t err; int32 i = 0; if (!IS_USER_ADDRESS(userStrings)) return B_BAD_ADDRESS; strings = (char **)malloc((count + 1) * sizeof(char *)); if (strings == NULL) return B_NO_MEMORY; if ((err = user_memcpy(strings, userStrings, count * sizeof(char *))) < B_OK) goto error; // scan all strings and copy to kernel space for (; i < count; i++) { err = user_strlcpy(buffer, strings[i], SYS_THREAD_STRING_LENGTH_MAX); if (err < B_OK) goto error; strings[i] = strdup(buffer); if (strings[i] == NULL) { err = B_NO_MEMORY; goto error; } } strings[count] = NULL; *_strings = strings; return B_OK; error: free_strings_array(strings, i); TRACE(("user_copy_strings_array failed %ld\n", err)); return err; } /** Quick check to see if we have a valid team ID. */ bool team_is_valid(team_id id) { struct team *team; int state; if (id <= 0) return false; state = disable_interrupts(); GRAB_TEAM_LOCK(); team = team_get_team_struct_locked(id); RELEASE_TEAM_LOCK(); restore_interrupts(state); return team != NULL; } struct team * team_get_team_struct_locked(team_id id) { struct team_key key; key.id = id; return hash_lookup(team_hash, &key); } static int team_struct_compare(void *_p, const void *_key) { struct team *p = _p; const struct team_key *key = _key; if (p->id == key->id) return 0; return 1; } static uint32 team_struct_hash(void *_p, const void *_key, uint32 range) { struct team *p = _p; const struct team_key *key = _key; if (p != NULL) return p->id % range; return key->id % range; } static void insert_team_into_parent(struct team *parent, struct team *team) { ASSERT(parent != NULL); team->siblings_next = parent->children; parent->children = team; team->parent = parent; } /** Note: must have TEAM lock held */ static void remove_team_from_parent(struct team *parent, struct team *team) { struct team *child, *last = NULL; for (child = parent->children; child != NULL; child = child->siblings_next) { if (child == team) { if (last == NULL) parent->children = child->siblings_next; else last->siblings_next = child->siblings_next; team->parent = NULL; break; } last = child; } } /** Reparent each of our children * Note: must have TEAM lock held */ static void reparent_children(struct team *team) { struct team *child = team->children; while (child != NULL) { // remove the child from the current proc and add to the parent remove_team_from_parent(team, child); insert_team_into_parent(team->parent, child); child = team->children; } } static bool is_process_group_leader(struct team *team) { return team->group_id == team->main_thread->id; } static void insert_group_into_session(struct process_session *session, struct process_group *group) { if (group == NULL) return; group->session = session; list_add_link_to_tail(&session->groups, group); } static void insert_team_into_group(struct process_group *group, struct team *team) { team->group = group; team->group_id = group->id; team->session_id = group->session->id; atomic_add(&team->dead_children.wait_for_any, group->wait_for_any); team->group_next = group->teams; group->teams = team; } /** Removes a group from a session, and puts the session object * back into the session cache, if it's not used anymore. * You must hold the team lock when calling this function. */ static void remove_group_from_session(struct process_group *group) { struct process_session *session = group->session; // the group must be in any session to let this function have any effect if (session == NULL) return; list_remove_link(group); // we cannot free the resource here, so we're keeping the group link // around - this way it'll be freed by free_process_group() if (!list_is_empty(&session->groups)) group->session = NULL; } void team_delete_process_group(struct process_group *group) { if (group == NULL) return; TRACE(("team_delete_process_group(id = %ld)\n", group->id)); delete_sem(group->dead_child_sem); // remove_group_from_session() keeps this pointer around // only if the session can be freed as well if (group->session) { TRACE(("team_delete_process_group(): frees session %ld\n", group->session->id)); free(group->session); } free(group); } /** Removes the team from the group. If that group becomes therefore * unused, it will set \a _freeGroup to point to the group - otherwise * it will be \c NULL. * It cannot be freed here because this function has to be called * with having the team lock held. * * \param team the team that'll be removed from it's group * \param _freeGroup points to the group to be freed or NULL */ static void remove_team_from_group(struct team *team, struct process_group **_freeGroup) { struct process_group *group = team->group; struct team *current, *last = NULL; *_freeGroup = NULL; // the team must be in any team to let this function have any effect if (group == NULL) return; for (current = group->teams; current != NULL; current = current->group_next) { if (current == team) { if (last == NULL) group->teams = current->group_next; else last->group_next = current->group_next; team->group = NULL; break; } last = current; } // all wait_for_child() that wait on the group don't wait for us anymore atomic_add(&team->dead_children.wait_for_any, -group->wait_for_any); team->group = NULL; team->group_next = NULL; if (group->teams != NULL) return; // we can remove this group as it is no longer used remove_group_from_session(group); *_freeGroup = group; } static struct process_group * create_process_group(pid_t id) { struct process_group *group = (struct process_group *)malloc(sizeof(struct process_group)); if (group == NULL) return NULL; group->dead_child_sem = create_sem(0, "dead group children"); if (group->dead_child_sem < B_OK) { free(group); return NULL; } group->id = id; group->session = NULL; group->teams = NULL; group->wait_for_any = 0; return group; } static struct process_session * create_process_session(pid_t id) { struct process_session *session = (struct process_session *)malloc(sizeof(struct process_session)); if (session == NULL) return NULL; session->id = id; list_init(&session->groups); return session; } struct team * team_get_kernel_team(void) { return kernel_team; } team_id team_get_kernel_team_id(void) { if (!kernel_team) return 0; return kernel_team->id; } team_id team_get_current_team_id(void) { return thread_get_current_thread()->team->id; } status_t team_get_address_space(team_id id, vm_address_space **_addressSpace) { cpu_status state; struct team *team; status_t status; // ToDo: we need to do something about B_SYSTEM_TEAM vs. its real ID (1) if (id == 1) { // we're the kernel team, so we don't have to go through all // the hassle (locking and hash lookup) atomic_add(&kernel_team->kaspace->ref_count, 1); *_addressSpace = kernel_team->kaspace; return B_OK; } state = disable_interrupts(); GRAB_TEAM_LOCK(); team = team_get_team_struct_locked(id); if (team != NULL) { atomic_add(&team->aspace->ref_count, 1); *_addressSpace = team->aspace; status = B_OK; } else status = B_BAD_VALUE; RELEASE_TEAM_LOCK(); restore_interrupts(state); return status; } static struct team * create_team_struct(const char *name, bool kernel) { struct team *team = (struct team *)malloc(sizeof(struct team)); if (team == NULL) return NULL; team->next = team->siblings_next = team->children = team->parent = NULL; team->id = atomic_add(&next_team_id, 1); strlcpy(team->name, name, B_OS_NAME_LENGTH); team->num_threads = 0; team->io_context = NULL; team->aspace = NULL; team->kaspace = vm_get_kernel_aspace(); vm_put_aspace(team->kaspace); team->thread_list = NULL; team->main_thread = NULL; team->state = TEAM_STATE_BIRTH; team->pending_signals = 0; team->death_sem = -1; team->user_env_base = 0; team->dead_threads_kernel_time = 0; team->dead_threads_user_time = 0; list_init(&team->dead_children.list); team->dead_children.count = 0; team->dead_children.wait_for_any = 0; team->dead_children.kernel_time = 0; team->dead_children.user_time = 0; team->dead_children.sem = create_sem(0, "dead children"); if (team->dead_children.sem < B_OK) goto error1; list_init(&team->image_list); if (arch_team_init_team_struct(team, kernel) < 0) goto error2; return team; error2: delete_sem(team->dead_children.sem); error1: free(team); return NULL; } static void delete_team_struct(struct team *team) { struct death_entry *death = NULL; delete_sem(team->dead_children.sem); while ((death = list_get_next_item(&team->dead_children.list, death)) != NULL) free(death); free(team); } /** Removes the specified team from the global team hash, and from its parent. * It also moves all of its children up to the parent. * You must hold the team lock when you call this function. * If \a _freeGroup is set to a value other than \c NULL, it must be freed * from the calling function. */ void team_remove_team(struct team *team, struct process_group **_freeGroup) { hash_remove(team_hash, team); sUsedTeams--; team->state = TEAM_STATE_DEATH; // reparent each of the team's children reparent_children(team); // remove us from our process group remove_team_from_group(team, _freeGroup); // remove us from our parent remove_team_from_parent(team->parent, team); } void team_delete_team(struct team *team) { if (team->num_threads > 0) { // there are other threads still in this team, // cycle through and signal kill on each of the threads // ToDo: this can be optimized. There's got to be a better solution. struct thread *temp_thread; char death_sem_name[B_OS_NAME_LENGTH]; cpu_status state; sprintf(death_sem_name, "team %ld death sem", team->id); team->death_sem = create_sem(0, death_sem_name); if (team->death_sem < 0) panic("thread_exit: cannot init death sem for team %ld\n", team->id); state = disable_interrupts(); GRAB_TEAM_LOCK(); // we can safely walk the list because of the lock. no new threads can be created // because of the TEAM_STATE_DEATH flag on the team temp_thread = team->thread_list; while (temp_thread) { struct thread *next = temp_thread->team_next; send_signal_etc(temp_thread->id, SIGKILLTHR, B_DO_NOT_RESCHEDULE); temp_thread = next; } RELEASE_TEAM_LOCK(); restore_interrupts(state); // wait until all threads in team are dead. acquire_sem_etc(team->death_sem, team->num_threads, 0, 0); delete_sem(team->death_sem); } // free team resources vm_delete_aspace(team->aspace); delete_owned_ports(team->id); sem_delete_owned_sems(team->id); remove_images(team); vfs_free_io_context(team->io_context); free(team); } static uint32 get_arguments_data_size(char **args, int32 argc) { uint32 size = 0; int32 count; for (count = 0; count < argc; count++) size += strlen(args[count]) + 1; return size + (argc + 1) * sizeof(char *) + sizeof(struct uspace_program_args); } static void free_team_arg(struct team_arg *teamArg) { free_strings_array(teamArg->args, teamArg->arg_count); free_strings_array(teamArg->env, teamArg->env_count); free(teamArg); } static struct team_arg * create_team_arg(int32 argc, char **args, int32 envCount, char **env) { struct team_arg *teamArg = (struct team_arg *)malloc(sizeof(struct team_arg)); if (teamArg == NULL) return NULL; teamArg->arg_count = argc; teamArg->args = args; teamArg->env_count = envCount; teamArg->env = env; return teamArg; } static int32 team_create_thread_start(void *args) { int err; struct thread *t; struct team *team; struct team_arg *teamArgs = args; const char *path; addr_t entry; char ustack_name[128]; uint32 sizeLeft; char **uargs; char **uenv; char *udest; struct uspace_program_args *uspa; uint32 argCount, envCount, i; t = thread_get_current_thread(); team = t->team; TRACE(("team_create_thread_start: entry thread %ld\n", t->id)); // create an initial primary stack area // Main stack area layout is currently as follows (starting from 0): // // size | usage // -----------------------------+-------------------------------- // USER_MAIN_THREAD_STACK_SIZE | actual stack // TLS_SIZE | TLS data // ENV_SIZE | environment variables // arguments size | arguments passed to the team // ToDo: make ENV_SIZE variable and put it on the heap? // ToDo: we could reserve the whole USER_STACK_REGION upfront... sizeLeft = PAGE_ALIGN(USER_MAIN_THREAD_STACK_SIZE + TLS_SIZE + ENV_SIZE + get_arguments_data_size(teamArgs->args, teamArgs->arg_count)); t->user_stack_base = USER_STACK_REGION + USER_STACK_REGION_SIZE - sizeLeft; t->user_stack_size = USER_MAIN_THREAD_STACK_SIZE; // the exact location at the end of the user stack area sprintf(ustack_name, "%s_main_stack", team->name); t->user_stack_area = create_area_etc(team, ustack_name, (void **)&t->user_stack_base, B_EXACT_ADDRESS, sizeLeft, B_NO_LOCK, B_READ_AREA | B_WRITE_AREA | B_STACK_AREA); if (t->user_stack_area < 0) { dprintf("team_create_thread_start: could not create default user stack region\n"); return t->user_stack_area; } // now that the TLS area is allocated, initialize TLS arch_thread_init_tls(t); argCount = teamArgs->arg_count; envCount = teamArgs->env_count; uspa = (struct uspace_program_args *)(t->user_stack_base + t->user_stack_size + TLS_SIZE + ENV_SIZE); uargs = (char **)(uspa + 1); udest = (char *)(uargs + argCount + 1); TRACE(("addr: stack base = 0x%lx, uargs = %p, udest = %p, sizeLeft = %lu\n", t->user_stack_base, uargs, udest, sizeLeft)); sizeLeft = t->user_stack_base + sizeLeft - (addr_t)udest; for (i = 0; i < argCount; i++) { ssize_t length = user_strlcpy(udest, teamArgs->args[i], sizeLeft); if (length < B_OK) { argCount = 0; break; } uargs[i] = udest; udest += ++length; sizeLeft -= length; } uargs[argCount] = NULL; team->user_env_base = t->user_stack_base + t->user_stack_size + TLS_SIZE; uenv = (char **)team->user_env_base; udest = (char *)team->user_env_base + ENV_SIZE - 1; // the environment variables are copied from back to front TRACE(("team_create_thread_start: envc: %ld, env: %p\n", teamArgs->env_count, (void *)teamArgs->env)); for (i = 0; i < envCount; i++) { ssize_t length = strlen(teamArgs->env[i]) + 1; udest -= length; uenv[i] = udest; if (user_memcpy(udest, teamArgs->env[i], length) < B_OK) { envCount = 0; break; } sizeLeft -= length; } uenv[envCount] = NULL; path = teamArgs->args[0]; user_memcpy(uspa->program_path, path, sizeof(uspa->program_path)); uspa->argc = argCount; uspa->argv = uargs; uspa->envc = envCount; uspa->envp = uenv; TRACE(("team_create_thread_start: loading elf binary '%s'\n", path)); free_team_arg(teamArgs); // ToDo: don't use fixed paths! err = elf_load_user_image("/boot/beos/system/lib/rld.so", team, 0, &entry); if (err < 0) { // Luckily, we don't have to clean up the mess we created - that's // done for us by the normal team deletion process return err; } TRACE(("team_create_thread_start: loaded elf. entry = 0x%lx\n", entry)); team->state = TEAM_STATE_NORMAL; // jump to the entry point in user space arch_thread_enter_uspace(t, entry, uspa, NULL); // never gets here return 0; } /** The BeOS kernel exports a function with this name, but most probably with * different parameters; we should not make it public. */ static thread_id load_image_etc(int32 argCount, char **args, int32 envCount, char **env, int32 priority) { struct process_group *group; struct team *team, *parent; const char *threadName; thread_id thread; int err; cpu_status state; struct team_arg *teamArgs; if (args == NULL || argCount == 0) return B_BAD_VALUE; TRACE(("load_image_etc: name '%s', args = %p, argCount = %ld\n", args[0], args, argCount)); team = create_team_struct(args[0], false); if (team == NULL) return B_NO_MEMORY; parent = thread_get_current_thread()->team; state = disable_interrupts(); GRAB_TEAM_LOCK(); hash_insert(team_hash, team); insert_team_into_parent(parent, team); insert_team_into_group(parent->group, team); sUsedTeams++; RELEASE_TEAM_LOCK(); restore_interrupts(state); // copy the args over teamArgs = create_team_arg(argCount, args, envCount, env); if (teamArgs == NULL) { err = B_NO_MEMORY; goto err1; } // create a new io_context for this team team->io_context = vfs_new_io_context(parent->io_context); if (!team->io_context) { err = B_NO_MEMORY; goto err2; } // create an address space for this team err = vm_create_aspace(team->name, USER_BASE, USER_SIZE, false, &team->aspace); if (err < B_OK) goto err3; // cut the path from the main thread name threadName = strrchr(args[0], '/'); if (threadName != NULL) threadName++; else threadName = args[0]; // create a kernel thread, but under the context of the new team thread = spawn_kernel_thread_etc(team_create_thread_start, threadName, B_NORMAL_PRIORITY, teamArgs, team->id); if (thread < 0) { err = thread; goto err4; } return thread; err4: vm_put_aspace(team->aspace); err3: vfs_free_io_context(team->io_context); err2: free_team_arg(teamArgs); err1: // remove the team structure from the team hash table and delete the team structure state = disable_interrupts(); GRAB_TEAM_LOCK(); remove_team_from_group(team, &group); remove_team_from_parent(parent, team); hash_remove(team_hash, team); RELEASE_TEAM_LOCK(); restore_interrupts(state); team_delete_process_group(group); delete_team_struct(team); return err; } /** Almost shuts down the current team and loads a new image into it. * If successful, this function does not return and will takeover ownership of * the arguments provided. */ static status_t exec_team(int32 argCount, char **args, int32 envCount, char **env) { struct team *team = thread_get_current_thread()->team; struct team_arg *teamArgs; const char *threadName; status_t status; TRACE(("exec_team(path = \"%s\", argc = %ld, envCount = %ld)\n", args[0], argCount, envCount)); // switching the kernel at run time is probably not a good idea :) if (team == team_get_kernel_team()) return B_NOT_ALLOWED; // we currently need to be single threaded here // ToDo: maybe we should just kill all other threads and // make the current thread the team's main thread? if (team->main_thread != thread_get_current_thread() || team->main_thread != team->thread_list || team->main_thread->team_next != NULL) return B_NOT_ALLOWED; // ToDo: maybe we should make sure upfront that the target path is an app? teamArgs = create_team_arg(argCount, args, envCount, env); if (teamArgs == NULL) return B_NO_MEMORY; // ToDo: remove team resources if there are any left // alarm, signals // thread_atkernel_exit() might not be called at all vm_delete_areas(team->aspace); delete_owned_ports(team->id); sem_delete_owned_sems(team->id); remove_images(team); vfs_exec_io_context(team->io_context); // rename the team strlcpy(team->name, args[0], B_OS_NAME_LENGTH); // cut the path from the team name and rename the main thread, too threadName = strrchr(args[0], '/'); if (threadName != NULL) threadName++; else threadName = args[0]; rename_thread(thread_get_current_thread_id(), threadName); status = team_create_thread_start(teamArgs); // this one usually doesn't return... // sorry, we have to kill us, there is no way out anymore (without any areas left and all that) exit_thread(status); // we'll never make it here return B_ERROR; } /** This is the first function to be called from the newly created * main child thread. * It will fill in everything what's left to do from fork_arg, and * return from the parent's fork() syscall to the child. */ static int32 fork_team_thread_start(void *_args) { struct thread *thread = thread_get_current_thread(); struct fork_arg *forkArgs = (struct fork_arg *)_args; struct arch_fork_arg archArgs = forkArgs->arch_info; // we need a local copy of the arch dependent part thread->user_stack_area = forkArgs->user_stack_area; thread->user_stack_base = forkArgs->user_stack_base; thread->user_stack_size = forkArgs->user_stack_size; thread->user_local_storage = forkArgs->user_local_storage; arch_thread_init_tls(thread); free(forkArgs); // set frame of the parent thread to this one, too arch_restore_fork_frame(&archArgs); // This one won't return here return 0; } static thread_id fork_team(void) { struct team *parentTeam = thread_get_current_thread()->team, *team; struct thread *parentThread = thread_get_current_thread(); struct process_group *group = NULL; struct fork_arg *forkArgs; struct area_info info; thread_id threadID; cpu_status state; status_t status; int32 cookie; TRACE(("fork_team()\n")); if (parentTeam == team_get_kernel_team()) return B_NOT_ALLOWED; // create a new team // ToDo: this is very similar to team_create_team() - maybe we can do something about it :) team = create_team_struct(parentTeam->name, false); if (team == NULL) return B_NO_MEMORY; state = disable_interrupts(); GRAB_TEAM_LOCK(); hash_insert(team_hash, team); insert_team_into_parent(parentTeam, team); insert_team_into_group(parentTeam->group, team); sUsedTeams++; RELEASE_TEAM_LOCK(); restore_interrupts(state); forkArgs = (struct fork_arg *)malloc(sizeof(struct fork_arg)); if (forkArgs == NULL) { status = B_NO_MEMORY; goto err1; } // create a new io_context for this team team->io_context = vfs_new_io_context(parentTeam->io_context); if (!team->io_context) { status = B_NO_MEMORY; goto err2; } // create an address space for this team status = vm_create_aspace(team->name, USER_BASE, USER_SIZE, false, &team->aspace); if (status < B_OK) goto err3; // copy all areas of the team // ToDo: should be able to handle stack areas differently (ie. don't have them copy-on-write) // ToDo: all stacks of other threads than the current one could be left out cookie = 0; while (get_next_area_info(B_CURRENT_TEAM, &cookie, &info) == B_OK) { void *address; area_id area = vm_copy_area(team->aspace->id, info.name, &address, B_CLONE_ADDRESS, info.protection, info.area); if (area < B_OK) { status = area; break; } if (info.area == parentThread->user_stack_area) forkArgs->user_stack_area = area; } if (status < B_OK) goto err4; forkArgs->user_stack_base = parentThread->user_stack_base; forkArgs->user_stack_size = parentThread->user_stack_size; forkArgs->user_local_storage = parentThread->user_local_storage; arch_store_fork_frame(&forkArgs->arch_info); team->user_env_base = parentTeam->user_env_base; // ToDo: copy image list // create a kernel thread under the context of the new team threadID = spawn_kernel_thread_etc(fork_team_thread_start, parentThread->name, parentThread->priority, forkArgs, team->id); if (threadID < 0) { status = threadID; goto err4; } resume_thread(threadID); return threadID; err4: vm_delete_aspace(team->aspace); err3: vfs_free_io_context(team->io_context); err2: free(forkArgs); err1: // remove the team structure from the team hash table and delete the team structure state = disable_interrupts(); GRAB_TEAM_LOCK(); remove_team_from_group(team, &group); remove_team_from_parent(parentTeam, team); hash_remove(team_hash, team); RELEASE_TEAM_LOCK(); restore_interrupts(state); team_delete_process_group(group); delete_team_struct(team); return status; } /** This searches the session of the team for the specified group ID. * You must hold the team lock when you call this function. */ static struct process_group * get_process_group_locked(struct team *team, pid_t id) { struct list *groups = &team->group->session->groups; struct process_group *group = NULL; // ToDo: a process group lasts as long as its last member - and // that doesn't have to be the process leader. IOW we need // a separate hash table for those groups without a leader. // a short cut when the current team's group is asked for if (team->group->id == id) return team->group; while ((group = list_get_next_item(groups, group)) != NULL) { if (group->id == id) return group; } return NULL; } static status_t update_wait_for_any(struct team *team, thread_id child, int32 change) { struct process_group *group; cpu_status state; if (child > 0) return B_OK; if (child == -1) { // we only wait for children of the current team atomic_add(&team->dead_children.wait_for_any, change); return B_OK; } state = disable_interrupts(); GRAB_TEAM_LOCK(); if (child < 0) { // we wait for all children of the specified process group group = get_process_group_locked(team, -child); } else { // we wait for any children of the current team's group group = team->group; } if (group != NULL) { for (team = group->teams; team; team = team->group_next) { atomic_add(&team->dead_children.wait_for_any, change); } atomic_add(&group->wait_for_any, change); } RELEASE_TEAM_LOCK(); restore_interrupts(state); return group != NULL ? B_OK : B_BAD_THREAD_ID; } static status_t unregister_wait_for_any(struct team *team, thread_id child) { return update_wait_for_any(team, child, -1); } static status_t register_wait_for_any(struct team *team, thread_id child) { return update_wait_for_any(team, child, 1); } static status_t get_team_death_entry(struct team *team, thread_id child, struct death_entry *death, struct death_entry **_freeDeath) { struct death_entry *entry = NULL; // find matching death entry structure while ((entry = list_get_next_item(&team->dead_children.list, entry)) != NULL) { if (child != -1 && entry->thread != child) continue; // we found one *death = *entry; // only remove the death entry if there aren't any other interested parties if ((child == -1 && atomic_add(&team->dead_children.wait_for_any, -1) == 1) || (child != -1 && team->dead_children.wait_for_any == 0)) { list_remove_link(entry); team->dead_children.count--; *_freeDeath = entry; } return B_OK; } return child > 0 ? B_BAD_THREAD_ID : B_WOULD_BLOCK; } static status_t get_death_entry(struct team *team, pid_t child, struct death_entry *death, sem_id *_waitSem, struct death_entry **_freeDeath) { struct process_group *group; status_t status; if (child == -1 || child > 0) { // wait for any children or a specific child of this team to die *_waitSem = team->dead_children.sem; return get_team_death_entry(team, child, death, _freeDeath); } else if (child < 0) { // we wait for all children of the specified process group group = get_process_group_locked(team, -child); if (group == NULL) return B_BAD_THREAD_ID; } else { // we wait for any children of the current team's group group = team->group; } for (team = group->teams; team; team = team->group_next) { status = get_team_death_entry(team, -1, death, _freeDeath); if (status == B_OK) { atomic_add(&group->wait_for_any, -1); return B_OK; } } *_waitSem = group->dead_child_sem; return B_WOULD_BLOCK; } /** This is the kernel backend for waitpid(). It is a bit more powerful when it comes * to the reason why a thread has died than waitpid() can be. */ static thread_id wait_for_child(thread_id child, uint32 flags, int32 *_reason, status_t *_returnCode) { struct team *team = thread_get_current_thread()->team; struct death_entry death, *freeDeath = NULL; status_t status = B_OK; sem_id waitSem; cpu_status state; TRACE(("wait_for_child(child = %ld, flags = %ld)\n", child, flags)); if (child == 0 || child < -1) { dprintf("wait_for_child() process group ID waiting not yet implemented!\n"); return EOPNOTSUPP; } if (child <= 0) { // we need to make sure the death entries won't get deleted too soon status = register_wait_for_any(team, child); if (status != B_OK) return status; } while (true) { if (child > 0) { // wait for the specified child if (thread_get_thread_struct(child) != NULL) { // team is still running, so we would need to block return B_WOULD_BLOCK; } } // see if there is any death entry for us already state = disable_interrupts(); GRAB_TEAM_LOCK(); status = get_death_entry(team, child, &death, &waitSem, &freeDeath); RELEASE_TEAM_LOCK(); restore_interrupts(state); // we got our death entry and can return to our caller if (status == B_OK) break; // there was no matching group/child we could wait for if (status == B_BAD_THREAD_ID) goto err; if ((flags & WNOHANG) != 0) { status = B_WOULD_BLOCK; goto err; } status = acquire_sem(waitSem); if (status == B_INTERRUPTED) goto err; } free(freeDeath); // when we got here, we have a valid death entry, and // already got unregistered from the team or group *_returnCode = death.status; *_reason = death.reason; return death.thread; err: unregister_wait_for_any(team, child); return status; } // #pragma mark - // public team API thread_id load_image(int32 argCount, const char **args, const char **env) { char **argsCopy, **envCopy; int32 envCount = 0; if (copy_strings_array(args, argCount, &argsCopy) != B_OK) return B_NO_MEMORY; // count env variables while (env && env[envCount] != NULL) envCount++; if (copy_strings_array(env, envCount, &envCopy) != B_OK) { free_strings_array(argsCopy, argCount); return B_NO_MEMORY; } return load_image_etc(argCount, argsCopy, envCount, envCopy, B_NORMAL_PRIORITY); } status_t wait_for_team(team_id id, status_t *_returnCode) { struct team *team; thread_id thread; cpu_status state; // find main thread and wait for that state = disable_interrupts(); GRAB_TEAM_LOCK(); team = team_get_team_struct_locked(id); if (team && team->main_thread) thread = team->main_thread->id; else thread = B_BAD_THREAD_ID; RELEASE_TEAM_LOCK(); restore_interrupts(state); if (thread < 0) return thread; return wait_for_thread(thread, _returnCode); } status_t kill_team(team_id id) { int state; struct team *team; // struct thread *t; thread_id tid = -1; int retval = 0; state = disable_interrupts(); GRAB_TEAM_LOCK(); team = team_get_team_struct_locked(id); if (team != NULL) tid = team->main_thread->id; else retval = B_BAD_THREAD_ID; RELEASE_TEAM_LOCK(); restore_interrupts(state); if (retval < 0) return retval; // just kill the main thread in the team. The cleanup code there will // take care of the team return kill_thread(tid); } /** Fills the team_info structure with information from the specified * team. * The team lock must be held when called. */ static status_t fill_team_info(struct team *team, team_info *info, size_t size) { if (size != sizeof(team_info)) return B_BAD_VALUE; // ToDo: Set more informations for team_info memset(info, 0, size); info->team = team->id; info->thread_count = team->num_threads; info->image_count = count_images(team); //info->area_count = //info->debugger_nub_thread = //info->debugger_nub_port = //info->argc = //info->args[64] = //info->uid = //info->gid = // ToDo: make this to return real argc/argv strlcpy(info->args, team->name, sizeof(info->args)); info->argc = 1; return B_OK; } status_t _get_team_info(team_id id, team_info *info, size_t size) { int state; status_t rc = B_OK; struct team *team; state = disable_interrupts(); GRAB_TEAM_LOCK(); if (id == B_CURRENT_TEAM) team = thread_get_current_thread()->team; else team = team_get_team_struct_locked(id); if (team == NULL) { rc = B_BAD_TEAM_ID; goto err; } rc = fill_team_info(team, info, size); err: RELEASE_TEAM_LOCK(); restore_interrupts(state); return rc; } status_t _get_next_team_info(int32 *cookie, team_info *info, size_t size) { status_t status = B_BAD_TEAM_ID; struct team *team = NULL; int32 slot = *cookie; int state = disable_interrupts(); GRAB_TEAM_LOCK(); if (slot >= next_team_id) goto err; // get next valid team while ((slot < next_team_id) && !(team = team_get_team_struct_locked(slot))) slot++; if (team) { status = fill_team_info(team, info, size); *cookie = ++slot; } err: RELEASE_TEAM_LOCK(); restore_interrupts(state); return status; } status_t _get_team_usage_info(team_id id, int32 who, team_usage_info *info, size_t size) { bigtime_t kernelTime = 0, userTime = 0; status_t status = B_OK; struct team *team; cpu_status state; if (size != sizeof(team_usage_info) || (who != B_TEAM_USAGE_SELF && who != B_TEAM_USAGE_CHILDREN)) return B_BAD_VALUE; state = disable_interrupts(); GRAB_TEAM_LOCK(); if (id == B_CURRENT_TEAM) team = thread_get_current_thread()->team; else team = team_get_team_struct_locked(id); if (team == NULL) { status = B_BAD_TEAM_ID; goto out; } switch (who) { case B_TEAM_USAGE_SELF: { struct thread *thread = team->thread_list; for (; thread != NULL; thread = thread->team_next) { kernelTime += thread->kernel_time; userTime += thread->user_time; } kernelTime += team->dead_threads_kernel_time; userTime += team->dead_threads_user_time; break; } case B_TEAM_USAGE_CHILDREN: { struct team *child = team->children; for (; child != NULL; child = child->siblings_next) { struct thread *thread = team->thread_list; for (; thread != NULL; thread = thread->team_next) { kernelTime += thread->kernel_time; userTime += thread->user_time; } kernelTime += child->dead_threads_kernel_time; userTime += child->dead_threads_user_time; } kernelTime += team->dead_children.kernel_time; userTime += team->dead_children.user_time; break; } } out: RELEASE_TEAM_LOCK(); restore_interrupts(state); if (status == B_OK) { info->kernel_time = kernelTime; info->user_time = userTime; } return status; } pid_t getpid(void) { return thread_get_current_thread()->team->main_thread->id; } pid_t getppid(void) { struct team *team = thread_get_current_thread()->team; cpu_status state; pid_t parent; state = disable_interrupts(); GRAB_TEAM_LOCK(); parent = team->parent->main_thread->id; RELEASE_TEAM_LOCK(); restore_interrupts(state); return parent; } pid_t getpgid(pid_t process) { struct thread *thread; pid_t result = -1; cpu_status state; if (process == 0) process = thread_get_current_thread()->team->main_thread->id; state = disable_interrupts(); GRAB_THREAD_LOCK(); thread = thread_get_thread_struct_locked(process); if (thread != NULL) result = thread->team->group_id; RELEASE_THREAD_LOCK(); restore_interrupts(state); return thread != NULL ? result : B_BAD_VALUE; } pid_t getsid(pid_t process) { struct thread *thread; pid_t result = -1; cpu_status state; if (process == 0) process = thread_get_current_thread()->team->main_thread->id; state = disable_interrupts(); GRAB_THREAD_LOCK(); thread = thread_get_thread_struct_locked(process); if (thread != NULL) result = thread->team->session_id; RELEASE_THREAD_LOCK(); restore_interrupts(state); return thread != NULL ? result : B_BAD_VALUE; } // #pragma mark - // syscalls int sys_setenv(const char *name, const char *value, int overwrite) { char var[SYS_THREAD_STRING_LENGTH_MAX]; // int state; addr_t env_space; char **envp; int envc; bool var_exists = false; int var_pos = 0; int name_size; int rc = 0; int i; char *p; // ToDo: please put me out of the kernel into libroot.so! TRACE(("sys_setenv: entry (name=%s, value=%s)\n", name, value)); if (strlen(name) + strlen(value) + 1 >= SYS_THREAD_STRING_LENGTH_MAX) return -1; env_space = thread_get_current_thread()->team->user_env_base; // ToDo: this is totally broken! // (temporary fix is to do this with interrupts enabled) // state = disable_interrupts(); // GRAB_TEAM_LOCK(); strcpy(var, name); strncat(var, "=", SYS_THREAD_STRING_LENGTH_MAX-1); name_size = strlen(var); strncat(var, value, SYS_THREAD_STRING_LENGTH_MAX-1); envp = (char **)env_space; for (envc = 0; envp[envc]; envc++) { if (!strncmp(envp[envc], var, name_size)) { var_exists = true; var_pos = envc; } } if (!var_exists) var_pos = envc; TRACE(("sys_setenv: variable does%s exist\n", var_exists ? "" : " not")); if ((!var_exists) || (var_exists && overwrite)) { // XXX- make a better allocator if (var_exists) { if (strlen(var) <= strlen(envp[var_pos])) { strcpy(envp[var_pos], var); } else { for (p = (char *)env_space + ENV_SIZE - 1, i = 0; envp[i]; i++) if (envp[i] < p) p = envp[i]; p -= (strlen(var) + 1); if (p < (char *)env_space + (envc * sizeof(char *))) { rc = -1; } else { envp[var_pos] = p; strcpy(envp[var_pos], var); } } } else { for (p = (char *)env_space + ENV_SIZE - 1, i=0; envp[i]; i++) if (envp[i] < p) p = envp[i]; p -= (strlen(var) + 1); if (p < (char *)env_space + ((envc + 1) * sizeof(char *))) { rc = -1; } else { envp[envc] = p; strcpy(envp[envc], var); envp[envc + 1] = NULL; } } } TRACE(("sys_setenv: variable set.\n")); // RELEASE_TEAM_LOCK(); // restore_interrupts(state); return rc; } int sys_getenv(const char *name, char **value) { char **envp; char *p; // int state; int i; int len = strlen(name); int rc = -1; // ToDo: please put me out of the kernel into libroot.so! // ToDo: this is totally broken! // (temporary fix is to do this with interrupts enabled) envp = (char **)thread_get_current_thread()->team->user_env_base; // state = disable_interrupts(); // GRAB_TEAM_LOCK(); for (i = 0; envp[i]; i++) { if (!strncmp(envp[i], name, len)) { p = envp[i] + len; if (*p == '=') { *value = (p + 1); rc = 0; break; } } } // RELEASE_TEAM_LOCK(); // restore_interrupts(state); return rc; } // #pragma mark - // User syscalls status_t _user_exec(const char *userPath, int32 argCount, char * const *userArgs, int32 envCount, char * const *userEnvironment) { char path[B_PATH_NAME_LENGTH]; status_t status; char **args; char **env; if (argCount < 1) return B_BAD_VALUE; if (!IS_USER_ADDRESS(userPath) || !IS_USER_ADDRESS(userArgs) || !IS_USER_ADDRESS(userEnvironment) || user_strlcpy(path, userPath, sizeof(path)) < B_OK) return B_BAD_ADDRESS; status = user_copy_strings_array(userArgs, argCount, &args); if (status < B_OK) return status; status = user_copy_strings_array(userEnvironment, envCount, &env); if (status < B_OK) { free_strings_array(args, argCount); return status; } // replace args[0] with the path argument, just to be on the safe side free(args[0]); args[0] = strdup(path); status = exec_team(argCount, args, envCount, env); // this one only returns in case of error free_strings_array(args, argCount); free_strings_array(env, envCount); return status; } thread_id _user_fork(void) { return fork_team(); } thread_id _user_wait_for_child(thread_id child, uint32 flags, int32 *_userReason, status_t *_userReturnCode) { status_t returnCode; int32 reason; thread_id deadChild; if ((_userReason != NULL && !IS_USER_ADDRESS(_userReason)) || (_userReturnCode != NULL && !IS_USER_ADDRESS(_userReturnCode))) return B_BAD_ADDRESS; deadChild = wait_for_child(child, flags, &reason, &returnCode); if (deadChild >= B_OK) { // copy result data on successful completion if ((_userReason != NULL && user_memcpy(_userReason, &reason, sizeof(int32)) < B_OK) || (_userReturnCode != NULL && user_memcpy(_userReturnCode, &returnCode, sizeof(status_t)) < B_OK)) return B_BAD_ADDRESS; } return deadChild; } pid_t _user_process_info(pid_t process, int32 which) { // we only allow to return the parent of the current process if (which == PARENT_ID && process != 0 && process != thread_get_current_thread()->team->main_thread->id) return B_BAD_VALUE; switch (which) { case SESSION_ID: return getsid(process); case GROUP_ID: return getpgid(process); case PARENT_ID: return getppid(); } return B_BAD_VALUE; } pid_t _user_setpgid(pid_t processID, pid_t groupID) { struct team *currentTeam = thread_get_current_thread()->team; struct process_group *group = NULL, *freeGroup = NULL; struct thread *thread; struct team *team; cpu_status state; team_id teamID = -1; status_t status = B_OK; if (groupID < 0) return B_BAD_VALUE; if (processID == 0) { // get our own process ID processID = currentTeam->main_thread->id; teamID = currentTeam->id; // we must not change our process group ID if we're a group leader if (is_process_group_leader(currentTeam)) return B_NOT_ALLOWED; status = B_OK; } else { state = disable_interrupts(); GRAB_THREAD_LOCK(); thread = thread_get_thread_struct_locked(processID); // the thread must be the team's main thread, as that // determines its process ID if (thread != NULL && thread == thread->team->main_thread) { // check if the thread is in a child team of the calling team and // if it's already a process group leader and in the same session if (thread->team->parent != currentTeam || is_process_group_leader(thread->team) || thread->team->session_id != currentTeam->session_id) status = B_NOT_ALLOWED; else teamID = thread->team->id; } else status = B_BAD_THREAD_ID; RELEASE_THREAD_LOCK(); restore_interrupts(state); } if (status != B_OK) return status; // if the group ID is not specified, a new group should be created if (groupID == 0) groupID = processID; if (groupID == processID) { // We need to create a new process group for this team group = create_process_group(groupID); if (group == NULL) return B_NO_MEMORY; } state = disable_interrupts(); GRAB_TEAM_LOCK(); team = team_get_team_struct_locked(teamID); if (team != NULL) { if (processID == groupID) { // we created a new process group, let us insert it into the team's session insert_group_into_session(team->group->session, group); remove_team_from_group(team, &freeGroup); insert_team_into_group(group, team); } else { struct process_session *session = team->group->session; struct process_group *group = NULL; // check if this team can have the group ID; there must be one matching // process ID in the team's session while ((group = list_get_next_item(&session->groups, group)) != NULL) { if (group->id == groupID) break; } if (group) { // we got a group, let's move the team there remove_team_from_group(team, &freeGroup); insert_team_into_group(group, team); } else status = B_NOT_ALLOWED; } } else status = B_NOT_ALLOWED; RELEASE_TEAM_LOCK(); restore_interrupts(state); if (status != B_OK && group != NULL) team_delete_process_group(group); team_delete_process_group(freeGroup); return status == B_OK ? groupID : status; } pid_t _user_setsid(void) { struct team *team = thread_get_current_thread()->team; struct process_session *session; struct process_group *group, *freeGroup = NULL; cpu_status state; bool failed = false; // the team must not already be a process group leader if (is_process_group_leader(team)) return B_NOT_ALLOWED; group = create_process_group(team->main_thread->id); if (group == NULL) return B_NO_MEMORY; session = create_process_session(group->id); if (session == NULL) { team_delete_process_group(group); return B_NO_MEMORY; } state = disable_interrupts(); GRAB_TEAM_LOCK(); // this may have changed since the check above if (!is_process_group_leader(team)) { remove_team_from_group(team, &freeGroup); insert_group_into_session(session, group); insert_team_into_group(group, team); } else failed = true; RELEASE_TEAM_LOCK(); restore_interrupts(state); if (failed) { team_delete_process_group(group); free(session); return B_NOT_ALLOWED; } else team_delete_process_group(freeGroup); return team->group_id; } status_t _user_wait_for_team(team_id id, status_t *_userReturnCode) { status_t returnCode; status_t status; if (_userReturnCode != NULL && !IS_USER_ADDRESS(_userReturnCode)) return B_BAD_ADDRESS; status = wait_for_team(id, &returnCode); if (status >= B_OK && _userReturnCode != NULL) { if (user_memcpy(_userReturnCode, &returnCode, sizeof(returnCode)) < B_OK) return B_BAD_ADDRESS; } return status; } team_id _user_load_image(int32 argCount, const char **userArgs, int32 envCount, const char **userEnv, int32 priority) { char **args = NULL; char **env = NULL; TRACE(("_user_load_image_etc: argc = %ld\n", argCount)); if (argCount < 1 || userArgs == NULL || userEnv == NULL) return B_BAD_VALUE; if (!IS_USER_ADDRESS(userArgs) || !IS_USER_ADDRESS(userEnv) || user_copy_strings_array((char * const *)userArgs, argCount, &args) < B_OK) return B_BAD_ADDRESS; if (user_copy_strings_array((char * const *)userEnv, envCount, &env) < B_OK) { free_strings_array(args, argCount); return B_BAD_ADDRESS; } return load_image_etc(argCount, args, envCount, env, priority); } status_t _user_kill_team(team_id team) { return kill_team(team); } status_t _user_get_team_info(team_id id, team_info *userInfo) { status_t status; team_info info; if (!IS_USER_ADDRESS(userInfo)) return B_BAD_ADDRESS; status = _get_team_info(id, &info, sizeof(team_info)); if (status == B_OK) { if (user_memcpy(userInfo, &info, sizeof(team_info)) < B_OK) return B_BAD_ADDRESS; } return status; } status_t _user_get_next_team_info(int32 *userCookie, team_info *userInfo) { status_t status; team_info info; int32 cookie; if (!IS_USER_ADDRESS(userCookie) || !IS_USER_ADDRESS(userInfo) || user_memcpy(&cookie, userCookie, sizeof(int32)) < B_OK) return B_BAD_ADDRESS; status = _get_next_team_info(&cookie, &info, sizeof(team_info)); if (status != B_OK) return status; if (user_memcpy(userCookie, &cookie, sizeof(int32)) < B_OK || user_memcpy(userInfo, &info, sizeof(team_info)) < B_OK) return B_BAD_ADDRESS; return status; } team_id _user_get_current_team(void) { return team_get_current_team_id(); } status_t _user_get_team_usage_info(team_id team, int32 who, team_usage_info *userInfo, size_t size) { team_usage_info info; status_t status; if (!IS_USER_ADDRESS(userInfo)) return B_BAD_ADDRESS; status = _get_team_usage_info(team, who, &info, size); if (status != B_OK) return status; if (user_memcpy(userInfo, &info, size) < B_OK) return B_BAD_ADDRESS; return status; } int _user_getenv(const char *userName, char **_userValue) { char name[SYS_THREAD_STRING_LENGTH_MAX]; char *value; int rc; if (!IS_USER_ADDRESS(userName) || !IS_USER_ADDRESS(_userValue) || user_strlcpy(name, userName, SYS_THREAD_STRING_LENGTH_MAX) < B_OK) return B_BAD_ADDRESS; rc = sys_getenv(name, &value); if (rc < 0) return rc; if (user_memcpy(_userValue, &value, sizeof(char *)) < B_OK) return B_BAD_ADDRESS; return rc; } int _user_setenv(const char *userName, const char *userValue, int overwrite) { char name[SYS_THREAD_STRING_LENGTH_MAX]; char value[SYS_THREAD_STRING_LENGTH_MAX]; if (!IS_USER_ADDRESS(userName) || !IS_USER_ADDRESS(userValue) || user_strlcpy(name, userName, SYS_THREAD_STRING_LENGTH_MAX) < B_OK || user_strlcpy(value, userValue, SYS_THREAD_STRING_LENGTH_MAX) < B_OK) return B_BAD_ADDRESS; return sys_setenv(name, value, overwrite); }