/* * Copyright 2002-2009, 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. */ #ifndef _KERNEL_VFS_H #define _KERNEL_VFS_H #include #include #include #include #include #include #include #include #include #include #define DEFAULT_FD_TABLE_SIZE 256 #define MAX_FD_TABLE_SIZE 8192 #define DEFAULT_NODE_MONITORS 4096 #define MAX_NODE_MONITORS 65536 #define B_UNMOUNT_BUSY_PARTITION 0x80000000 struct attr_info; struct file_descriptor; struct generic_io_vec; struct kernel_args; struct net_stat; struct pollfd; struct rlimit; struct selectsync; struct select_info; struct VMCache; struct vnode; /** The I/O context of a process/team, holds the fd array among others */ typedef struct io_context { struct vnode *root; struct vnode *cwd; mutex io_mutex; int32 ref_count; uint32 table_size; uint32 num_used_fds; struct file_descriptor **fds; struct select_info **select_infos; uint8 *fds_close_on_exec; struct list node_monitors; uint32 num_monitors; uint32 max_monitors; } io_context; #ifdef __cplusplus extern "C" { #endif status_t vfs_init(struct kernel_args *args); status_t vfs_bootstrap_file_systems(void); void vfs_mount_boot_file_system(struct kernel_args *args); void vfs_exec_io_context(io_context *context); io_context* vfs_new_io_context(io_context* parentContext, bool purgeCloseOnExec); void vfs_get_io_context(io_context *context); void vfs_put_io_context(io_context *context); int vfs_getrlimit(int resource, struct rlimit *rlp); int vfs_setrlimit(int resource, const struct rlimit *rlp); /* calls needed by the VM for paging and by the file cache */ status_t vfs_get_vnode_from_fd(int fd, bool kernel, struct vnode **_vnode); status_t vfs_get_vnode_from_path(const char *path, bool kernel, struct vnode **_vnode); status_t vfs_get_vnode(dev_t mountID, ino_t vnodeID, bool canWait, struct vnode **_vnode); status_t vfs_entry_ref_to_vnode(dev_t mountID, ino_t directoryID, const char *name, struct vnode **_vnode); void vfs_vnode_to_node_ref(struct vnode *vnode, dev_t *_mountID, ino_t *_vnodeID); int vfs_open_vnode(struct vnode* vnode, int openMode, bool kernel); status_t vfs_lookup_vnode(dev_t mountID, ino_t vnodeID, struct vnode **_vnode); void vfs_put_vnode(struct vnode *vnode); void vfs_acquire_vnode(struct vnode *vnode); status_t vfs_get_cookie_from_fd(int fd, void **_cookie); bool vfs_can_page(struct vnode *vnode, void *cookie); status_t vfs_read_pages(struct vnode *vnode, void *cookie, off_t pos, const struct generic_io_vec *vecs, size_t count, uint32 flags, generic_size_t *_numBytes); status_t vfs_write_pages(struct vnode *vnode, void *cookie, off_t pos, const struct generic_io_vec *vecs, size_t count, uint32 flags, generic_size_t *_numBytes); status_t vfs_vnode_io(struct vnode* vnode, void* cookie, io_request* request); status_t vfs_synchronous_io(io_request* request, status_t (*doIO)(void* cookie, off_t offset, void* buffer, size_t* length), void* cookie); status_t vfs_get_vnode_cache(struct vnode *vnode, struct VMCache **_cache, bool allocate); status_t vfs_get_file_map(struct vnode *vnode, off_t offset, size_t size, struct file_io_vec *vecs, size_t *_count); status_t vfs_get_fs_node_from_path(fs_volume *volume, const char *path, bool traverseLeafLink, bool kernel, void **_node); status_t vfs_stat_vnode(struct vnode *vnode, struct stat *stat); status_t vfs_stat_node_ref(dev_t device, ino_t inode, struct stat *stat); status_t vfs_get_vnode_name(struct vnode *vnode, char *name, size_t nameSize); status_t vfs_entry_ref_to_path(dev_t device, ino_t inode, const char *leaf, char *path, size_t pathLength); status_t vfs_get_cwd(dev_t *_mountID, ino_t *_vnodeID); void vfs_unlock_vnode_if_locked(struct file_descriptor *descriptor); status_t vfs_unmount(dev_t mountID, uint32 flags); status_t vfs_disconnect_vnode(dev_t mountID, ino_t vnodeID); void vfs_free_unused_vnodes(int32 level); status_t vfs_read_stat(int fd, const char *path, bool traverseLeafLink, struct stat *stat, bool kernel); /* special module convenience call */ status_t vfs_get_module_path(const char *basePath, const char *moduleName, char *pathBuffer, size_t bufferSize); /* service call for whoever needs a normalized path */ status_t vfs_normalize_path(const char *path, char *buffer, size_t bufferSize, bool traverseLink, bool kernel); /* service call for whoever wants to create a special node */ status_t vfs_create_special_node(const char *path, fs_vnode *subVnode, mode_t mode, uint32 flags, bool kernel, fs_vnode *_superVnode, struct vnode **_createdVnode); /* service call for the node monitor */ status_t resolve_mount_point_to_volume_root(dev_t mountID, ino_t nodeID, dev_t *resolvedMountID, ino_t *resolvedNodeID); /* calls the syscall dispatcher should use for user file I/O */ dev_t _user_mount(const char *path, const char *device, const char *fs_name, uint32 flags, const char *args, size_t argsLength); status_t _user_unmount(const char *path, uint32 flags); status_t _user_read_fs_info(dev_t device, struct fs_info *info); status_t _user_write_fs_info(dev_t device, const struct fs_info *info, int mask); dev_t _user_next_device(int32 *_cookie); status_t _user_sync(void); status_t _user_get_next_fd_info(team_id team, uint32 *cookie, struct fd_info *info, size_t infoSize); status_t _user_entry_ref_to_path(dev_t device, ino_t inode, const char *leaf, char *userPath, size_t pathLength); status_t _user_normalize_path(const char* userPath, bool traverseLink, char* buffer); int _user_open_entry_ref(dev_t device, ino_t inode, const char *name, int openMode, int perms); int _user_open(int fd, const char *path, int openMode, int perms); int _user_open_dir_node_ref(dev_t device, ino_t inode); int _user_open_dir_entry_ref(dev_t device, ino_t inode, const char *name); int _user_open_dir(int fd, const char *path); int _user_open_parent_dir(int fd, char *name, size_t nameLength); status_t _user_fcntl(int fd, int op, uint32 argument); status_t _user_fsync(int fd); status_t _user_flock(int fd, int op); status_t _user_read_stat(int fd, const char *path, bool traverseLink, struct stat *stat, size_t statSize); status_t _user_write_stat(int fd, const char *path, bool traverseLink, const struct stat *stat, size_t statSize, int statMask); off_t _user_seek(int fd, off_t pos, int seekType); status_t _user_create_dir_entry_ref(dev_t device, ino_t inode, const char *name, int perms); status_t _user_create_dir(int fd, const char *path, int perms); status_t _user_remove_dir(int fd, const char *path); status_t _user_read_link(int fd, const char *path, char *buffer, size_t *_bufferSize); status_t _user_write_link(const char *path, const char *toPath); status_t _user_create_symlink(int fd, const char *path, const char *toPath, int mode); status_t _user_create_link(int pathFD, const char *path, int toFD, const char *toPath, bool traverseLeafLink); status_t _user_unlink(int fd, const char *path); status_t _user_rename(int oldFD, const char *oldpath, int newFD, const char *newpath); status_t _user_create_fifo(int fd, const char *path, mode_t perms); status_t _user_create_pipe(int *fds); status_t _user_access(int fd, const char *path, int mode, bool effectiveUserGroup); ssize_t _user_select(int numfds, fd_set *readSet, fd_set *writeSet, fd_set *errorSet, bigtime_t timeout, const sigset_t *sigMask); ssize_t _user_poll(struct pollfd *fds, int numfds, bigtime_t timeout); int _user_open_attr_dir(int fd, const char *path); ssize_t _user_read_attr(int fd, const char *attribute, off_t pos, void *buffer, size_t readBytes); ssize_t _user_write_attr(int fd, const char *attribute, uint32 type, off_t pos, const void *buffer, size_t readBytes); status_t _user_stat_attr(int fd, const char *attribute, struct attr_info *attrInfo); int _user_open_attr(int fd, const char* path, const char *name, uint32 type, int openMode); status_t _user_remove_attr(int fd, const char *name); status_t _user_rename_attr(int fromFile, const char *fromName, int toFile, const char *toName); int _user_open_index_dir(dev_t device); status_t _user_create_index(dev_t device, const char *name, uint32 type, uint32 flags); status_t _user_read_index_stat(dev_t device, const char *name, struct stat *stat); status_t _user_remove_index(dev_t device, const char *name); status_t _user_getcwd(char *buffer, size_t size); status_t _user_setcwd(int fd, const char *path); status_t _user_change_root(const char *path); int _user_open_query(dev_t device, const char *query, size_t queryLength, uint32 flags, port_id port, int32 token); /* fd user prototypes (implementation located in fd.cpp) */ ssize_t _user_read(int fd, off_t pos, void *buffer, size_t bufferSize); ssize_t _user_readv(int fd, off_t pos, const iovec *vecs, size_t count); ssize_t _user_write(int fd, off_t pos, const void *buffer, size_t bufferSize); ssize_t _user_writev(int fd, off_t pos, const iovec *vecs, size_t count); status_t _user_ioctl(int fd, uint32 cmd, void *data, size_t length); ssize_t _user_read_dir(int fd, struct dirent *buffer, size_t bufferSize, uint32 maxCount); status_t _user_rewind_dir(int fd); status_t _user_close(int fd); int _user_dup(int fd); int _user_dup2(int ofd, int nfd); status_t _user_lock_node(int fd); status_t _user_unlock_node(int fd); /* socket user prototypes (implementation in socket.cpp) */ int _user_socket(int family, int type, int protocol); status_t _user_bind(int socket, const struct sockaddr *address, socklen_t addressLength); status_t _user_shutdown_socket(int socket, int how); status_t _user_connect(int socket, const struct sockaddr *address, socklen_t addressLength); status_t _user_listen(int socket, int backlog); int _user_accept(int socket, struct sockaddr *address, socklen_t *_addressLength); ssize_t _user_recv(int socket, void *data, size_t length, int flags); ssize_t _user_recvfrom(int socket, void *data, size_t length, int flags, struct sockaddr *address, socklen_t *_addressLength); ssize_t _user_recvmsg(int socket, struct msghdr *message, int flags); ssize_t _user_send(int socket, const void *data, size_t length, int flags); ssize_t _user_sendto(int socket, const void *data, size_t length, int flags, const struct sockaddr *address, socklen_t addressLength); ssize_t _user_sendmsg(int socket, const struct msghdr *message, int flags); status_t _user_getsockopt(int socket, int level, int option, void *value, socklen_t *_length); status_t _user_setsockopt(int socket, int level, int option, const void *value, socklen_t length); status_t _user_getpeername(int socket, struct sockaddr *address, socklen_t *_addressLength); status_t _user_getsockname(int socket, struct sockaddr *address, socklen_t *_addressLength); int _user_sockatmark(int socket); status_t _user_socketpair(int family, int type, int protocol, int *socketVector); status_t _user_get_next_socket_stat(int family, uint32 *cookie, struct net_stat *stat); #ifdef __cplusplus } #endif #ifdef __cplusplus class AsyncIOCallback { public: virtual ~AsyncIOCallback(); virtual void IOFinished(status_t status, bool partialTransfer, generic_size_t bytesTransferred) = 0; static status_t IORequestCallback(void* data, io_request* request, status_t status, bool partialTransfer, generic_size_t transferEndOffset); }; class StackableAsyncIOCallback : public AsyncIOCallback { public: StackableAsyncIOCallback(AsyncIOCallback* next); protected: AsyncIOCallback* fNextCallback; }; status_t vfs_asynchronous_read_pages(struct vnode* vnode, void* cookie, off_t pos, const struct generic_io_vec* vecs, size_t count, generic_size_t numBytes, uint32 flags, AsyncIOCallback* callback); status_t vfs_asynchronous_write_pages(struct vnode* vnode, void* cookie, off_t pos, const struct generic_io_vec* vecs, size_t count, generic_size_t numBytes, uint32 flags, AsyncIOCallback* callback); #endif // __cplusplus #endif /* _KERNEL_VFS_H */