/** * @file kernel/vfs/vfs.c * @brief Virtual file system. * * Provides the high-level generic operations for the VFS. * * @warning Here be dragons * * This VFS implementation comes from toaru32. It has a lot of weird * quirks and doesn't quite work like a typical Unix VFS would. * * @copyright * This file is part of ToaruOS and is released under the terms * of the NCSA / University of Illinois License - see LICENSE.md * Copyright (C) 2011-2021 K. Lange * Copyright (C) 2014 Lioncash * Copyright (C) 2012 Tianyi Wang */ #include #include #include #include #include #include #include #include #include #include #include #include #define MAX_SYMLINK_DEPTH 8 #define MAX_SYMLINK_SIZE 4096 tree_t * fs_tree = NULL; /* File system mountpoint tree */ fs_node_t * fs_root = NULL; /* Pointer to the root mount fs_node (must be some form of filesystem, even ramdisk) */ hashmap_t * fs_types = NULL; #define MIN(l,r) ((l) < (r) ? (l) : (r)) #define MAX(l,r) ((l) > (r) ? (l) : (r)) #define debug_print(x, ...) do { if (0) {printf("vfs.c [%s] ", #x); printf(__VA_ARGS__); printf("\n"); } } while (0) static int cb_printf(void * user, char c) { fs_node_t * f = user; write_fs(f, 0, 1, (uint8_t*)&c); return 0; } /** * @brief Write printf output to a simple file node. * * The file node, f, must be a simple character device that * allows repeated writes of a single byte without an incrementing * offset, such as a serial port or TTY. */ int fprintf(fs_node_t * f, const char * fmt, ...) { va_list args; va_start(args, fmt); int out = xvasprintf(cb_printf, f, fmt, args); va_end(args); return out; } int has_permission(fs_node_t * node, int permission_bit) { if (!node) return 0; if (this_core->current_process->user == 0 && permission_bit != 01) { /* even root needs exec to exec */ return 1; } uint64_t permissions = node->mask; uint8_t my_permissions = (permissions) & 07; uint8_t user_perm = (permissions >> 6) & 07; uint8_t group_perm = (permissions >> 3) & 07; if (this_core->current_process->user == node->uid) my_permissions |= user_perm; if (this_core->current_process->user_group == node->gid) my_permissions |= group_perm; else if (this_core->current_process->supplementary_group_count) { for (int i = 0; i < this_core->current_process->supplementary_group_count; ++i) { if (this_core->current_process->supplementary_group_list[i] == node->gid) { my_permissions |= group_perm; } } } return (permission_bit & my_permissions); } static struct dirent * readdir_mapper(fs_node_t *node, unsigned long index) { tree_node_t * d = (tree_node_t *)node->device; if (!d) return NULL; if (index == 0) { struct dirent * dir = malloc(sizeof(struct dirent)); strcpy(dir->d_name, "."); dir->d_ino = 0; return dir; } else if (index == 1) { struct dirent * dir = malloc(sizeof(struct dirent)); strcpy(dir->d_name, ".."); dir->d_ino = 1; return dir; } index -= 2; unsigned long i = 0; foreach(child, d->children) { if (i == index) { /* Recursively print the children */ tree_node_t * tchild = (tree_node_t *)child->value; struct vfs_entry * n = (struct vfs_entry *)tchild->value; struct dirent * dir = malloc(sizeof(struct dirent)); size_t len = strlen(n->name) + 1; memcpy(&dir->d_name, n->name, MIN(256, len)); dir->d_ino = i; return dir; } ++i; } return NULL; } static fs_node_t * vfs_mapper(void) { fs_node_t * fnode = malloc(sizeof(fs_node_t)); memset(fnode, 0x00, sizeof(fs_node_t)); fnode->mask = 0555; fnode->flags = FS_DIRECTORY; fnode->readdir = readdir_mapper; fnode->ctime = now(); fnode->mtime = now(); fnode->atime = now(); return fnode; } /** * @brief Check if a read from this file would block. */ int selectcheck_fs(fs_node_t * node) { if (!node) return -ENOENT; if (node->selectcheck) { return node->selectcheck(node); } return -EINVAL; } /** * @brief Inform a node that it should alert the current_process. */ int selectwait_fs(fs_node_t * node, void * process) { if (!node) return -ENOENT; if (node->selectwait) { return node->selectwait(node, process); } return -EINVAL; } /** * @brief Read a file system node based on its underlying type. * * @param node Node to read * @param offset Offset into the node data to read from * @param size How much data to read (in bytes) * @param buffer A buffer to copy of the read data into * @returns Bytes read */ ssize_t read_fs(fs_node_t *node, off_t offset, size_t size, uint8_t *buffer) { if (!node) return -ENOENT; if (node->read) { return node->read(node, offset, size, buffer); } else { return -EINVAL; } } /** * @brief Write a file system node based on its underlying type. * * @param node Node to write to * @param offset Offset into the node data to write to * @param size How much data to write (in bytes) * @param buffer A buffer to copy from * @returns Bytes written */ ssize_t write_fs(fs_node_t *node, off_t offset, size_t size, uint8_t *buffer) { if (!node) return -ENOENT; if (node->write) { return node->write(node, offset, size, buffer); } else { return -EROFS; } } /** * @brief set the size of a file to 9 * * @param node File to resize */ int truncate_fs(fs_node_t * node) { if (!node) return -ENOENT; if (node->truncate) { return node->truncate(node); } return -EINVAL; } //volatile uint8_t tmp_refcount_lock = 0; static spin_lock_t tmp_refcount_lock = { 0 }; void vfs_lock(fs_node_t * node) { spin_lock(tmp_refcount_lock); node->refcount = -1; spin_unlock(tmp_refcount_lock); } /** * @brief Open a file system node. * * @param node Node to open * @param flags Same as open, specifies read/write/append/truncate */ void open_fs(fs_node_t *node, unsigned int flags) { if (!node) return; if (node->refcount >= 0) { spin_lock(tmp_refcount_lock); node->refcount++; spin_unlock(tmp_refcount_lock); } if (node->open) { node->open(node, flags); } } /** * @brief Close a file system node * * @param node Node to close */ void close_fs(fs_node_t *node) { //assert(node != fs_root && "Attempted to close the filesystem root. kablooey"); if (!node) { debug_print(WARNING, "Double close? This isn't an fs_node."); return; } if (node->refcount == -1) return; spin_lock(tmp_refcount_lock); node->refcount--; if (node->refcount == 0) { debug_print(NOTICE, "Node refcount [%s] is now 0: %ld", node->name, node->refcount); if (node->close) { node->close(node); } free(node); } spin_unlock(tmp_refcount_lock); } /** * @brief Change permissions for a file system node. * * @param node Node to change permissions for * @param mode New mode bits */ int chmod_fs(fs_node_t *node, mode_t mode) { if (node->chmod) { return node->chmod(node, mode); } return 0; } /** * @brief Change ownership for a file system node. */ int chown_fs(fs_node_t *node, uid_t uid, gid_t gid) { if (node->chown) { return node->chown(node, uid, gid); } return 0; } /** * @brief Read a directory for the requested index * * @param node Directory to read * @param index Offset to look for * @returns A dirent object. */ struct dirent *readdir_fs(fs_node_t *node, unsigned long index) { if (!node) return NULL; if ((node->flags & FS_DIRECTORY) && node->readdir) { return node->readdir(node, index); } else { return NULL; } } /** * @brief Find the requested file in the directory and return an fs_node for it * * @param node Directory to search * @param name File to look for * @returns An fs_node that the caller can free */ fs_node_t *finddir_fs(fs_node_t *node, char *name) { if (!node) return NULL; if ((node->flags & FS_DIRECTORY) && node->finddir) { return node->finddir(node, name); } else { debug_print(WARNING, "Node passed to finddir_fs isn't a directory!"); debug_print(WARNING, "node = %p, name = %s", (void*)node, name); return NULL; } } /** * @brief Control Device * * @param node Device node to control * @param request Device-specific request code * @param argp Depends on `request` * @returns Depends on `request` */ int ioctl_fs(fs_node_t *node, unsigned long request, void * argp) { if (!node) return -ENOENT; if (node->ioctl) { return node->ioctl(node, request, argp); } else { return -EINVAL; } } /* * XXX: The following two function should be replaced with * one function to create children of directory nodes. * There is no fundamental difference between a directory * and a file, thus, the use of flag sets should suffice */ int create_file_fs(char *name, mode_t permission) { fs_node_t * parent; char *cwd = (char *)(this_core->current_process->wd_name); char *path = canonicalize_path(cwd, name); char * parent_path = malloc(strlen(path) + 5); snprintf(parent_path, strlen(path) + 4, "%s/..", path); char * f_path = path + strlen(path) - 1; while (f_path > path) { if (*f_path == '/') { f_path += 1; break; } f_path--; } while (*f_path == '/') { f_path++; } debug_print(NOTICE, "creating file %s within %s (hope these strings are good)", f_path, parent_path); parent = kopen(parent_path, 0); free(parent_path); if (!parent) { debug_print(WARNING, "failed to open parent"); free(path); return -ENOENT; } if (!has_permission(parent, 02)) { debug_print(WARNING, "bad permissions"); return -EACCES; } int ret = 0; if (parent->create) { ret = parent->create(parent, f_path, permission); } else { ret = -EINVAL; } free(path); free(parent); return ret; } int unlink_fs(char * name) { fs_node_t * parent; char *cwd = (char *)(this_core->current_process->wd_name); char *path = canonicalize_path(cwd, name); char * parent_path = malloc(strlen(path) + 5); snprintf(parent_path, strlen(path) + 4, "%s/..", path); char * f_path = path + strlen(path) - 1; while (f_path > path) { if (*f_path == '/') { f_path += 1; break; } f_path--; } while (*f_path == '/') { f_path++; } debug_print(WARNING, "unlinking file %s within %s (hope these strings are good)", f_path, parent_path); parent = kopen(parent_path, 0); free(parent_path); if (!parent) { free(path); return -ENOENT; } if (!has_permission(parent, 02)) { free(path); close_fs(parent); return -EACCES; } int ret = 0; if (parent->unlink) { ret = parent->unlink(parent, f_path); } else { ret = -EINVAL; } free(path); close_fs(parent); return ret; } int mkdir_fs(char *name, mode_t permission) { fs_node_t * parent; char *cwd = (char *)(this_core->current_process->wd_name); char *path = canonicalize_path(cwd, name); if (!name || !strlen(name)) { return -EINVAL; } char * parent_path = malloc(strlen(path) + 5); snprintf(parent_path, strlen(path) + 4, "%s/..", path); char * f_path = path + strlen(path) - 1; while (f_path > path) { if (*f_path == '/') { f_path += 1; break; } f_path--; } while (*f_path == '/') { f_path++; } debug_print(WARNING, "creating directory %s within %s (hope these strings are good)", f_path, parent_path); parent = kopen(parent_path, 0); free(parent_path); if (!parent) { free(path); return -ENOENT; } if (!f_path || !strlen(f_path)) { /* Odd edge case with / */ return -EEXIST; } fs_node_t * this = kopen(path, 0); int _exists = 0; if (this) { /* We need to do this because permission check stuff... */ close_fs(this); _exists = 1; } if (!has_permission(parent, 02)) { free(path); close_fs(parent); return _exists ? -EEXIST : -EACCES; } int ret = 0; if (parent->mkdir) { ret = parent->mkdir(parent, f_path, permission); } else { ret = -EROFS; } free(path); close_fs(parent); return ret; } fs_node_t *clone_fs(fs_node_t *source) { if (!source) return NULL; if (source->refcount >= 0) { spin_lock(tmp_refcount_lock); source->refcount++; spin_unlock(tmp_refcount_lock); } return source; } int symlink_fs(char * target, char * name) { fs_node_t * parent; char *cwd = (char *)(this_core->current_process->wd_name); char *path = canonicalize_path(cwd, name); char * parent_path = malloc(strlen(path) + 5); snprintf(parent_path, strlen(path) + 4, "%s/..", path); char * f_path = path + strlen(path) - 1; while (f_path > path) { if (*f_path == '/') { f_path += 1; break; } f_path--; } debug_print(NOTICE, "creating symlink %s within %s", f_path, parent_path); parent = kopen(parent_path, 0); free(parent_path); if (!parent) { free(path); return -ENOENT; } int ret = 0; if (parent->symlink) { ret = parent->symlink(parent, target, f_path); } else { ret = -EINVAL; } free(path); close_fs(parent); return ret; } ssize_t readlink_fs(fs_node_t *node, char * buf, size_t size) { if (!node) return -ENOENT; if (node->readlink) { return node->readlink(node, buf, size); } else { return -EINVAL; } } /** * @brief Canonicalize a path. * * @param cwd Current working directory * @param input Path to append or canonicalize on * @returns An absolute path string */ char *canonicalize_path(const char *cwd, const char *input) { /* This is a stack-based canonicalizer; we use a list as a stack */ list_t *out = list_create("vfs canonicalize_path working memory",input); /* * If we have a relative path, we need to canonicalize * the working directory and insert it into the stack. */ if (strlen(input) && input[0] != PATH_SEPARATOR) { /* Make a copy of the working directory */ char *path = malloc((strlen(cwd) + 1) * sizeof(char)); memcpy(path, cwd, strlen(cwd) + 1); /* Setup tokenizer */ char *pch; char *save; pch = strtok_r(path,PATH_SEPARATOR_STRING,&save); /* Start tokenizing */ while (pch != NULL) { /* Make copies of the path elements */ char *s = malloc(sizeof(char) * (strlen(pch) + 1)); memcpy(s, pch, strlen(pch) + 1); /* And push them */ list_insert(out, s); pch = strtok_r(NULL,PATH_SEPARATOR_STRING,&save); } free(path); } /* Similarly, we need to push the elements from the new path */ char *path = malloc((strlen(input) + 1) * sizeof(char)); memcpy(path, input, strlen(input) + 1); /* Initialize the tokenizer... */ char *pch; char *save; pch = strtok_r(path,PATH_SEPARATOR_STRING,&save); /* * Tokenize the path, this time, taking care to properly * handle .. and . to represent up (stack pop) and current * (do nothing) */ while (pch != NULL) { if (!strcmp(pch,PATH_UP)) { /* * Path = .. * Pop the stack to move up a directory */ node_t * n = list_pop(out); if (n) { free(n->value); free(n); } } else if (!strcmp(pch,PATH_DOT)) { /* * Path = . * Do nothing */ } else { /* * Regular path, push it * XXX: Path elements should be checked for existence! */ char * s = malloc(sizeof(char) * (strlen(pch) + 1)); memcpy(s, pch, strlen(pch) + 1); list_insert(out, s); } pch = strtok_r(NULL, PATH_SEPARATOR_STRING, &save); } free(path); /* Calculate the size of the path string */ size_t size = 0; foreach(item, out) { /* Helpful use of our foreach macro. */ size += strlen(item->value) + 1; } /* join() the list */ char *output = malloc(sizeof(char) * (size + 1)); char *output_offset = output; if (size == 0) { /* * If the path is empty, we take this to mean the root * thus we synthesize a path of "/" to return. */ output = realloc(output, sizeof(char) * 2); output[0] = PATH_SEPARATOR; output[1] = '\0'; } else { /* Otherwise, append each element together */ foreach(item, out) { output_offset[0] = PATH_SEPARATOR; output_offset++; memcpy(output_offset, item->value, strlen(item->value) + 1); output_offset += strlen(item->value); } } /* Clean up the various things we used to get here */ list_destroy(out); list_free(out); free(out); /* And return a working, absolute path */ return output; } void vfs_install(void) { /* Initialize the mountpoint tree */ fs_tree = tree_create(); struct vfs_entry * root = malloc(sizeof(struct vfs_entry)); root->name = strdup("[root]"); root->file = NULL; /* Nothing mounted as root */ root->fs_type = NULL; root->device = NULL; tree_set_root(fs_tree, root); fs_types = hashmap_create(5); } int vfs_register(const char * name, vfs_mount_callback callback) { if (hashmap_get(fs_types, name)) return 1; hashmap_set(fs_types, name, (void *)(uintptr_t)callback); return 0; } int vfs_mount_type(const char * type, const char * arg, const char * mountpoint) { vfs_mount_callback t = (vfs_mount_callback)(uintptr_t)hashmap_get(fs_types, type); if (!t) { debug_print(WARNING, "Unknown filesystem type: %s", type); return -ENODEV; } fs_node_t * n = t(arg, mountpoint); /* Quick hack to let partition mappers not return a node to mount at 'mountpoint'... */ if ((uintptr_t)n == (uintptr_t)1) return 0; if (!n) return -EINVAL; tree_node_t * node = vfs_mount(mountpoint, n); if (node && node->value) { struct vfs_entry * ent = (struct vfs_entry *)node->value; ent->fs_type = strdup(type); ent->device = strdup(arg); } debug_print(NOTICE, "Mounted %s[%s] to %s: %p", type, arg, mountpoint, (void*)n); debug_print_vfs_tree(); return 0; } static spin_lock_t tmp_vfs_lock = { 0 }; /** * @brief Mount a file system to the specified path. * * Mounts a file system node to a given base path. * For example, if we have an EXT2 filesystem with a root node * of ext2_root and we want to mount it to /, we would run * vfs_mount("/", ext2_root); - or, if we have a procfs node, * we could mount that to /dev/procfs. Individual files can also * be mounted. * * Paths here must be absolute. */ void * vfs_mount(const char * path, fs_node_t * local_root) { if (!fs_tree) { debug_print(ERROR, "VFS hasn't been initialized, you can't mount things yet!"); return NULL; } if (!path || path[0] != '/') { debug_print(ERROR, "Path must be absolute for mountpoint."); return NULL; } spin_lock(tmp_vfs_lock); local_root->refcount = -1; tree_node_t * ret_val = NULL; char * p = strdup(path); char * i = p; int path_len = strlen(p); /* Chop the path up */ while (i < p + path_len) { if (*i == PATH_SEPARATOR) { *i = '\0'; } i++; } /* Clean up */ p[path_len] = '\0'; i = p + 1; /* Root */ tree_node_t * root_node = fs_tree->root; if (*i == '\0') { /* Special case, we're trying to set the root node */ struct vfs_entry * root = (struct vfs_entry *)root_node->value; if (root->file) { debug_print(WARNING, "Path %s already mounted, unmount before trying to mount something else.", path); } root->file = local_root; /* We also keep a legacy shortcut around for that */ fs_root = local_root; ret_val = root_node; } else { tree_node_t * node = root_node; char * at = i; while (1) { if (at >= p + path_len) { break; } int found = 0; debug_print(NOTICE, "Searching for %s", at); foreach(child, node->children) { tree_node_t * tchild = (tree_node_t *)child->value; struct vfs_entry * ent = (struct vfs_entry *)tchild->value; if (!strcmp(ent->name, at)) { found = 1; node = tchild; ret_val = node; break; } } if (!found) { debug_print(NOTICE, "Did not find %s, making it.", at); struct vfs_entry * ent = malloc(sizeof(struct vfs_entry)); ent->name = strdup(at); ent->file = NULL; ent->device = NULL; ent->fs_type = NULL; node = tree_node_insert_child(fs_tree, node, ent); } at = at + strlen(at) + 1; } struct vfs_entry * ent = (struct vfs_entry *)node->value; if (ent->file) { debug_print(WARNING, "Path %s already mounted, unmount before trying to mount something else.", path); } ent->file = local_root; ret_val = node; } free(p); spin_unlock(tmp_vfs_lock); return ret_val; } void map_vfs_directory(const char * c) { fs_node_t * f = vfs_mapper(); struct vfs_entry * e = vfs_mount((char*)c, f); if (!strcmp(c, "/")) { f->device = fs_tree->root; } else { f->device = e; } } void debug_print_vfs_tree_node(tree_node_t * node, size_t height) { /* End recursion on a blank entry */ if (!node) return; char * tmp = malloc(512); memset(tmp, 0, 512); char * c = tmp; /* Indent output */ for (uint32_t i = 0; i < height; ++i) { c += snprintf(c, 3, " "); } /* Get the current process */ struct vfs_entry * fnode = (struct vfs_entry *)node->value; /* Print the process name */ if (fnode->file) { c += snprintf(c, 100, "%s → %s %p (%s, %s)", fnode->name, fnode->device, (void*)fnode->file, fnode->fs_type, fnode->file->name); } else { c += snprintf(c, 100, "%s → (empty)", fnode->name); } /* Linefeed */ debug_print(NOTICE, "%s", tmp); free(tmp); foreach(child, node->children) { /* Recursively print the children */ debug_print_vfs_tree_node(child->value, height + 1); } } void debug_print_vfs_tree(void) { debug_print_vfs_tree_node(fs_tree->root, 0); } /** * get_mount_point * */ fs_node_t *get_mount_point(char * path, unsigned int path_depth, char **outpath, unsigned int * outdepth) { size_t depth; for (depth = 0; depth <= path_depth; ++depth) { path += strlen(path) + 1; } /* Last available node */ fs_node_t * last = fs_root; tree_node_t * node = fs_tree->root; char * at = *outpath; int _depth = 1; int _tree_depth = 0; while (1) { if (at >= path) { break; } int found = 0; debug_print(INFO, "Searching for %s", at); foreach(child, node->children) { tree_node_t * tchild = (tree_node_t *)child->value; struct vfs_entry * ent = (struct vfs_entry *)tchild->value; if (!strcmp(ent->name, at)) { found = 1; node = tchild; at = at + strlen(at) + 1; if (ent->file) { _tree_depth = _depth; last = ent->file; *outpath = at; } break; } } if (!found) { break; } _depth++; } *outdepth = _tree_depth; if (last) { fs_node_t * last_clone = malloc(sizeof(fs_node_t)); memcpy(last_clone, last, sizeof(fs_node_t)); last_clone->refcount = 0; return last_clone; } return last; } fs_node_t *kopen_recur(const char *filename, uint64_t flags, uint64_t symlink_depth, char *relative_to) { /* Simple sanity checks that we actually have a file system */ if (!filename) { return NULL; } /* Canonicalize the (potentially relative) path... */ char *path = canonicalize_path(relative_to, filename); /* And store the length once to save recalculations */ size_t path_len = strlen(path); /* If strlen(path) == 1, then path = "/"; return root */ if (path_len == 1) { /* Clone the root file system node */ fs_node_t *root_clone = malloc(sizeof(fs_node_t)); memcpy(root_clone, fs_root, sizeof(fs_node_t)); root_clone->refcount = 0; /* Free the path */ free(path); open_fs(root_clone, flags); /* And return the clone */ return root_clone; } /* Otherwise, we need to break the path up and start searching */ char *path_offset = path; uint64_t path_depth = 0; while (path_offset < path + path_len) { /* Find each PATH_SEPARATOR */ if (*path_offset == PATH_SEPARATOR) { *path_offset = '\0'; path_depth++; } path_offset++; } /* Clean up */ path[path_len] = '\0'; path_offset = path + 1; /* * At this point, the path is tokenized and path_offset points * to the first token (directory) and path_depth is the number * of directories in the path */ /* * Dig through the (real) tree to find the file */ unsigned int depth = 0; /* Find the mountpoint for this file */ fs_node_t *node_ptr = get_mount_point(path, path_depth, &path_offset, &depth); debug_print(INFO, "path_offset: %s", path_offset); debug_print(INFO, "depth: %d", depth); if (!node_ptr) return NULL; do { /* * This test is a little complicated, but we basically always resolve symlinks in the * of a path (like /home/symlink/file) even if O_NOFOLLOW and O_PATH are set. If we are * on the leaf of the path then we will look at those flags and act accordingly */ if ((node_ptr->flags & FS_SYMLINK) && !((flags & O_NOFOLLOW) && (flags & O_PATH) && depth == path_depth)) { /* This ensures we don't return a path when NOFOLLOW is requested but PATH * isn't passed. */ debug_print(NOTICE, "resolving symlink at %s", node_ptr->name); if ((flags & O_NOFOLLOW) && depth == path_depth - 1) { /* TODO(gerow): should probably be setting errno from this */ debug_print(NOTICE, "Refusing to follow final entry for open with O_NOFOLLOW for %s.", node_ptr->name); free((void *)path); free(node_ptr); return NULL; } if (symlink_depth >= MAX_SYMLINK_DEPTH) { /* TODO(gerow): should probably be setting errno from this */ debug_print(WARNING, "Reached max symlink depth on %s.", node_ptr->name); free((void *)path); free(node_ptr); return NULL; } /* * This may actually be big enough that we wouldn't want to allocate it on * the stack, especially considering this function is called recursively */ char symlink_buf[MAX_SYMLINK_SIZE]; int len = readlink_fs(node_ptr, symlink_buf, sizeof(symlink_buf)); if (len < 0) { /* TODO(gerow): should probably be setting errno from this */ debug_print(WARNING, "Got error %d from symlink for %s.", len, node_ptr->name); free((void *)path); free(node_ptr); return NULL; } if (symlink_buf[len] != '\0') { /* TODO(gerow): should probably be setting errno from this */ debug_print(WARNING, "readlink for %s doesn't end in a null pointer. That's weird...", node_ptr->name); free((void *)path); free(node_ptr); return NULL; } fs_node_t * old_node_ptr = node_ptr; /* Rebuild our path up to this point. This is hella hacky. */ char * relpath = malloc(path_len + 1); char * ptr = relpath; memcpy(relpath, path, path_len + 1); for (unsigned int i = 0; depth && i < depth-1; i++) { while(*ptr != '\0') { ptr++; } *ptr = PATH_SEPARATOR; } node_ptr = kopen_recur(symlink_buf, 0, symlink_depth + 1, relpath); free(relpath); free(old_node_ptr); if (!node_ptr) { /* Dangling symlink? */ debug_print(WARNING, "Failed to open symlink path %s. Perhaps it's a dangling symlink?", symlink_buf); free((void *)path); return NULL; } } if (path_offset >= path+path_len) { free(path); open_fs(node_ptr, flags); return node_ptr; } if (depth == path_depth) { /* We found the file and are done, open the node */ open_fs(node_ptr, flags); free((void *)path); return node_ptr; } /* We are still searching... */ debug_print(INFO, "... Searching for %s", path_offset); fs_node_t * node_next = finddir_fs(node_ptr, path_offset); free(node_ptr); /* Always a clone or an unopened thing */ node_ptr = node_next; /* Search the active directory for the requested directory */ if (!node_ptr) { /* We failed to find the requested directory */ free((void *)path); return NULL; } path_offset += strlen(path_offset) + 1; ++depth; } while (depth < path_depth + 1); debug_print(INFO, "- Not found."); /* We failed to find the requested file, but our loop terminated. */ free((void *)path); return NULL; } /** * @brief Open a file by name. * * Explore the file system tree to find the appropriate node for * for a given path. The path can be relative to the working directory * and will be canonicalized by the kernel. * * @param filename Filename to open * @param flags Flag bits for read/write mode. * @returns A file system node element that the caller can free. */ fs_node_t *kopen(const char *filename, unsigned int flags) { debug_print(NOTICE, "kopen(%s)", filename); return kopen_recur(filename, flags, 0, (char *)(this_core->current_process->wd_name)); }