/* * Samba Unix/Linux SMB client library * Registry Editor * Copyright (C) Christopher Davis 2012 * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "regedit_treeview.h" #include "regedit_list.h" #include "lib/registry/registry.h" #define HEADING_X 3 static int tree_node_free(struct tree_node *node) { DEBUG(9, ("tree_node_free('%s', %p)\n", node->name, node)); return 0; } struct tree_node *tree_node_new(TALLOC_CTX *ctx, struct tree_node *parent, const char *name, struct registry_key *key) { struct tree_node *node; node = talloc_zero(ctx, struct tree_node); if (!node) { return NULL; } talloc_set_destructor(node, tree_node_free); DEBUG(9, ("tree_node_new('%s', %p)\n", name, node)); node->name = talloc_strdup(node, name); if (!node->name) { talloc_free(node); return NULL; } if (key) { node->key = talloc_steal(node, key); } if (parent) { /* Check if this node is the first descendant of parent. */ if (!parent->child_head) { parent->child_head = node; } node->parent = parent; } return node; } /* prepare a root node with all available hives as children */ struct tree_node *tree_node_new_root(TALLOC_CTX *ctx, struct registry_context *regctx) { const char *hives[] = { "HKEY_CLASSES_ROOT", "HKEY_CURRENT_USER", "HKEY_LOCAL_MACHINE", "HKEY_PERFORMANCE_DATA", "HKEY_USERS", "HKEY_CURRENT_CONFIG", "HKEY_DYN_DATA", "HKEY_PERFORMANCE_TEXT", "HKEY_PERFORMANCE_NLSTEXT", NULL }; struct tree_node *root, *prev, *node; struct registry_key *key; WERROR rv; size_t i; root = tree_node_new(ctx, NULL, "ROOT", NULL); if (root == NULL) { return NULL; } prev = NULL; for (i = 0; hives[i] != NULL; ++i) { rv = reg_get_predefined_key_by_name(regctx, hives[i], &key); if (!W_ERROR_IS_OK(rv)) { continue; } node = tree_node_new(root, root, hives[i], key); if (node == NULL) { return NULL; } if (prev) { tree_node_append(prev, node); } prev = node; } return root; } void tree_node_append(struct tree_node *left, struct tree_node *right) { if (left->next) { right->next = left->next; left->next->previous = right; } left->next = right; right->previous = left; } void tree_node_append_last(struct tree_node *list, struct tree_node *node) { tree_node_append(tree_node_last(list), node); } struct tree_node *tree_node_pop(struct tree_node **plist) { struct tree_node *node; node = *plist; if (node == NULL) return NULL; *plist = node->previous; if (*plist == NULL) { *plist = node->next; } if (node->previous) { node->previous->next = node->next; } if (node->next) { node->next->previous = node->previous; } if (node->parent && node->parent->child_head == node) { node->parent->child_head = node->next; } node->next = NULL; node->previous = NULL; return node; } struct tree_node *tree_node_first(struct tree_node *list) { /* Grab the first node in this list from the parent if available. */ if (list->parent) { return list->parent->child_head; } while (list && list->previous) { list = list->previous; } return list; } struct tree_node *tree_node_last(struct tree_node *list) { while (list && list->next) { list = list->next; } return list; } static uint32_t get_num_subkeys(struct tree_node *node) { const char *classname; uint32_t num_subkeys; uint32_t num_values; NTTIME last_change_time; uint32_t max_subkeynamelen; uint32_t max_valnamelen; uint32_t max_valbufsize; WERROR rv; rv = reg_key_get_info(node, node->key, &classname, &num_subkeys, &num_values, &last_change_time, &max_subkeynamelen, &max_valnamelen, &max_valbufsize); if (W_ERROR_IS_OK(rv)) { return num_subkeys; } return 0; } WERROR tree_node_reopen_key(struct registry_context *ctx, struct tree_node *node) { SMB_ASSERT(node->parent != NULL); SMB_ASSERT(node->name != NULL); TALLOC_FREE(node->key); if (tree_node_is_top_level(node)) { WERROR rv; struct registry_key *key; rv = reg_get_predefined_key_by_name(ctx, node->name, &key); if (W_ERROR_IS_OK(rv)) { node->key = talloc_steal(node, key); } return rv; } return reg_open_key(node, node->parent->key, node->name, &node->key); } bool tree_node_has_children(struct tree_node *node) { if (node->child_head) { return true; } return get_num_subkeys(node) > 0; } static int node_cmp(struct tree_node **a, struct tree_node **b) { return strcmp((*a)->name, (*b)->name); } void tree_node_insert_sorted(struct tree_node *list, struct tree_node *node) { list = tree_node_first(list); if (node_cmp(&list, &node) >= 0) { tree_node_append(node, list); if (list->parent) { list->parent->child_head = node; } return; } while (list->next && node_cmp(&list->next, &node) < 0) { list = list->next; } tree_node_append(list, node); } WERROR tree_node_load_children(struct tree_node *node) { struct registry_key *key; const char *reg_key_name, *klass; NTTIME modified; uint32_t i, nsubkeys, count; WERROR rv; struct tree_node *prev, **array; /* does this node already have it's children loaded? */ if (node->child_head) return WERR_OK; nsubkeys = get_num_subkeys(node); if (nsubkeys == 0) return WERR_OK; array = talloc_zero_array(node, struct tree_node *, nsubkeys); if (array == NULL) { return WERR_NOT_ENOUGH_MEMORY; } for (count = 0, i = 0; i < nsubkeys; ++i) { rv = reg_key_get_subkey_by_index(node, node->key, i, ®_key_name, &klass, &modified); if (!W_ERROR_IS_OK(rv)) { goto finish; } rv = reg_open_key(node, node->key, reg_key_name, &key); if (!W_ERROR_IS_OK(rv)) { continue; } array[count] = tree_node_new(array, node, reg_key_name, key); if (array[count] == NULL) { rv = WERR_NOT_ENOUGH_MEMORY; goto finish; } ++count; } if (count) { TYPESAFE_QSORT(array, count, node_cmp); for (i = 1, prev = array[0]; i < count; ++i) { talloc_steal(node, array[i]); tree_node_append(prev, array[i]); prev = array[i]; } node->child_head = talloc_steal(node, array[0]); rv = WERR_OK; } finish: talloc_free(array); return rv; } static WERROR next_depth_first(struct tree_node **node) { WERROR rv = WERR_OK; SMB_ASSERT(node != NULL && *node != NULL); if (tree_node_has_children(*node)) { /* 1. If the node has children, go to the first one. */ rv = tree_node_load_children(*node); if (W_ERROR_IS_OK(rv)) { SMB_ASSERT((*node)->child_head != NULL); *node = (*node)->child_head; } } else if ((*node)->next) { /* 2. If there's a node directly after this one, go there */ *node = (*node)->next; } else { /* 3. Otherwise, go up the hierarchy to find the next one */ do { *node = (*node)->parent; if (*node && (*node)->next) { *node = (*node)->next; break; } } while (*node); } return rv; } static WERROR prev_depth_first(struct tree_node **node) { WERROR rv = WERR_OK; SMB_ASSERT(node != NULL && *node != NULL); if ((*node)->previous) { *node = (*node)->previous; while (tree_node_has_children(*node)) { rv = tree_node_load_children(*node); if (W_ERROR_IS_OK(rv)) { SMB_ASSERT((*node)->child_head != NULL); *node = tree_node_last((*node)->child_head); } } } else if (!tree_node_is_top_level(*node)) { *node = (*node)->parent; } else { *node = NULL; } return rv; } bool tree_node_next(struct tree_node **node, bool depth, WERROR *err) { *err = WERR_OK; if (*node == NULL) { return false; } if (depth) { *err = next_depth_first(node); } else { *node = (*node)->next; } return *node != NULL && W_ERROR_IS_OK(*err); } bool tree_node_prev(struct tree_node **node, bool depth, WERROR *err) { *err = WERR_OK; if (*node == NULL) { return false; } if (depth) { *err = prev_depth_first(node); } else { *node = (*node)->previous; } return *node != NULL && W_ERROR_IS_OK(*err); } void tree_view_clear(struct tree_view *view) { multilist_set_data(view->list, NULL); } WERROR tree_view_set_root(struct tree_view *view, struct tree_node *root) { multilist_set_data(view->list, NULL); talloc_free(view->root); view->root = root; return tree_view_update(view, root->child_head); } WERROR tree_view_set_path(struct tree_view *view, const char **path) { struct tree_node *top, *node; WERROR rv; top = view->root->child_head; while (*path) { for (node = top; node != NULL; node = node->next) { if (strcmp(*path, node->name) == 0) { if (path[1] && tree_node_has_children(node)) { rv = tree_node_load_children(node); if (!W_ERROR_IS_OK(rv)) { return rv; } SMB_ASSERT(node->child_head); top = node->child_head; break; } else { tree_view_update(view, top); tree_view_set_current_node(view, node); return WERR_OK; } } } ++path; } return WERR_OK; } WERROR tree_view_update(struct tree_view *view, struct tree_node *list) { WERROR rv; rv = multilist_set_data(view->list, list); if (W_ERROR_IS_OK(rv)) { multilist_refresh(view->list); } return rv; } /* is this node in the current level? */ bool tree_view_is_node_visible(struct tree_view *view, struct tree_node *node) { const struct tree_node *first; first = multilist_get_data(view->list); return first && first->parent == node->parent; } void tree_view_set_current_node(struct tree_view *view, struct tree_node *node) { multilist_set_current_row(view->list, node); } struct tree_node *tree_view_get_current_node(struct tree_view *view) { const void *row = multilist_get_current_row(view->list); return talloc_get_type_abort(row, struct tree_node); } void tree_view_driver(struct tree_view *view, int c) { multilist_driver(view->list, c); } void tree_view_set_selected(struct tree_view *view, bool reverse) { attr_t attr = A_NORMAL; if (reverse) { attr = A_REVERSE; } mvwchgat(view->window, 0, HEADING_X, 3, attr, 0, NULL); } void tree_view_show(struct tree_view *view) { multilist_refresh(view->list); touchwin(view->window); wnoutrefresh(view->window); wnoutrefresh(view->sub); } static int tree_view_free(struct tree_view *view) { if (view->panel) { del_panel(view->panel); } if (view->sub) { delwin(view->sub); } if (view->window) { delwin(view->window); } return 0; } static const char *tv_get_column_header(const void *data, unsigned col) { SMB_ASSERT(col == 0); return "Name"; } static const void *tv_get_first_row(const void *data) { if (data == NULL) { return NULL; } return talloc_get_type_abort(data, struct tree_node); } static const void *tv_get_next_row(const void *data, const void *row) { const struct tree_node *node; SMB_ASSERT(row != NULL); node = talloc_get_type_abort(row, struct tree_node); return node->next; } static const void *tv_get_prev_row(const void *data, const void *row) { const struct tree_node *node; SMB_ASSERT(row != NULL); node = talloc_get_type_abort(row, struct tree_node); return node->previous; } static const char *tv_get_item_prefix(const void *row, unsigned col) { struct tree_node *node; SMB_ASSERT(col == 0); SMB_ASSERT(row != NULL); node = talloc_get_type_abort(row, struct tree_node); if (tree_node_has_children(node)) { return "+"; } return " "; } static const char *tv_get_item_label(const void *row, unsigned col) { const struct tree_node *node; SMB_ASSERT(col == 0); SMB_ASSERT(row != NULL); node = talloc_get_type_abort(row, struct tree_node); return node->name; } static struct multilist_accessors tv_accessors = { .get_column_header = tv_get_column_header, .get_first_row = tv_get_first_row, .get_next_row = tv_get_next_row, .get_prev_row = tv_get_prev_row, .get_item_prefix = tv_get_item_prefix, .get_item_label = tv_get_item_label }; struct tree_view *tree_view_new(TALLOC_CTX *ctx, struct tree_node *root, int nlines, int ncols, int begin_y, int begin_x) { struct tree_view *view; view = talloc_zero(ctx, struct tree_view); if (view == NULL) { return NULL; } talloc_set_destructor(view, tree_view_free); view->window = newwin(nlines, ncols, begin_y, begin_x); if (view->window == NULL) { goto fail; } view->sub = subwin(view->window, nlines - 2, ncols - 2, begin_y + 1, begin_x + 1); if (view->sub == NULL) { goto fail; } box(view->window, 0, 0); mvwprintw(view->window, 0, HEADING_X, "Key"); view->panel = new_panel(view->window); if (view->panel == NULL) { goto fail; } view->root = root; view->list = multilist_new(view, view->sub, &tv_accessors, 1); if (view->list == NULL) { goto fail; } tree_view_update(view, root->child_head); return view; fail: talloc_free(view); return NULL; } void tree_view_resize(struct tree_view *view, int nlines, int ncols, int begin_y, int begin_x) { WINDOW *nwin, *nsub; nwin = newwin(nlines, ncols, begin_y, begin_x); if (nwin == NULL) { return; } nsub = subwin(nwin, nlines - 2, ncols - 2, begin_y + 1, begin_x + 1); if (nsub == NULL) { delwin(nwin); return; } replace_panel(view->panel, nwin); delwin(view->sub); delwin(view->window); view->window = nwin; view->sub = nsub; box(view->window, 0, 0); mvwprintw(view->window, 0, HEADING_X, "Key"); multilist_set_window(view->list, view->sub); tree_view_show(view); } const char **tree_node_get_path(TALLOC_CTX *ctx, struct tree_node *node) { const char **array; size_t nitems, idx; struct tree_node *p; for (nitems = 0, p = node; !tree_node_is_root(p); p = p->parent) { ++nitems; } array = talloc_zero_array(ctx, const char *, nitems + 1); if (array == NULL) { return NULL; } for (idx = nitems - 1, p = node; !tree_node_is_root(p); p = p->parent, --idx) { array[idx] = talloc_strdup(array, p->name); if (array[idx] == NULL) { talloc_free(discard_const(array)); return NULL; } } return array; } /* print the path of node to label */ size_t tree_node_print_path(WINDOW *label, struct tree_node *node) { size_t len = 1; const char **path; TALLOC_CTX *frame; if (node == NULL) return 0; werase(label); wprintw(label, "/"); if (tree_node_is_top_level(node)) return 0; frame = talloc_stackframe(); path = tree_node_get_path(frame, node->parent); while (*path) { len += strlen(*path) + 1; wprintw(label, "%s/", *path); ++path; } talloc_free(frame); return len; }