/* * vim:ts=4:sw=4:expandtab */ #include "all.h" struct Con *croot; struct Con *focused; struct all_cons_head all_cons = TAILQ_HEAD_INITIALIZER(all_cons); /* * Loads tree from ~/.i3/_restart.json (used for in-place restarts). * */ bool tree_restore(const char *path) { char *globbed = resolve_tilde(path); if (!path_exists(globbed)) { LOG("%s does not exist, not restoring tree\n", globbed); free(globbed); return false; } /* TODO: refactor the following */ croot = con_new(NULL); focused = croot; tree_append_json(globbed); printf("appended tree, using new root\n"); croot = TAILQ_FIRST(&(croot->nodes_head)); printf("new root = %p\n", croot); Con *out = TAILQ_FIRST(&(croot->nodes_head)); printf("out = %p\n", out); Con *ws = TAILQ_FIRST(&(out->nodes_head)); printf("ws = %p\n", ws); return true; } /* * Initializes the tree by creating the root node, adding all RandR outputs * to the tree (that means randr_init() has to be called before) and * assigning a workspace to each RandR output. * */ void tree_init() { Output *output; croot = con_new(NULL); croot->name = "root"; croot->type = CT_ROOT; Con *ws; int c = 1; /* add the outputs */ TAILQ_FOREACH(output, &outputs, outputs) { if (!output->active) continue; Con *oc = con_new(croot); oc->name = strdup(output->name); oc->type = CT_OUTPUT; oc->rect = output->rect; output->con = oc; char *name; asprintf(&name, "[i3 con] output %s", oc->name); x_set_name(oc, name); free(name); /* add a workspace to this output */ ws = con_new(NULL); ws->type = CT_WORKSPACE; ws->num = c; asprintf(&(ws->name), "%d", c); c++; con_attach(ws, oc, false); asprintf(&name, "[i3 con] workspace %s", ws->name); x_set_name(ws, name); free(name); ws->fullscreen_mode = CF_OUTPUT; ws->orientation = HORIZ; } con_focus(ws); } /* * Opens an empty container in the current container * */ Con *tree_open_con(Con *con) { if (con == NULL) { /* every focusable Con has a parent (outputs have parent root) */ con = focused->parent; /* If the parent is an output, we are on a workspace. In this case, * the new container needs to be opened as a leaf of the workspace. */ if (con->type == CT_OUTPUT) con = focused; /* If the currently focused container is a floating container, we * attach the new container to the workspace */ if (con->type == CT_FLOATING_CON) con = con->parent; } assert(con != NULL); /* 3: re-calculate child->percent for each child */ con_fix_percent(con, WINDOW_ADD); /* 4: add a new container leaf to this con */ Con *new = con_new(con); con_focus(new); return new; } /* * vanishing is the container that is about to be closed (so any floating * client which has old_parent == vanishing needs to be "re-parented"). * */ static void fix_floating_parent(Con *con, Con *vanishing) { Con *child; if (con->old_parent == vanishing) { LOG("Fixing vanishing old_parent (%p) of container %p to be %p\n", vanishing, con, vanishing->parent); con->old_parent = vanishing->parent; } TAILQ_FOREACH(child, &(con->floating_head), floating_windows) fix_floating_parent(child, vanishing); TAILQ_FOREACH(child, &(con->nodes_head), nodes) fix_floating_parent(child, vanishing); } static bool _is_con_mapped(Con *con) { Con *child; TAILQ_FOREACH(child, &(con->nodes_head), nodes) if (_is_con_mapped(child)) return true; return con->mapped; } /* * Closes the given container including all children * */ void tree_close(Con *con, bool kill_window, bool dont_kill_parent) { bool was_mapped = con->mapped; Con *parent = con->parent; if (!was_mapped) { /* Even if the container itself is not mapped, its children may be * mapped (for example split containers don't have a mapped window on * their own but usually contain mapped children). */ was_mapped = _is_con_mapped(con); } /* check floating clients and adjust old_parent if necessary */ fix_floating_parent(croot, con); /* Get the container which is next focused */ Con *next = con_next_focused(con); DLOG("closing %p, kill_window = %d\n", con, kill_window); Con *child; /* We cannot use TAILQ_FOREACH because the children get deleted * in their parent’s nodes_head */ while (!TAILQ_EMPTY(&(con->nodes_head))) { child = TAILQ_FIRST(&(con->nodes_head)); DLOG("killing child=%p\n", child); tree_close(child, kill_window, true); } if (con->window != NULL) { if (kill_window) x_window_kill(con->window->id); else { /* un-parent the window */ xcb_reparent_window(conn, con->window->id, root, 0, 0); /* TODO: client_unmap to set state to withdrawn */ } free(con->window); } /* kill the X11 part of this container */ x_con_kill(con); con_detach(con); if (con->type != CT_FLOATING_CON) { /* If the container is *not* floating, we might need to re-distribute * percentage values for the resized containers. */ con_fix_percent(parent, WINDOW_REMOVE); } if (con_is_floating(con)) { DLOG("Container was floating, killing floating container\n"); tree_close(parent, false, false); next = NULL; } free(con->name); TAILQ_REMOVE(&all_cons, con, all_cons); free(con); /* in the case of floating windows, we already focused another container * when closing the parent, so we can exit now. */ if (!next) return; if (was_mapped || con == focused) { DLOG("focusing %p / %s\n", next, next->name); /* TODO: check if the container (or one of its children) was focused */ con_focus(next); } else { DLOG("not focusing, was not mapped\n"); } /* check if the parent container is empty now and close it */ if (!dont_kill_parent && parent->type != CT_WORKSPACE && TAILQ_EMPTY(&(parent->nodes_head))) { DLOG("Closing empty parent container\n"); /* TODO: check if this container would swallow any other client and * don’t close it automatically. */ tree_close(parent, false, false); } } /* * Closes the current container using tree_close(). * */ void tree_close_con() { assert(focused != NULL); if (focused->type == CT_WORKSPACE) { LOG("Cannot close workspace\n"); return; } /* There *should* be no possibility to focus outputs / root container */ assert(focused->type != CT_OUTPUT); assert(focused->type != CT_ROOT); /* Kill con */ tree_close(focused, true, false); } /* * Splits (horizontally or vertically) the given container by creating a new * container which contains the old one and the future ones. * */ void tree_split(Con *con, orientation_t orientation) { /* for a workspace, we just need to change orientation */ if (con->type == CT_WORKSPACE) { DLOG("Workspace, simply changing orientation to %d\n", orientation); con->orientation = orientation; return; } Con *parent = con->parent; /* if we are in a container whose parent contains only one * child (its split functionality is unused so far), we just change the * orientation (more intuitive than splitting again) */ if (con_num_children(parent) == 1) { parent->orientation = orientation; DLOG("Just changing orientation of existing container\n"); return; } DLOG("Splitting in orientation %d\n", orientation); /* 2: replace it with a new Con */ Con *new = con_new(NULL); TAILQ_REPLACE(&(parent->nodes_head), con, new, nodes); TAILQ_REPLACE(&(parent->focus_head), con, new, focused); new->parent = parent; new->orientation = orientation; /* 3: swap 'percent' (resize factor) */ new->percent = con->percent; con->percent = 0.0; /* 4: add it as a child to the new Con */ con_attach(con, new, false); } /* * Moves focus one level up. * */ void level_up() { /* We can focus up to the workspace, but not any higher in the tree */ if (focused->parent->type != CT_CON && focused->parent->type != CT_WORKSPACE) { printf("cannot go up\n"); return; } con_focus(focused->parent); } /* * Moves focus one level down. * */ void level_down() { /* Go down the focus stack of the current node */ Con *next = TAILQ_FIRST(&(focused->focus_head)); if (next == TAILQ_END(&(focused->focus_head))) { printf("cannot go down\n"); return; } con_focus(next); } static void mark_unmapped(Con *con) { Con *current; con->mapped = false; TAILQ_FOREACH(current, &(con->nodes_head), nodes) mark_unmapped(current); if (con->type == CT_WORKSPACE) { TAILQ_FOREACH(current, &(con->floating_head), floating_windows) { current->mapped = false; Con *child = TAILQ_FIRST(&(current->nodes_head)); child->mapped = false; } } } /* * Renders the tree, that is rendering all outputs using render_con() and * pushing the changes to X11 using x_push_changes(). * */ void tree_render() { if (croot == NULL) return; printf("-- BEGIN RENDERING --\n"); /* Reset map state for all nodes in tree */ /* TODO: a nicer method to walk all nodes would be good, maybe? */ mark_unmapped(croot); croot->mapped = true; /* We start rendering at an output */ Con *output; TAILQ_FOREACH(output, &(croot->nodes_head), nodes) { printf("output %p / %s\n", output, output->name); render_con(output, false); } x_push_changes(croot); printf("-- END RENDERING --\n"); } /* * Changes focus in the given way (next/previous) and given orientation * (horizontal/vertical). * */ void tree_next(char way, orientation_t orientation) { /* 1: get the first parent with the same orientation */ Con *parent = focused->parent; while (focused->type != CT_WORKSPACE && con_orientation(parent) != orientation) { LOG("need to go one level further up\n"); /* if the current parent is an output, we are at a workspace * and the orientation still does not match */ if (parent->type == CT_WORKSPACE) return; parent = parent->parent; } Con *current = TAILQ_FIRST(&(parent->focus_head)); assert(current != TAILQ_END(&(parent->focus_head))); /* 2: chose next (or previous) */ Con *next; if (way == 'n') { next = TAILQ_NEXT(current, nodes); /* if we are at the end of the list, we need to wrap */ if (next == TAILQ_END(&(parent->nodes_head))) next = TAILQ_FIRST(&(parent->nodes_head)); } else { next = TAILQ_PREV(current, nodes_head, nodes); /* if we are at the end of the list, we need to wrap */ if (next == TAILQ_END(&(parent->nodes_head))) next = TAILQ_LAST(&(parent->nodes_head), nodes_head); } /* 3: focus choice comes in here. at the moment we will go down * until we find a window */ /* TODO: check for window, atm we only go down as far as possible */ while (!TAILQ_EMPTY(&(next->focus_head))) next = TAILQ_FIRST(&(next->focus_head)); DLOG("focusing %p\n", next); con_focus(next); } /* * Moves the current container in the given way (next/previous) and given * orientation (horizontal/vertical). * */ void tree_move(char way, orientation_t orientation) { /* 1: get the first parent with the same orientation */ Con *parent = focused->parent; Con *old_parent = parent; if (focused->type == CT_WORKSPACE) return; bool level_changed = false; while (con_orientation(parent) != orientation) { DLOG("need to go one level further up\n"); /* If the current parent is an output, we are at a workspace * and the orientation still does not match. In this case, we split the * workspace to have the same look & feel as in older i3 releases. */ if (parent->type == CT_WORKSPACE) { DLOG("Arrived at workspace, splitting...\n"); /* 1: create a new split container */ Con *new = con_new(NULL); new->parent = parent; /* 2: copy layout and orientation from workspace */ new->layout = parent->layout; new->orientation = parent->orientation; Con *old_focused = TAILQ_FIRST(&(parent->focus_head)); if (old_focused == TAILQ_END(&(parent->focus_head))) old_focused = NULL; /* 3: move the existing cons of this workspace below the new con */ DLOG("Moving cons\n"); Con *child; while (!TAILQ_EMPTY(&(parent->nodes_head))) { child = TAILQ_FIRST(&(parent->nodes_head)); con_detach(child); con_attach(child, new, true); } /* 4: switch workspace orientation */ parent->orientation = orientation; /* 4: attach the new split container to the workspace */ DLOG("Attaching new split to ws\n"); con_attach(new, parent, false); if (old_focused) con_focus(old_focused); level_changed = true; break; } parent = parent->parent; level_changed = true; } Con *current = TAILQ_FIRST(&(parent->focus_head)); assert(current != TAILQ_END(&(parent->focus_head))); /* 2: chose next (or previous) */ Con *next = current; if (way == 'n') { LOG("i would insert it after %p / %s\n", next, next->name); /* Have a look at the next container: If there is no next container or * if it is a leaf node, we move the focused one left to it. However, * for split containers, we descend into it. */ next = TAILQ_NEXT(next, nodes); if (next == TAILQ_END(&(next->parent->nodes_head))) { if (focused == current) return; next = current; } else { if (level_changed && con_is_leaf(next)) { next = current; } else { /* if this is a split container, we need to go down */ while (!TAILQ_EMPTY(&(next->focus_head))) next = TAILQ_FIRST(&(next->focus_head)); } } con_detach(focused); focused->parent = next->parent; TAILQ_INSERT_AFTER(&(next->parent->nodes_head), next, focused, nodes); TAILQ_INSERT_HEAD(&(next->parent->focus_head), focused, focused); /* TODO: don’t influence focus handling? */ } else { LOG("i would insert it before %p / %s\n", current, current->name); bool gone_down = false; next = TAILQ_PREV(next, nodes_head, nodes); if (next == TAILQ_END(&(next->parent->nodes_head))) { if (focused == current) return; next = current; } else { if (level_changed && con_is_leaf(next)) { next = current; } else { /* if this is a split container, we need to go down */ while (!TAILQ_EMPTY(&(next->focus_head))) { gone_down = true; next = TAILQ_FIRST(&(next->focus_head)); } } } con_detach(focused); focused->parent = next->parent; /* After going down in the tree, we insert the container *after* * the currently focused one even though the command used "before". * This is to keep the user experience clear, since the before/after * only signifies the direction of the movement on top-level */ if (gone_down) TAILQ_INSERT_AFTER(&(next->parent->nodes_head), next, focused, nodes); else TAILQ_INSERT_BEFORE(next, focused, nodes); TAILQ_INSERT_HEAD(&(next->parent->focus_head), focused, focused); /* TODO: don’t influence focus handling? */ } /* We need to call con_focus() to fix the focus stack "above" the container * we just inserted the focused container into (otherwise, the parent * container(s) would still point to the old container(s)). */ con_focus(focused); if (con_num_children(old_parent) == 0) { DLOG("Old container empty after moving. Let's close it\n"); tree_close(old_parent, false, false); } }