str *
matcher_next(struct matcher *matcher, const void **ref_return)
{
struct match *m, **mp;
while (matcher->matches) {
/* Process all the exhausted strings */
mp = &matcher->matches;
while ((m = *mp)) {
if (stri_more(m->stri)) {
/* Advance the match candidate's state */
unsigned ch = stri_utf8_inc(&m->stri);
if (!globs_step(matcher->globs, ch, &m->state)){
/* Failed to advance; reject it */
*mp = m->next;
match_free(m);
}
} else if (m->flags & MATCH_DEFERRED) {
/* The string is exhausted, but it's
* a deferred string; so expand it now */
struct match *head, **tail;
tail = matcher_generate(matcher, &head, m);
/* Remove the current match (m),
* replacing it with the head..tail that
* was just generated. We don't return m. */
*tail = m->next;
*mp = head;
match_free(m);
} else {
/* Found a real, exhausted string.
* First, remove it from the list */
*mp = m->next;
/* Next, test if it's a real match */
const void *ref = globs_is_accept_state(
matcher->globs, m->state);
if (ref) {
/* It's real.
* Steal the match.str before freeing */
str *result = m->str;
m->str = 0;
match_free(m);
if (ref_return) {
*ref_return = ref;
}
return result;
} else {
/* Not a match; reject */
match_free(m);
}
}
}
}
return 0;
}
void findDiffMatches(const File* file, const License* license,
size_t textStartPosition, size_t searchStartPosition,
GArray* matches,
unsigned int maxAllowedDiff, unsigned int minAdjacentMatches) {
if (!matchNTokens(file->tokens, textStartPosition, file->tokens->len,
license->tokens, searchStartPosition, license->tokens->len,
minAdjacentMatches)) {
return;
}
DiffResult* diffResult = findMatchAsDiffs(file->tokens, license->tokens,
textStartPosition, searchStartPosition,
maxAllowedDiff, minAdjacentMatches);
if (diffResult) {
Match* newMatch = diffResult2Match(diffResult, license);
if (match_rank(newMatch) > MIN_ALLOWED_RANK)
g_array_append_val(matches, newMatch);
else {
match_free(newMatch);
}
}
}
static int driver_remove_match(sd_bus *bus, sd_bus_message *message, void *userdata, sd_bus_error *error) {
struct bus_match_component *components = NULL;
_cleanup_free_ char *normalized = NULL;
Context *context = userdata;
unsigned n_components = 0;
Client *c = NULL;
Match *m = NULL;
char *arg0;
uint64_t id;
int r;
assert(bus);
assert(message);
assert(context);
r = sd_bus_message_read(message, "s", &arg0);
if (r < 0)
return r;
r = bus_kernel_parse_unique_name(message->sender, &id);
if (r < 0)
return r;
c = hashmap_get(context->clients, &id);
if (!c)
return sd_bus_error_setf(error, SD_BUS_ERROR_MATCH_RULE_NOT_FOUND, "You have not registered any matches.");
r = bus_match_parse(arg0, &components, &n_components);
if (r < 0) {
r = sd_bus_error_setf(error, SD_BUS_ERROR_MATCH_RULE_INVALID, "Match rule \"%s\" is not valid", arg0);
goto finish;
}
normalized = bus_match_to_string(components, n_components);
if (!normalized) {
r = -ENOMEM;
goto finish;
}
m = hashmap_get(c->matches, normalized);
if (!m) {
r = sd_bus_error_setf(error, SD_BUS_ERROR_MATCH_RULE_NOT_FOUND, "Match rule \"%s\" not found.", normalized);
goto finish;
}
bus_remove_match_internal_kernel(bus, id, m->cookie);
match_free(m);
r = sd_bus_reply_method_return(message, NULL);
finish:
bus_match_parse_free(components, n_components);
if (c->n_matches <= 0)
client_free(c);
return r;
}
void trace_tree_emit_rule(struct xswitch *sw, struct trace_tree *tree)
{
struct match *ma = match();
struct action *ac_pi = action();
action_add(ac_pi, AC_PACKET_IN, 0);
emit_rule(sw, sw->table0, tree, ma, 1, ac_pi);
action_free(ac_pi);
match_free(ma);
}
/*
* finds the maximal matches according to match_partialComparator
* destructively filter matches array: input array and discarded matches are automatically freed
**/
GArray* filterNonOverlappingMatches(GArray* matches) {
const guint len = matches->len;
/* profiling says this is not time critical and worst case is O(n^2) with any algorithm */
/* instead of removing elements from the array set them to NULL and create a new array at the end */
for (guint i = 0; i < len; i++) {
Match* thisMatch = match_array_index(matches, i);
if (thisMatch == NULL) {
continue;
}
for (guint j = i + 1; j < len; j++) {
Match* otherMatch = match_array_index(matches, j);
if (otherMatch == NULL) {
continue;
}
gint comparison = match_partialComparator(thisMatch, otherMatch);
if (comparison > 0) {
match_free(otherMatch);
match_array_index(matches, j) = NULL;
}
else if (comparison < 0) {
match_free(thisMatch);
match_array_index(matches, i) = NULL;
break;
}
}
}
GArray* result = g_array_new(FALSE, FALSE, sizeof(Match*));
for (guint i = 0; i < len; i++) {
Match* thisMatch = match_array_index(matches, i);
if (thisMatch) {
g_array_append_val(result, thisMatch);
}
}
g_array_free(matches, TRUE);
return result;
}
void match_array_free(GArray* matches) {
#if GLIB_CHECK_VERSION(2, 32, 0)
g_array_set_clear_func(matches, match_destroyNotify);
#else
for (unsigned int i=0; i< matches->len; ++i) {
Match* tmp = g_array_index(matches, Match*, i);
match_free(tmp);
}
#endif
g_array_free(matches, TRUE);
}
static int json_printer_ft1(char *buf, int pos, struct trace_tree *tree)
{
int i;
int priority;
struct trace_tree_V *tv;
struct trace_tree_T *tt;
struct trace_tree_D *td;
struct trace_tree_G *tg;
struct match *ma;
struct action *ac_pi;
switch(tree->type) {
case TT_L:
case TT_E:
return pos;
case TT_D:
td = (struct trace_tree_D *)tree;
return json_printer_ft1(buf, pos, td->t);
case TT_V:
tv = (struct trace_tree_V *)tree;
for(i = 0; i < tv->num_branches; i++) {
pos = json_printer_ft1(buf, pos, tv->branches[i].tree);
}
return pos;
case TT_T:
tt = (struct trace_tree_T *)tree;
pos = json_printer_ft1(buf, pos, tt->f);
pos = json_printer_ft1(buf, pos, tt->t);
return pos;
case TT_G:
tg = (struct trace_tree_G *)tree;
priority = 0;
ac_pi = action();
action_add(ac_pi, AC_PACKET_IN, 0);
ma = match();
pos += sprintf(buf+pos, "{\"tid\":\"%d\",", flow_table_get_tid(tg->ft));
pos += sprintf(buf+pos, "\"columns\":[\"priority\",\"in_port\",");
pos += header_print_json(tg->new_spec, buf+pos);
if(buf[pos-1] == ',')
pos--;
pos += sprintf(buf+pos, ",\"actions\"],");
pos += sprintf(buf+pos, "\"data\":[");
pos = json_printer_ft(buf, pos, tg->t, ma, &priority, ac_pi, tg->new_spec);
if(buf[pos-1] == ',')
pos--;
pos += sprintf(buf+pos, "]},");
action_free(ac_pi);
match_free(ma);
pos = json_printer_ft1(buf, pos, tg->t);
return pos;
}
assert(0);
}
void
matcher_free(struct matcher *matcher)
{
struct match *m, *mnext;
if (matcher->generator->free) {
matcher->generator->free(matcher->gcontext);
}
mnext = matcher->matches;
while ((m = mnext)) {
mnext = m->next;
match_free(m);
}
free(matcher);
}
/* helper */
static void init_entry(struct xswitch *sw, struct flow_table *ft)
{
struct match *ma;
struct msgbuf *msg;
struct action *ac;
int index;
ma = match();
ac = action();
action_add(ac, AC_PACKET_IN, 0);
index = flow_table_get_entry_index(ft);
assert(index == 0);
msg = msg_flow_entry_add(ft, index, 0, ma, ac);
match_free(ma);
action_free(ac);
xswitch_send(sw, msg);
}
static int match_new(Client *c, struct bus_match_component *components, unsigned n_components, Match **_m) {
Match *m, *first;
int r;
assert(c);
assert(_m);
r = hashmap_ensure_allocated(&c->matches, string_hash_func, string_compare_func);
if (r < 0)
return r;
m = new0(Match, 1);
if (!m)
return -ENOMEM;
m->match = bus_match_to_string(components, n_components);
if (!m->match) {
r = -ENOMEM;
goto fail;
}
m->cookie = ++c->next_cookie;
first = hashmap_get(c->matches, m->match);
LIST_PREPEND(matches, first, m);
r = hashmap_replace(c->matches, m->match, first);
if (r < 0) {
LIST_REMOVE(matches, first, m);
goto fail;
}
m->client = c;
c->n_matches++;
*_m = m;
m = NULL;
return 0;
fail:
match_free(m);
return r;
}
static void client_free(Client *c) {
Match *m;
if (!c)
return;
if (c->context) {
if (c->watch)
sd_bus_remove_match(c->context->bus, c->watch, on_name_owner_changed, c);
assert_se(hashmap_remove(c->context->clients, &c->id) == c);
}
while ((m = hashmap_first(c->matches)))
match_free(m);
hashmap_free(c->matches);
free(c->watch);
free(c);
}
void do_test() {
Start:
if (isatty(fileno(stdin)))
printf("Enter a regular expression:\n\n");
if (fgets(buf, BUFFER, stdin) == NULL)
return;
trim(buf);
if ((shre = shre_compile(buf)) == NULL) {
printf("error: %s\n", shre_strerror(shre_er));
goto Start;
}
if (isatty(fileno(stdin)))
printf("\nEnter text to test the regular expression:\n\n");
while (fgets(buf, BUFFER, stdin) != NULL) {
trim(buf);
if (strcmp(buf, "NEW") == 0) {
goto Start;
}
printf("Pattern: '%s'\n", shre_expression(shre));
printf("String: '%s'\n", buf);
printf("Match: ");
if ((match = shre_search(shre, buf)) == NULL) {
printf(" None\n\n");
} else {
printf("'%s'\n", match_get(match));
for (int i = 1; i < match_num_groups(match); ++i) {
printf("Group %2d: ", i);
char* str = match_group(match, i);
if (!str) {
printf(" NULL\n");
} else {
printf("'%s'\n", str);
free(str);
}
}
printf("\n");
match_free(match);
}
}
}
void match_destroyNotify(gpointer matchP) {
match_free(*((Match**) matchP));
}
static int driver_add_match(sd_bus *bus, sd_bus_message *message, void *userdata, sd_bus_error *error) {
struct bus_match_component *components = NULL;
Context *context = userdata;
unsigned n_components = 0;
Match *m = NULL;
Client *c = NULL;
char *arg0;
uint64_t id;
int r;
assert(bus);
assert(message);
assert(context);
r = sd_bus_message_read(message, "s", &arg0);
if (r < 0)
return r;
r = bus_kernel_parse_unique_name(message->sender, &id);
if (r < 0)
return r;
r = client_acquire(context, id, &c);
if (r == -ENOBUFS)
return sd_bus_error_setf(error, SD_BUS_ERROR_LIMITS_EXCEEDED, "Reached limit of %u clients", CLIENTS_MAX);
if (r < 0)
return r;
if (c->n_matches >= MATCHES_MAX) {
r = sd_bus_error_setf(error, SD_BUS_ERROR_LIMITS_EXCEEDED, "Reached limit of %u matches per client", MATCHES_MAX);
goto fail;
}
r = bus_match_parse(arg0, &components, &n_components);
if (r < 0) {
r = sd_bus_error_setf(error, SD_BUS_ERROR_MATCH_RULE_INVALID, "Match rule \"%s\" is not valid", arg0);
goto fail;
}
r = match_new(c, components, n_components, &m);
if (r < 0)
goto fail;
r = bus_add_match_internal_kernel(bus, id, components, n_components, m->cookie);
if (r < 0)
goto fail;
bus_match_parse_free(components, n_components);
return sd_bus_reply_method_return(message, NULL);
fail:
bus_match_parse_free(components, n_components);
match_free(m);
if (c->n_matches <= 0)
client_free(c);
return r;
}
/*
* Do some sanity checks and then reparent the window.
*
*/
void manage_window(xcb_window_t window, xcb_get_window_attributes_cookie_t cookie,
bool needs_to_be_mapped) {
xcb_drawable_t d = {window};
xcb_get_geometry_cookie_t geomc;
xcb_get_geometry_reply_t *geom;
xcb_get_window_attributes_reply_t *attr = NULL;
xcb_get_property_cookie_t wm_type_cookie, strut_cookie, state_cookie,
utf8_title_cookie, title_cookie,
class_cookie, leader_cookie, transient_cookie,
role_cookie, startup_id_cookie, wm_hints_cookie,
wm_normal_hints_cookie, motif_wm_hints_cookie;
geomc = xcb_get_geometry(conn, d);
/* Check if the window is mapped (it could be not mapped when intializing and
calling manage_window() for every window) */
if ((attr = xcb_get_window_attributes_reply(conn, cookie, 0)) == NULL) {
DLOG("Could not get attributes\n");
xcb_discard_reply(conn, geomc.sequence);
return;
}
if (needs_to_be_mapped && attr->map_state != XCB_MAP_STATE_VIEWABLE) {
xcb_discard_reply(conn, geomc.sequence);
goto out;
}
/* Don’t manage clients with the override_redirect flag */
if (attr->override_redirect) {
xcb_discard_reply(conn, geomc.sequence);
goto out;
}
/* Check if the window is already managed */
if (con_by_window_id(window) != NULL) {
DLOG("already managed (by con %p)\n", con_by_window_id(window));
xcb_discard_reply(conn, geomc.sequence);
goto out;
}
/* Get the initial geometry (position, size, …) */
if ((geom = xcb_get_geometry_reply(conn, geomc, 0)) == NULL) {
DLOG("could not get geometry\n");
goto out;
}
uint32_t values[1];
/* Set a temporary event mask for the new window, consisting only of
* PropertyChange and StructureNotify. We need to be notified of
* PropertyChanges because the client can change its properties *after* we
* requested them but *before* we actually reparented it and have set our
* final event mask.
* We need StructureNotify because the client may unmap the window before
* we get to re-parent it.
* If this request fails, we assume the client has already unmapped the
* window between the MapRequest and our event mask change. */
values[0] = XCB_EVENT_MASK_PROPERTY_CHANGE |
XCB_EVENT_MASK_STRUCTURE_NOTIFY;
xcb_void_cookie_t event_mask_cookie =
xcb_change_window_attributes_checked(conn, window, XCB_CW_EVENT_MASK, values);
if (xcb_request_check(conn, event_mask_cookie) != NULL) {
LOG("Could not change event mask, the window probably already disappeared.\n");
goto out;
}
#define GET_PROPERTY(atom, len) xcb_get_property(conn, false, window, atom, XCB_GET_PROPERTY_TYPE_ANY, 0, len)
wm_type_cookie = GET_PROPERTY(A__NET_WM_WINDOW_TYPE, UINT32_MAX);
strut_cookie = GET_PROPERTY(A__NET_WM_STRUT_PARTIAL, UINT32_MAX);
state_cookie = GET_PROPERTY(A__NET_WM_STATE, UINT32_MAX);
utf8_title_cookie = GET_PROPERTY(A__NET_WM_NAME, 128);
leader_cookie = GET_PROPERTY(A_WM_CLIENT_LEADER, UINT32_MAX);
transient_cookie = GET_PROPERTY(XCB_ATOM_WM_TRANSIENT_FOR, UINT32_MAX);
title_cookie = GET_PROPERTY(XCB_ATOM_WM_NAME, 128);
class_cookie = GET_PROPERTY(XCB_ATOM_WM_CLASS, 128);
role_cookie = GET_PROPERTY(A_WM_WINDOW_ROLE, 128);
startup_id_cookie = GET_PROPERTY(A__NET_STARTUP_ID, 512);
wm_hints_cookie = xcb_icccm_get_wm_hints(conn, window);
wm_normal_hints_cookie = xcb_icccm_get_wm_normal_hints(conn, window);
motif_wm_hints_cookie = GET_PROPERTY(A__MOTIF_WM_HINTS, 5 * sizeof(uint64_t));
DLOG("Managing window 0x%08x\n", window);
i3Window *cwindow = scalloc(1, sizeof(i3Window));
cwindow->id = window;
cwindow->depth = get_visual_depth(attr->visual);
/* We need to grab buttons 1-3 for click-to-focus and buttons 1-5
* to allow for mouse bindings using --whole-window to work correctly. */
xcb_grab_button(conn, false, window, XCB_EVENT_MASK_BUTTON_PRESS,
XCB_GRAB_MODE_SYNC, XCB_GRAB_MODE_ASYNC, root, XCB_NONE,
XCB_BUTTON_INDEX_ANY,
XCB_BUTTON_MASK_ANY /* don’t filter for any modifiers */);
/* update as much information as possible so far (some replies may be NULL) */
window_update_class(cwindow, xcb_get_property_reply(conn, class_cookie, NULL), true);
window_update_name_legacy(cwindow, xcb_get_property_reply(conn, title_cookie, NULL), true);
window_update_name(cwindow, xcb_get_property_reply(conn, utf8_title_cookie, NULL), true);
window_update_leader(cwindow, xcb_get_property_reply(conn, leader_cookie, NULL));
window_update_transient_for(cwindow, xcb_get_property_reply(conn, transient_cookie, NULL));
window_update_strut_partial(cwindow, xcb_get_property_reply(conn, strut_cookie, NULL));
window_update_role(cwindow, xcb_get_property_reply(conn, role_cookie, NULL), true);
bool urgency_hint;
window_update_hints(cwindow, xcb_get_property_reply(conn, wm_hints_cookie, NULL), &urgency_hint);
border_style_t motif_border_style = BS_NORMAL;
window_update_motif_hints(cwindow, xcb_get_property_reply(conn, motif_wm_hints_cookie, NULL), &motif_border_style);
xcb_size_hints_t wm_size_hints;
if (!xcb_icccm_get_wm_size_hints_reply(conn, wm_normal_hints_cookie, &wm_size_hints, NULL))
memset(&wm_size_hints, '\0', sizeof(xcb_size_hints_t));
xcb_get_property_reply_t *type_reply = xcb_get_property_reply(conn, wm_type_cookie, NULL);
xcb_get_property_reply_t *state_reply = xcb_get_property_reply(conn, state_cookie, NULL);
xcb_get_property_reply_t *startup_id_reply;
startup_id_reply = xcb_get_property_reply(conn, startup_id_cookie, NULL);
char *startup_ws = startup_workspace_for_window(cwindow, startup_id_reply);
DLOG("startup workspace = %s\n", startup_ws);
/* check if the window needs WM_TAKE_FOCUS */
cwindow->needs_take_focus = window_supports_protocol(cwindow->id, A_WM_TAKE_FOCUS);
/* read the preferred _NET_WM_WINDOW_TYPE atom */
cwindow->window_type = xcb_get_preferred_window_type(type_reply);
/* Where to start searching for a container that swallows the new one? */
Con *search_at = croot;
if (xcb_reply_contains_atom(type_reply, A__NET_WM_WINDOW_TYPE_DOCK)) {
LOG("This window is of type dock\n");
Output *output = get_output_containing(geom->x, geom->y);
if (output != NULL) {
DLOG("Starting search at output %s\n", output->name);
search_at = output->con;
}
/* find out the desired position of this dock window */
if (cwindow->reserved.top > 0 && cwindow->reserved.bottom == 0) {
DLOG("Top dock client\n");
cwindow->dock = W_DOCK_TOP;
} else if (cwindow->reserved.top == 0 && cwindow->reserved.bottom > 0) {
DLOG("Bottom dock client\n");
cwindow->dock = W_DOCK_BOTTOM;
} else {
DLOG("Ignoring invalid reserved edges (_NET_WM_STRUT_PARTIAL), using position as fallback:\n");
if (geom->y < (int16_t)(search_at->rect.height / 2)) {
DLOG("geom->y = %d < rect.height / 2 = %d, it is a top dock client\n",
geom->y, (search_at->rect.height / 2));
cwindow->dock = W_DOCK_TOP;
} else {
DLOG("geom->y = %d >= rect.height / 2 = %d, it is a bottom dock client\n",
geom->y, (search_at->rect.height / 2));
cwindow->dock = W_DOCK_BOTTOM;
}
}
}
DLOG("Initial geometry: (%d, %d, %d, %d)\n", geom->x, geom->y, geom->width, geom->height);
Con *nc = NULL;
Match *match = NULL;
Assignment *assignment;
/* TODO: two matches for one container */
/* See if any container swallows this new window */
nc = con_for_window(search_at, cwindow, &match);
if (nc == NULL) {
/* If not, check if it is assigned to a specific workspace */
if ((assignment = assignment_for(cwindow, A_TO_WORKSPACE))) {
DLOG("Assignment matches (%p)\n", match);
Con *assigned_ws = workspace_get(assignment->dest.workspace, NULL);
nc = con_descend_tiling_focused(assigned_ws);
DLOG("focused on ws %s: %p / %s\n", assigned_ws->name, nc, nc->name);
if (nc->type == CT_WORKSPACE)
nc = tree_open_con(nc, cwindow);
else
nc = tree_open_con(nc->parent, cwindow);
/* set the urgency hint on the window if the workspace is not visible */
if (!workspace_is_visible(assigned_ws))
urgency_hint = true;
} else if (startup_ws) {
/* If it’s not assigned, but was started on a specific workspace,
* we want to open it there */
DLOG("Using workspace on which this application was started (%s)\n", startup_ws);
nc = con_descend_tiling_focused(workspace_get(startup_ws, NULL));
DLOG("focused on ws %s: %p / %s\n", startup_ws, nc, nc->name);
if (nc->type == CT_WORKSPACE)
nc = tree_open_con(nc, cwindow);
else
nc = tree_open_con(nc->parent, cwindow);
} else {
/* If not, insert it at the currently focused position */
if (focused->type == CT_CON && con_accepts_window(focused)) {
LOG("using current container, focused = %p, focused->name = %s\n",
focused, focused->name);
nc = focused;
} else
nc = tree_open_con(NULL, cwindow);
}
} else {
/* M_BELOW inserts the new window as a child of the one which was
* matched (e.g. dock areas) */
if (match != NULL && match->insert_where == M_BELOW) {
nc = tree_open_con(nc, cwindow);
}
/* If M_BELOW is not used, the container is replaced. This happens with
* "swallows" criteria that are used for stored layouts, in which case
* we need to remove that criterion, because they should only be valid
* once. */
if (match != NULL && match->insert_where != M_BELOW) {
DLOG("Removing match %p from container %p\n", match, nc);
TAILQ_REMOVE(&(nc->swallow_head), match, matches);
match_free(match);
}
}
DLOG("new container = %p\n", nc);
if (nc->window != NULL && nc->window != cwindow) {
if (!restore_kill_placeholder(nc->window->id)) {
DLOG("Uh?! Container without a placeholder, but with a window, has swallowed this to-be-managed window?!\n");
} else {
/* Remove remaining criteria, the first swallowed window wins. */
while (!TAILQ_EMPTY(&(nc->swallow_head))) {
Match *first = TAILQ_FIRST(&(nc->swallow_head));
TAILQ_REMOVE(&(nc->swallow_head), first, matches);
match_free(first);
}
}
}
nc->window = cwindow;
x_reinit(nc);
nc->border_width = geom->border_width;
char *name;
sasprintf(&name, "[i3 con] container around %p", cwindow);
x_set_name(nc, name);
free(name);
/* handle fullscreen containers */
Con *ws = con_get_workspace(nc);
Con *fs = (ws ? con_get_fullscreen_con(ws, CF_OUTPUT) : NULL);
if (fs == NULL)
fs = con_get_fullscreen_con(croot, CF_GLOBAL);
if (xcb_reply_contains_atom(state_reply, A__NET_WM_STATE_FULLSCREEN)) {
/* If this window is already fullscreen (after restarting!), skip
* toggling fullscreen, that would drop it out of fullscreen mode. */
if (fs != nc)
con_toggle_fullscreen(nc, CF_OUTPUT);
fs = NULL;
}
bool set_focus = false;
if (fs == NULL) {
DLOG("Not in fullscreen mode, focusing\n");
if (!cwindow->dock) {
/* Check that the workspace is visible and on the same output as
* the current focused container. If the window was assigned to an
* invisible workspace, we should not steal focus. */
Con *current_output = con_get_output(focused);
Con *target_output = con_get_output(ws);
if (workspace_is_visible(ws) && current_output == target_output) {
if (!match || !match->restart_mode) {
set_focus = true;
} else
DLOG("not focusing, matched with restart_mode == true\n");
} else
DLOG("workspace not visible, not focusing\n");
} else
DLOG("dock, not focusing\n");
} else {
DLOG("fs = %p, ws = %p, not focusing\n", fs, ws);
/* Insert the new container in focus stack *after* the currently
* focused (fullscreen) con. This way, the new container will be
* focused after we return from fullscreen mode */
Con *first = TAILQ_FIRST(&(nc->parent->focus_head));
if (first != nc) {
/* We only modify the focus stack if the container is not already
* the first one. This can happen when existing containers swallow
* new windows, for example when restarting. */
TAILQ_REMOVE(&(nc->parent->focus_head), nc, focused);
TAILQ_INSERT_AFTER(&(nc->parent->focus_head), first, nc, focused);
}
}
/* set floating if necessary */
bool want_floating = false;
if (xcb_reply_contains_atom(type_reply, A__NET_WM_WINDOW_TYPE_DIALOG) ||
xcb_reply_contains_atom(type_reply, A__NET_WM_WINDOW_TYPE_UTILITY) ||
xcb_reply_contains_atom(type_reply, A__NET_WM_WINDOW_TYPE_TOOLBAR) ||
xcb_reply_contains_atom(type_reply, A__NET_WM_WINDOW_TYPE_SPLASH) ||
xcb_reply_contains_atom(state_reply, A__NET_WM_STATE_MODAL) ||
(wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_P_MAX_SIZE &&
wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_P_MIN_SIZE &&
wm_size_hints.min_height == wm_size_hints.max_height &&
wm_size_hints.min_width == wm_size_hints.max_width)) {
LOG("This window is a dialog window, setting floating\n");
want_floating = true;
}
if (xcb_reply_contains_atom(state_reply, A__NET_WM_STATE_STICKY))
nc->sticky = true;
FREE(state_reply);
FREE(type_reply);
if (cwindow->transient_for != XCB_NONE ||
(cwindow->leader != XCB_NONE &&
cwindow->leader != cwindow->id &&
con_by_window_id(cwindow->leader) != NULL)) {
LOG("This window is transient for another window, setting floating\n");
want_floating = true;
if (config.popup_during_fullscreen == PDF_LEAVE_FULLSCREEN &&
fs != NULL) {
LOG("There is a fullscreen window, leaving fullscreen mode\n");
con_toggle_fullscreen(fs, CF_OUTPUT);
} else if (config.popup_during_fullscreen == PDF_SMART &&
fs != NULL &&
fs->window != NULL) {
i3Window *transient_win = cwindow;
while (transient_win != NULL &&
transient_win->transient_for != XCB_NONE) {
if (transient_win->transient_for == fs->window->id) {
LOG("This floating window belongs to the fullscreen window (popup_during_fullscreen == smart)\n");
set_focus = true;
break;
}
Con *next_transient = con_by_window_id(transient_win->transient_for);
if (next_transient == NULL)
break;
/* Some clients (e.g. x11-ssh-askpass) actually set
* WM_TRANSIENT_FOR to their own window id, so break instead of
* looping endlessly. */
if (transient_win == next_transient->window)
break;
transient_win = next_transient->window;
}
}
}
/* dock clients cannot be floating, that makes no sense */
if (cwindow->dock)
want_floating = false;
/* Plasma windows set their geometry in WM_SIZE_HINTS. */
if ((wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_US_POSITION || wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_P_POSITION) &&
(wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_US_SIZE || wm_size_hints.flags & XCB_ICCCM_SIZE_HINT_P_SIZE)) {
DLOG("We are setting geometry according to wm_size_hints x=%d y=%d w=%d h=%d\n",
wm_size_hints.x, wm_size_hints.y, wm_size_hints.width, wm_size_hints.height);
geom->x = wm_size_hints.x;
geom->y = wm_size_hints.y;
geom->width = wm_size_hints.width;
geom->height = wm_size_hints.height;
}
/* Store the requested geometry. The width/height gets raised to at least
* 75x50 when entering floating mode, which is the minimum size for a
* window to be useful (smaller windows are usually overlays/toolbars/…
* which are not managed by the wm anyways). We store the original geometry
* here because it’s used for dock clients. */
if (nc->geometry.width == 0)
nc->geometry = (Rect){geom->x, geom->y, geom->width, geom->height};
if (motif_border_style != BS_NORMAL) {
DLOG("MOTIF_WM_HINTS specifies decorations (border_style = %d)\n", motif_border_style);
if (want_floating) {
con_set_border_style(nc, motif_border_style, config.default_floating_border_width);
} else {
con_set_border_style(nc, motif_border_style, config.default_border_width);
}
}
if (want_floating) {
DLOG("geometry = %d x %d\n", nc->geometry.width, nc->geometry.height);
/* automatically set the border to the default value if a motif border
* was not specified */
bool automatic_border = (motif_border_style == BS_NORMAL);
floating_enable(nc, automatic_border);
}
/* explicitly set the border width to the default */
if (nc->current_border_width == -1) {
nc->current_border_width = (want_floating ? config.default_floating_border_width : config.default_border_width);
}
/* to avoid getting an UnmapNotify event due to reparenting, we temporarily
* declare no interest in any state change event of this window */
values[0] = XCB_NONE;
xcb_change_window_attributes(conn, window, XCB_CW_EVENT_MASK, values);
xcb_void_cookie_t rcookie = xcb_reparent_window_checked(conn, window, nc->frame, 0, 0);
if (xcb_request_check(conn, rcookie) != NULL) {
LOG("Could not reparent the window, aborting\n");
goto geom_out;
}
values[0] = CHILD_EVENT_MASK & ~XCB_EVENT_MASK_ENTER_WINDOW;
xcb_change_window_attributes(conn, window, XCB_CW_EVENT_MASK, values);
xcb_flush(conn);
/* Put the client inside the save set. Upon termination (whether killed or
* normal exit does not matter) of the window manager, these clients will
* be correctly reparented to their most closest living ancestor (=
* cleanup) */
xcb_change_save_set(conn, XCB_SET_MODE_INSERT, window);
/* Check if any assignments match */
run_assignments(cwindow);
/* 'ws' may be invalid because of the assignments, e.g. when the user uses
* "move window to workspace 1", but had it assigned to workspace 2. */
ws = con_get_workspace(nc);
/* If this window was put onto an invisible workspace (via assignments), we
* render this workspace. It wouldn’t be rendered in our normal code path
* because only the visible workspaces get rendered.
*
* By rendering the workspace, we assign proper coordinates (read: not
* width=0, height=0) to the window, which is important for windows who
* actually use them to position their GUI elements, e.g. rhythmbox. */
if (ws && !workspace_is_visible(ws)) {
/* This is a bit hackish: we need to copy the content container’s rect
* to the workspace, because calling render_con() on the content
* container would also take the shortcut and not render the invisible
* workspace at all. However, just calling render_con() on the
* workspace isn’t enough either — it needs the rect. */
ws->rect = ws->parent->rect;
render_con(ws, true);
/* Disable setting focus, otherwise we’d move focus to an invisible
* workspace, which we generally prevent (e.g. in
* con_move_to_workspace). */
set_focus = false;
}
render_con(croot, false);
/* Send an event about window creation */
ipc_send_window_event("new", nc);
if (set_focus && assignment_for(cwindow, A_NO_FOCUS) != NULL) {
/* The first window on a workspace should always be focused. We have to
* compare with == 1 because the container has already been inserted at
* this point. */
if (con_num_children(ws) == 1) {
DLOG("This is the first window on this workspace, ignoring no_focus.\n");
} else {
DLOG("no_focus was set for con = %p, not setting focus.\n", nc);
set_focus = false;
}
}
/* Defer setting focus after the 'new' event has been sent to ensure the
* proper window event sequence. */
if (set_focus && !nc->window->doesnt_accept_focus && nc->mapped) {
DLOG("Now setting focus.\n");
con_focus(nc);
}
tree_render();
/* Windows might get managed with the urgency hint already set (Pidgin is
* known to do that), so check for that and handle the hint accordingly.
* This code needs to be in this part of manage_window() because the window
* needs to be on the final workspace first. */
con_set_urgency(nc, urgency_hint);
geom_out:
free(geom);
out:
free(attr);
return;
}
static int emit_rule(struct xswitch *sw, struct flow_table *ft,
struct trace_tree *tree, struct match *ma, int priority,
struct action *ac_pi)
{
int i;
struct trace_tree_L *tl;
struct trace_tree_V *tv;
struct trace_tree_T *tt;
struct trace_tree_D *td;
struct trace_tree_G *tg;
struct msgbuf *msg;
struct match *maa;
struct action *a;
char buf[128], buf2[128];
struct expr *move_expr;
switch(tree->type) {
case TT_L:
tl = (struct trace_tree_L *)tree;
match_dump(ma, buf, 128);
action_dump(tl->ac, buf2, 128);
xdebug("tid %d: %2d, %s, %s\n",
flow_table_get_tid(ft), priority, buf, buf2);
if(tl->index == -1) {
tl->index = flow_table_get_entry_index(ft);
msg = msg_flow_entry_add(ft, tl->index, priority, ma, tl->ac);
} else {
msg = msg_flow_entry_mod(ft, tl->index, priority, ma, tl->ac);
}
xswitch_send(sw, msg);
return priority + 1;
case TT_V:
tv = (struct trace_tree_V *)tree;
for(i = 0; i < tv->num_branches; i++) {
maa = match_copy(ma);
match_add(maa,
tv->name,
tv->branches[i].value,
value_from_64(0xffffffffffffffffull));
priority = emit_rule(sw, ft, tv->branches[i].tree, maa, priority, ac_pi);
match_free(maa);
}
return priority;
case TT_T:
tt = (struct trace_tree_T *)tree;
priority = emit_rule(sw, ft, tt->f, ma, priority, ac_pi);
maa = match_copy(ma);
match_add(maa,
tt->name,
tt->value,
value_from_64(0xffffffffffffffffull));
action_dump(ac_pi, buf, 128);
xdebug("tid %d: %2d, BARRIER, %s\n",
flow_table_get_tid(ft), priority, buf);
if(tt->barrier_index == -1) {
tt->barrier_index = flow_table_get_entry_index(ft);
msg = msg_flow_entry_add(ft, tt->barrier_index, priority, maa, ac_pi);
} else {
msg = msg_flow_entry_mod(ft, tt->barrier_index, priority, maa, ac_pi);
}
xswitch_send(sw, msg);
priority = emit_rule(sw, ft, tt->t, maa, priority + 1, ac_pi);
match_free(maa);
return priority;
case TT_G:
tg = (struct trace_tree_G *)tree;
if(tg->ft == NULL) {
int tid = sw->next_table_id++;
// add a new table
tg->ft = header_make_flow_table(tg->new_spec, tid);
msg = msg_flow_table_add(tg->ft);
xswitch_send(sw, msg);
init_entry(sw, tg->ft);
}
// insert GOTO_TABLE into orig table
a = action();
if(tg->old_spec)
move_expr = header_get_length(tg->old_spec);
else
move_expr = expr_value(0);
expr_generate_action(move_expr, tg->old_spec, tg->ft, tg->stack_base, a);
match_dump(ma, buf, 128);
action_dump(a, buf2, 128);
xdebug("tid %d: %2d, %s, %s\n",
flow_table_get_tid(ft), priority, buf, buf2);
if(tg->index == -1) {
tg->index = flow_table_get_entry_index(ft);
msg = msg_flow_entry_add(ft, tg->index, priority, ma, a);
} else {
msg = msg_flow_entry_mod(ft, tg->index, priority, ma, a);
}
xswitch_send(sw, msg);
action_free(a);
maa = match();
emit_rule(sw, tg->ft, tg->t, maa, 1, ac_pi);
match_free(maa);
return priority + 1;
case TT_D:
td = (struct trace_tree_D *)tree;
return emit_rule(sw, ft, td->t, ma, priority, ac_pi);
case TT_E:
return priority;
}
assert(0);
}
static int json_printer_ft(char *buf, int pos,
struct trace_tree *tree, struct match *ma, int *priority,
struct action *ac_pi, struct header *h)
{
int i;
struct trace_tree_L *tl;
struct trace_tree_V *tv;
struct trace_tree_T *tt;
struct trace_tree_D *td;
struct trace_tree_G *tg;
struct match *maa;
struct action *a;
char buf2[128];
struct expr *move_expr;
switch(tree->type) {
case TT_L:
tl = (struct trace_tree_L *)tree;
pos = json_printer_fe(buf, pos, *priority, h, ma, tl->ac);
(*priority)++;
return pos;
case TT_V:
tv = (struct trace_tree_V *)tree;
for(i = 0; i < tv->num_branches; i++) {
maa = match_copy(ma);
match_add(maa,
tv->name,
tv->branches[i].value,
value_from_64(0xffffffffffffffffull));
pos = json_printer_ft(buf, pos, tv->branches[i].tree, maa, priority, ac_pi, h);
match_free(maa);
}
return pos;
case TT_T:
tt = (struct trace_tree_T *)tree;
pos = json_printer_ft(buf, pos, tt->f, ma, priority, ac_pi, h);
maa = match_copy(ma);
match_add(maa,
tt->name,
tt->value,
value_from_64(0xffffffffffffffffull));
pos = json_printer_fe(buf, pos, *priority, h, maa, ac_pi);
(*priority)++;
pos = json_printer_ft(buf, pos, tt->t, maa, priority, ac_pi, h);
match_free(maa);
return pos;
case TT_G:
tg = (struct trace_tree_G *)tree;
// insert GOTO_TABLE into orig table
a = action();
if(tg->old_spec)
move_expr = header_get_length(tg->old_spec);
else
move_expr = expr_value(0);
expr_generate_action(move_expr, tg->old_spec, tg->ft, tg->stack_base, a);
action_dump(a, buf2, 128);
pos = json_printer_fe(buf, pos, *priority, h, ma, a);
action_free(a);
(*priority)++;
return pos;
case TT_D:
td = (struct trace_tree_D *)tree;
return json_printer_ft(buf, pos, td->t, ma, priority, ac_pi, h);
case TT_E:
return pos;
}
assert(0);
}
