static void
clutter_flow_layout_get_preferred_height (ClutterLayoutManager *manager,
ClutterContainer *container,
gfloat for_width,
gfloat *min_height_p,
gfloat *nat_height_p)
{
ClutterFlowLayoutPrivate *priv = CLUTTER_FLOW_LAYOUT (manager)->priv;
GList *l, *children = clutter_container_get_children (container);
gint n_columns, line_item_count, line_count;
gfloat total_min_height, total_natural_height;
gfloat line_min_height, line_natural_height;
gfloat max_min_height, max_natural_height;
gfloat item_x;
n_columns = get_columns (CLUTTER_FLOW_LAYOUT (manager), for_width);
total_min_height = 0;
total_natural_height = 0;
line_min_height = 0;
line_natural_height = 0;
line_item_count = 0;
line_count = 0;
item_x = 0;
/* clear the line height arrays */
if (priv->line_min != NULL)
g_array_free (priv->line_min, TRUE);
if (priv->line_natural != NULL)
g_array_free (priv->line_natural, TRUE);
priv->line_min = g_array_sized_new (FALSE, FALSE,
sizeof (gfloat),
16);
priv->line_natural = g_array_sized_new (FALSE, FALSE,
sizeof (gfloat),
16);
if (children)
line_count = 1;
max_min_height = max_natural_height = 0;
for (l = children; l != NULL; l = l->next)
{
ClutterActor *child = l->data;
gfloat child_min, child_natural;
gfloat new_x, item_width;
if (!CLUTTER_ACTOR_IS_VISIBLE (child))
continue;
if (priv->orientation == CLUTTER_FLOW_HORIZONTAL && for_width > 0)
{
if (line_item_count == n_columns)
{
total_min_height += line_min_height;
total_natural_height += line_natural_height;
g_array_append_val (priv->line_min,
line_min_height);
g_array_append_val (priv->line_natural,
line_natural_height);
line_min_height = line_natural_height = 0;
line_item_count = 0;
line_count += 1;
item_x = 0;
}
new_x = ((line_item_count + 1) * (for_width + priv->col_spacing))
/ n_columns;
item_width = new_x - item_x - priv->col_spacing;
clutter_actor_get_preferred_height (child, item_width,
&child_min,
&child_natural);
line_min_height = MAX (line_min_height, child_min);
line_natural_height = MAX (line_natural_height, child_natural);
item_x = new_x;
line_item_count += 1;
max_min_height = MAX (max_min_height, line_min_height);
max_natural_height = MAX (max_natural_height, line_natural_height);
}
else
{
clutter_actor_get_preferred_height (child, for_width,
&child_min,
&child_natural);
max_min_height = MAX (max_min_height, child_min);
max_natural_height = MAX (max_natural_height, child_natural);
total_min_height += max_min_height;
total_natural_height += max_natural_height;
line_count += 1;
}
}
g_list_free (children);
priv->row_height = max_natural_height;
if (priv->max_row_height > 0 && priv->row_height > priv->max_row_height)
priv->row_height = MAX (priv->max_row_height, max_min_height);
if (priv->row_height < priv->min_row_height)
priv->row_height = priv->min_row_height;
if (priv->orientation == CLUTTER_FLOW_HORIZONTAL && for_width > 0)
{
/* if we have a non-full row we need to add it */
if (line_item_count > 0)
{
total_min_height += line_min_height;
total_natural_height += line_natural_height;
g_array_append_val (priv->line_min,
line_min_height);
g_array_append_val (priv->line_natural,
line_natural_height);
}
priv->line_count = line_count;
if (priv->line_count > 0)
{
gfloat total_spacing;
total_spacing = priv->row_spacing * (priv->line_count - 1);
total_min_height += total_spacing;
total_natural_height += total_spacing;
}
}
else
{
g_array_append_val (priv->line_min, line_min_height);
g_array_append_val (priv->line_natural, line_natural_height);
priv->line_count = line_count;
if (priv->line_count > 0)
{
gfloat total_spacing;
total_spacing = priv->col_spacing * priv->line_count;
total_min_height += total_spacing;
total_natural_height += total_spacing;
}
}
CLUTTER_NOTE (LAYOUT,
"Flow[h]: %d lines (%d per line): w [ %.2f, %.2f ] for h %.2f",
n_columns, priv->line_count,
total_min_height,
total_natural_height,
for_width);
if (min_height_p)
*min_height_p = total_min_height;
if (nat_height_p)
*nat_height_p = total_natural_height;
}
static gboolean
process_nduseropt_dnssl (NMIP6Device *device, struct nd_opt_hdr *opt)
{
size_t opt_len;
struct nd_opt_dnssl *dnssl_opt;
unsigned char *opt_ptr;
time_t now = time (NULL);
GArray *new_domains;
NMIP6DNSSL domain, *cur_domain;
gboolean changed;
guint i;
opt_len = opt->nd_opt_len;
if (opt_len < 2)
return FALSE;
dnssl_opt = (struct nd_opt_dnssl *) opt;
opt_ptr = (unsigned char *)(dnssl_opt + 1);
opt_len = (opt_len - 1) * 8; /* prefer bytes for later handling */
new_domains = g_array_new (FALSE, FALSE, sizeof (NMIP6DNSSL));
changed = FALSE;
/* Pad the DNS server expiry somewhat to give a bit of slack in cases
* where one RA gets lost or something (which can happen on unreliable
* links like wifi where certain types of frames are not retransmitted).
* Note that 0 has special meaning and is therefore not adjusted.
*/
domain.expires = ntohl (dnssl_opt->nd_opt_dnssl_lifetime);
if (domain.expires > 0)
domain.expires += now + 10;
while (opt_len) {
const char *domain_str;
domain_str = parse_dnssl_domain (opt_ptr, opt_len);
if (domain_str == NULL) {
nm_log_dbg (LOGD_IP6, "(%s): invalid DNSSL option, parsing aborted",
device->iface);
break;
}
/* The DNSSL encoding of domains happen to occupy the same size
* as the length of the resulting string, including terminating
* null. */
opt_ptr += strlen (domain_str) + 1;
opt_len -= strlen (domain_str) + 1;
/* Ignore empty domains. They're probably just padding... */
if (domain_str[0] == '\0')
continue;
/* Update cached domain information if we've seen this domain before */
for (i = 0; i < device->dnssl_domains->len; i++) {
cur_domain = &(g_array_index (device->dnssl_domains, NMIP6DNSSL, i));
if (strcmp (domain_str, cur_domain->domain) != 0)
continue;
cur_domain->expires = domain.expires;
if (domain.expires > 0) {
nm_log_dbg (LOGD_IP6, "(%s): refreshing RA-provided domain %s (expires in %ld seconds)",
device->iface, domain_str,
domain.expires - now);
break;
}
nm_log_dbg (LOGD_IP6, "(%s): removing RA-provided domain %s on router request",
device->iface, domain_str);
g_array_remove_index (device->dnssl_domains, i);
changed = TRUE;
break;
}
if (domain.expires == 0)
continue;
if (i < device->dnssl_domains->len)
continue;
nm_log_dbg (LOGD_IP6, "(%s): found RA-provided domain %s (expires in %ld seconds)",
device->iface, domain_str, domain.expires - now);
g_assert (strlen (domain_str) < sizeof (domain.domain));
strcpy (domain.domain, domain_str);
g_array_append_val (new_domains, domain);
}
/* New domains must be added in the order they are listed in the
* RA option and before any existing domains.
*
* Note: This is the place to remove domains if we want to cap the
* number of domains. The RFC states that the one to expire
* first of the existing domains should be removed.
*/
if (new_domains->len) {
g_array_prepend_vals (device->dnssl_domains,
new_domains->data, new_domains->len);
changed = TRUE;
}
g_array_free (new_domains, TRUE);
/* Timeouts may have changed even if domains didn't */
set_dnssl_timeout (device);
return changed;
}
/**
* parse_output_fields:
* @field_str: comma-separated field names to parse
* @fields_array: array of allowed fields
* @parse_groups: whether the fields can contain group prefix (e.g. general.driver)
* @group_fields: (out) (allow-none): array of field names for particular groups
* @error: (out) (allow-none): location to store error, or %NULL
*
* Parses comma separated fields in @fields_str according to @fields_array.
* When @parse_groups is %TRUE, fields can be in the form 'group.field'. Then
* @group_fields will be filled with the required field for particular group.
* @group_fields array corresponds to the returned array.
* Examples:
* @field_str: "type,name,uuid" | "ip4,general.device" | "ip4.address,ip6"
* returned array: 2 0 1 | 7 0 | 7 9
* @group_fields: NULL NULL NULL | NULL "device" | "address" NULL
*
* Returns: #GArray with indices representing fields in @fields_array.
* Caller is responsible for freeing the array.
*/
GArray *
parse_output_fields (const char *fields_str,
const NmcOutputField fields_array[],
gboolean parse_groups,
GPtrArray **group_fields,
GError **error)
{
char **fields, **iter;
GArray *array;
int i, j;
g_return_val_if_fail (error == NULL || *error == NULL, NULL);
g_return_val_if_fail (group_fields == NULL || *group_fields == NULL, NULL);
array = g_array_new (FALSE, FALSE, sizeof (int));
if (parse_groups && group_fields)
*group_fields = g_ptr_array_new_full (20, (GDestroyNotify) g_free);
/* Split supplied fields string */
fields = g_strsplit_set (fields_str, ",", -1);
for (iter = fields; iter && *iter; iter++) {
int idx = -1;
g_strstrip (*iter);
if (parse_groups) {
/* e.g. "general.device,general.driver,ip4,ip6" */
gboolean found = FALSE;
char *left = *iter;
char *right = strchr (*iter, '.');
if (right)
*right++ = '\0';
for (i = 0; fields_array[i].name; i++) {
if (strcasecmp (left, fields_array[i].name) == 0) {
NmcOutputField *valid_names = fields_array[i].group;
idx = i;
if (!right && !valid_names) {
found = TRUE;
break;
}
for (j = 0; valid_names && valid_names[j].name; j++) {
if (!right || strcasecmp (right, valid_names[j].name) == 0) {
found = TRUE;
break;
}
}
if (found)
break;
}
}
if (found) {
/* Add index to array, and field name (or NULL) to group_fields array */
g_array_append_val (array, idx);
if (group_fields && *group_fields)
g_ptr_array_add (*group_fields, g_strdup (right));
}
if (right)
*(right-1) = '.'; /* Restore the original string */
} else {
/* e.g. "general,ip4,ip6" */
for (i = 0; fields_array[i].name; i++) {
if (strcasecmp (*iter, fields_array[i].name) == 0) {
g_array_append_val (array, i);
break;
}
}
}
/* Field was not found - error case */
if (fields_array[i].name == NULL) {
/* Set GError */
if (!strcasecmp (*iter, "all") || !strcasecmp (*iter, "common"))
g_set_error (error, NMCLI_ERROR, 0, _("field '%s' has to be alone"), *iter);
else {
char *allowed_fields = nmc_get_allowed_fields (fields_array, idx);
g_set_error (error, NMCLI_ERROR, 1, _("invalid field '%s'; allowed fields: %s"),
*iter, allowed_fields);
g_free (allowed_fields);
}
/* Free arrays on error */
g_array_free (array, TRUE);
array = NULL;
if (group_fields && *group_fields) {
g_ptr_array_free (*group_fields, TRUE);
*group_fields = NULL;
}
goto done;
}
}
done:
if (fields)
g_strfreev (fields);
return array;
}
int main(int argc, char * argv[]){
int i = 1;
const char * bigram_filename = NULL;
setlocale(LC_ALL, "");
while ( i < argc ){
if ( strcmp("--help", argv[i]) == 0 ){
print_help();
exit(0);
} else if ( strcmp("-k", argv[i]) == 0 ){
if ( ++i >= argc ){
print_help();
exit(EINVAL);
}
g_prune_k = atoi(argv[i]);
} else if ( strcmp("--CDF", argv[i]) == 0 ){
if ( ++i >= argc ){
print_help();
exit(EINVAL);
}
g_prune_poss = atof(argv[i]);
} else {
bigram_filename = argv[i];
}
++i;
}
/* TODO: magic header signature check here. */
KMixtureModelBigram bigram(K_MIXTURE_MODEL_MAGIC_NUMBER);
bigram.attach(bigram_filename, ATTACH_READWRITE);
KMixtureModelMagicHeader magic_header;
bigram.get_magic_header(magic_header);
GArray * items = g_array_new(FALSE, FALSE, sizeof(phrase_token_t));
bigram.get_all_items(items);
/* print prune progress */
size_t progress = 0; size_t onestep = items->len / 20;
for ( size_t i = 0; i < items->len; ++i ){
if ( progress >= onestep ) {
progress = 0; fprintf(stderr, "*");
}
progress ++;
phrase_token_t * token = &g_array_index(items, phrase_token_t, i);
KMixtureModelSingleGram * single_gram = NULL;
bigram.load(*token, single_gram);
FlexibleBigramPhraseArray removed_array = g_array_new(FALSE, FALSE, sizeof(KMixtureModelArrayItemWithToken));
prune_k_mixture_model(&magic_header, single_gram, removed_array);
bigram.store(*token, single_gram);
delete single_gram;
/* post processing for unigram reduce */
for (size_t m = 0; m < removed_array->len; ++m ){
KMixtureModelArrayItemWithToken * item =
&g_array_index(removed_array,
KMixtureModelArrayItemWithToken, m);
KMixtureModelArrayHeader array_header;
assert(bigram.get_array_header(item->m_token, array_header));
array_header.m_freq -= item->m_item.m_WC;
assert(array_header.m_freq >= 0);
assert(bigram.set_array_header(item->m_token, array_header));
}
g_array_free(removed_array, TRUE);
removed_array = NULL;
}
fprintf(stderr, "\n");
bigram.set_magic_header(magic_header);
/* post processing clean up zero items */
KMixtureModelArrayHeader array_header;
for ( size_t i = 0; i < items->len; ++i ){
phrase_token_t * token = &g_array_index(items, phrase_token_t, i);
assert(bigram.get_array_header(*token, array_header));
if ( 0 == array_header.m_WC && 0 == array_header.m_freq )
assert(bigram.remove(*token));
}
g_array_free(items, TRUE);
return 0;
}
static void
pygi_signal_closure_marshal(GClosure *closure,
GValue *return_value,
guint n_param_values,
const GValue *param_values,
gpointer invocation_hint,
gpointer marshal_data)
{
PyGILState_STATE state;
PyGClosure *pc = (PyGClosure *)closure;
PyObject *params, *ret = NULL;
guint i;
GISignalInfo *signal_info;
gint n_sig_info_args;
gint sig_info_highest_arg;
GSList *list_item = NULL;
GSList *pass_by_ref_structs = NULL;
state = PyGILState_Ensure();
signal_info = ((PyGISignalClosure *)closure)->signal_info;
n_sig_info_args = g_callable_info_get_n_args(signal_info);
/* the first argument to a signal callback is instance,
but instance is not counted in the introspection data */
sig_info_highest_arg = n_sig_info_args + 1;
g_assert_cmpint(sig_info_highest_arg, ==, n_param_values);
/* construct Python tuple for the parameter values */
params = PyTuple_New(n_param_values);
for (i = 0; i < n_param_values; i++) {
/* swap in a different initial data for connect_object() */
if (i == 0 && G_CCLOSURE_SWAP_DATA(closure)) {
g_return_if_fail(pc->swap_data != NULL);
Py_INCREF(pc->swap_data);
PyTuple_SetItem(params, 0, pc->swap_data);
} else if (i == 0) {
PyObject *item = pyg_value_as_pyobject(¶m_values[i], FALSE);
if (!item) {
goto out;
}
PyTuple_SetItem(params, i, item);
} else if (i < sig_info_highest_arg) {
GIArgInfo arg_info;
GITypeInfo type_info;
GITypeTag type_tag;
GIArgument arg = { 0, };
PyObject *item = NULL;
gboolean free_array = FALSE;
gboolean pass_struct_by_ref = FALSE;
g_callable_info_load_arg(signal_info, i - 1, &arg_info);
g_arg_info_load_type(&arg_info, &type_info);
arg = _pygi_argument_from_g_value(¶m_values[i], &type_info);
type_tag = g_type_info_get_tag (&type_info);
if (type_tag == GI_TYPE_TAG_ARRAY) {
/* Skip the self argument of param_values */
arg.v_pointer = _pygi_argument_to_array (&arg,
_pygi_argument_array_length_marshal,
(void *)(param_values + 1),
signal_info,
&type_info,
&free_array);
}
/* Hack to ensure struct arguments are passed-by-reference allowing
* callback implementors to modify the struct values. This is needed
* for keeping backwards compatibility and should be removed in future
* versions which support signal output arguments as return values.
* See: https://bugzilla.gnome.org/show_bug.cgi?id=735486
*
* Note the logic here must match the logic path taken in _pygi_argument_to_object.
*/
if (type_tag == GI_TYPE_TAG_INTERFACE) {
GIBaseInfo *info = g_type_info_get_interface (&type_info);
GIInfoType info_type = g_base_info_get_type (info);
if (info_type == GI_INFO_TYPE_STRUCT ||
info_type == GI_INFO_TYPE_BOXED ||
info_type == GI_INFO_TYPE_UNION) {
GType gtype = g_registered_type_info_get_g_type ((GIRegisteredTypeInfo *) info);
gboolean is_foreign = (info_type == GI_INFO_TYPE_STRUCT) &&
(g_struct_info_is_foreign ((GIStructInfo *) info));
if (!is_foreign && !g_type_is_a (gtype, G_TYPE_VALUE) &&
g_type_is_a (gtype, G_TYPE_BOXED)) {
pass_struct_by_ref = TRUE;
}
}
g_base_info_unref (info);
}
if (pass_struct_by_ref) {
/* transfer everything will ensure the struct is not copied when wrapped. */
item = _pygi_argument_to_object (&arg, &type_info, GI_TRANSFER_EVERYTHING);
if (item && PyObject_IsInstance (item, (PyObject *) &PyGIBoxed_Type)) {
((PyGBoxed *)item)->free_on_dealloc = FALSE;
pass_by_ref_structs = g_slist_prepend (pass_by_ref_structs, item);
}
} else {
item = _pygi_argument_to_object (&arg, &type_info, GI_TRANSFER_NOTHING);
}
if (free_array) {
g_array_free (arg.v_pointer, FALSE);
}
if (item == NULL) {
PyErr_Print ();
goto out;
}
PyTuple_SetItem(params, i, item);
}
}
/* params passed to function may have extra arguments */
if (pc->extra_args) {
PyObject *tuple = params;
params = PySequence_Concat(tuple, pc->extra_args);
Py_DECREF(tuple);
}
ret = PyObject_CallObject(pc->callback, params);
if (ret == NULL) {
if (pc->exception_handler)
pc->exception_handler(return_value, n_param_values, param_values);
else
PyErr_Print();
goto out;
}
if (G_IS_VALUE(return_value) && pyg_value_from_pyobject(return_value, ret) != 0) {
PyErr_SetString(PyExc_TypeError,
"can't convert return value to desired type");
if (pc->exception_handler)
pc->exception_handler(return_value, n_param_values, param_values);
else
PyErr_Print();
}
Py_DECREF(ret);
/* Run through the list of structs which have been passed by reference and
* check if they are being held longer than the duration of the callback
* execution. This is determined if the ref count is greater than 1.
* A single ref is held by the argument list and any more would mean the callback
* stored a ref somewhere else. In this case we make an internal copy of
* the boxed struct so Python can own the memory to it.
*/
list_item = pass_by_ref_structs;
while (list_item) {
PyObject *item = list_item->data;
if (item->ob_refcnt > 1) {
_pygi_boxed_copy_in_place ((PyGIBoxed *)item);
}
list_item = g_slist_next (list_item);
}
out:
g_slist_free (pass_by_ref_structs);
Py_DECREF(params);
PyGILState_Release(state);
}
static void
pgd_annots_add_annot (PgdAnnotsDemo *demo)
{
PopplerRectangle rect;
PopplerColor color;
PopplerAnnot *annot;
gdouble height;
g_assert (demo->mode == MODE_ADD);
poppler_page_get_size (demo->page, NULL, &height);
rect.x1 = demo->start.x;
rect.y1 = height - demo->start.y;
rect.x2 = demo->stop.x;
rect.y2 = height - demo->stop.y;
color.red = CLAMP ((guint) (demo->annot_color.red * 65535), 0, 65535);
color.green = CLAMP ((guint) (demo->annot_color.green * 65535), 0, 65535);
color.blue = CLAMP ((guint) (demo->annot_color.blue * 65535), 0, 65535);
switch (demo->annot_type) {
case POPPLER_ANNOT_TEXT:
annot = poppler_annot_text_new (demo->doc, &rect);
break;
case POPPLER_ANNOT_LINE: {
PopplerPoint start, end;
start.x = rect.x1;
start.y = rect.y1;
end.x = rect.x2;
end.y = rect.y2;
annot = poppler_annot_line_new (demo->doc, &rect, &start, &end);
}
break;
case POPPLER_ANNOT_SQUARE:
annot = poppler_annot_square_new (demo->doc, &rect);
break;
case POPPLER_ANNOT_CIRCLE:
annot = poppler_annot_circle_new (demo->doc, &rect);
break;
case POPPLER_ANNOT_HIGHLIGHT: {
GArray *quads_array;
quads_array = pgd_annots_create_quads_array_for_rectangle (&rect);
annot = poppler_annot_text_markup_new_highlight (demo->doc, &rect, quads_array);
g_array_free (quads_array, TRUE);
}
break;
case POPPLER_ANNOT_UNDERLINE: {
GArray *quads_array;
quads_array = pgd_annots_create_quads_array_for_rectangle (&rect);
annot = poppler_annot_text_markup_new_underline (demo->doc, &rect, quads_array);
g_array_free (quads_array, TRUE);
}
break;
case POPPLER_ANNOT_SQUIGGLY: {
GArray *quads_array;
quads_array = pgd_annots_create_quads_array_for_rectangle (&rect);
annot = poppler_annot_text_markup_new_squiggly (demo->doc, &rect, quads_array);
g_array_free (quads_array, TRUE);
}
break;
case POPPLER_ANNOT_STRIKE_OUT: {
GArray *quads_array;
quads_array = pgd_annots_create_quads_array_for_rectangle (&rect);
annot = poppler_annot_text_markup_new_strikeout (demo->doc, &rect, quads_array);
g_array_free (quads_array, TRUE);
}
break;
default:
g_assert_not_reached ();
}
demo->active_annot = annot;
poppler_annot_set_color (annot, &color);
poppler_page_add_annot (demo->page, annot);
pgd_annots_add_annot_to_model (demo, annot, rect, TRUE);
g_object_unref (annot);
}
/*
* make_logical_config:
*
* Turn outputs and CRTCs into logical MetaMonitorInfo,
* that will be used by the core and API layer (MetaScreen
* and friends)
*/
static void
make_logical_config (MetaMonitorManager *manager)
{
GArray *monitor_infos;
unsigned int i, j;
monitor_infos = g_array_sized_new (FALSE, TRUE, sizeof (MetaMonitorInfo),
manager->n_outputs);
/* Walk the list of MetaCRTCs, and build a MetaMonitorInfo
for each of them, unless they reference a rectangle that
is already there.
*/
for (i = 0; i < manager->n_crtcs; i++)
{
MetaCRTC *crtc = &manager->crtcs[i];
/* Ignore CRTCs not in use */
if (crtc->current_mode == NULL)
continue;
for (j = 0; j < monitor_infos->len; j++)
{
MetaMonitorInfo *info = &g_array_index (monitor_infos, MetaMonitorInfo, i);
if (meta_rectangle_equal (&crtc->rect,
&info->rect))
{
crtc->logical_monitor = info;
break;
}
}
if (crtc->logical_monitor == NULL)
{
MetaMonitorInfo info;
info.number = monitor_infos->len;
info.rect = crtc->rect;
info.is_primary = FALSE;
/* This starts true because we want
is_presentation only if all outputs are
marked as such (while for primary it's enough
that any is marked)
*/
info.is_presentation = TRUE;
info.in_fullscreen = -1;
info.output_id = 0;
g_array_append_val (monitor_infos, info);
crtc->logical_monitor = &g_array_index (monitor_infos, MetaMonitorInfo,
info.number);
}
}
/* Now walk the list of outputs applying extended properties (primary
and presentation)
*/
for (i = 0; i < manager->n_outputs; i++)
{
MetaOutput *output;
MetaMonitorInfo *info;
output = &manager->outputs[i];
/* Ignore outputs that are not active */
if (output->crtc == NULL)
continue;
/* We must have a logical monitor on every CRTC at this point */
g_assert (output->crtc->logical_monitor != NULL);
info = output->crtc->logical_monitor;
info->is_primary = info->is_primary || output->is_primary;
info->is_presentation = info->is_presentation && output->is_presentation;
if (output->is_primary || info->output_id == 0)
info->output_id = output->output_id;
if (info->is_primary)
manager->primary_monitor_index = info->number;
}
manager->n_monitor_infos = monitor_infos->len;
manager->monitor_infos = (void*)g_array_free (monitor_infos, FALSE);
}
// Store (key,value) pairs from a GHashTable in the kwallet.
// Every 'slot' has to take care of it's own data.
gboolean dt_pwstorage_kwallet_set(const backend_kwallet_context_t *context, const gchar* slot, GHashTable* table)
{
printf("slot %s\n", slot);
GArray* byte_array = g_array_new(FALSE, FALSE, sizeof(gchar));
GHashTableIter iter;
g_hash_table_iter_init (&iter, table);
gpointer key, value;
guint size = g_hash_table_size(table);
size = GINT_TO_BE(size);
g_array_append_vals(byte_array, &size, sizeof(guint)/sizeof(gchar));
while (g_hash_table_iter_next (&iter, &key, &value))
{
dt_print(DT_DEBUG_PWSTORAGE,"[pwstorage_kwallet_set] storing (%s, %s)\n",(gchar*)key, (gchar*)value);
gsize length;
gchar* new_key = char2qstring(key, &length);
if(new_key == NULL)
{
g_free(g_array_free(byte_array, FALSE));
return FALSE;
}
g_array_append_vals(byte_array, new_key, length);
g_free(new_key);
gchar* new_value = char2qstring(value, &length);
if(new_value == NULL)
{
g_free(g_array_free(byte_array, FALSE));
return FALSE;
}
g_array_append_vals(byte_array, new_value, length);
g_free(new_value);
}
int wallet_handle = get_wallet_handle(context);
GError* error = NULL;
/* signature:
*
* in i handle,
* in s folder,
* in s key,
* in ay value,
* in s appid,
*
* out i arg_0
*/
GVariant *ret = g_dbus_proxy_call_sync(context->proxy,
"writeMap",
g_variant_new("(iss@ays)", wallet_handle, kwallet_folder, slot,
g_variant_new_from_data(G_VARIANT_TYPE_BYTESTRING,
byte_array->data,
byte_array->len,
TRUE,
g_free,
byte_array->data),
app_id),
G_DBUS_CALL_FLAGS_NONE,
-1,
NULL,
&error);
g_array_free(byte_array, FALSE);
if(check_error(error))
{
g_variant_unref(ret);
return FALSE;
}
GVariant *child = g_variant_get_child_value(ret, 0);
int return_code = g_variant_get_int32(child);
g_variant_unref(child);
g_variant_unref(ret);
if (return_code != 0)
dt_print(DT_DEBUG_PWSTORAGE,"[pwstorage_kwallet_set] Warning: bad return code %d from kwallet\n", return_code);
return return_code == 0;
}
/* Print preorder traversal */
GArray * balanced_bst_preorder(Bst * tree, GArray * traversal) {
g_array_free(traversal, TRUE);
GArray * newtraversal = g_array_new(FALSE, FALSE, sizeof(int));
g_tree_traverse(tree, (GTraverseFunc)traverse_func, G_PRE_ORDER, newtraversal);
return newtraversal;
}
static void
handle_method_call_perform_writeback (TrackerController *controller,
GDBusMethodInvocation *invocation,
GVariant *parameters)
{
TrackerControllerPrivate *priv;
TrackerDBusRequest *request;
const gchar *subject;
GPtrArray *results = NULL;
GHashTableIter iter;
gpointer key, value;
GVariantIter *iter1, *iter2, *iter3;
GArray *rdf_types_array;
GStrv rdf_types;
gchar *rdf_type = NULL;
GList *writeback_handlers = NULL;
priv = controller->priv;
results = g_ptr_array_new_with_free_func ((GDestroyNotify) g_strfreev);
g_variant_get (parameters, "(&sasaas)", &subject, &iter1, &iter2);
rdf_types_array = g_array_new (TRUE, TRUE, sizeof (gchar *));
while (g_variant_iter_loop (iter1, "&s", &rdf_type)) {
g_array_append_val (rdf_types_array, rdf_type);
}
rdf_types = (GStrv) rdf_types_array->data;
g_array_free (rdf_types_array, FALSE);
while (g_variant_iter_loop (iter2, "as", &iter3)) {
GArray *row_array = g_array_new (TRUE, TRUE, sizeof (gchar *));
gchar *cell = NULL;
while (g_variant_iter_loop (iter3, "&s", &cell)) {
g_array_append_val (row_array, cell);
}
g_ptr_array_add (results, row_array->data);
g_array_free (row_array, FALSE);
}
g_variant_iter_free (iter1);
g_variant_iter_free (iter2);
reset_shutdown_timeout (controller);
request = tracker_dbus_request_begin (NULL, "%s (%s)", __FUNCTION__, subject);
g_hash_table_iter_init (&iter, priv->modules);
while (g_hash_table_iter_next (&iter, &key, &value)) {
TrackerWritebackModule *module;
const gchar * const *module_types;
module = value;
module_types = tracker_writeback_module_get_rdf_types (module);
if (sparql_rdf_types_match (module_types, (const gchar * const *) rdf_types)) {
TrackerWriteback *writeback;
g_message (" Updating metadata for subject:'%s' using module:'%s'",
subject,
module->name);
writeback = tracker_writeback_module_create (module);
writeback_handlers = g_list_prepend (writeback_handlers, writeback);
}
}
if (writeback_handlers != NULL) {
WritebackData *data;
GTask *task;
data = writeback_data_new (controller,
writeback_handlers,
priv->connection,
subject,
results,
invocation,
request);
task = g_task_new (controller, data->cancellable, NULL, NULL);
/* No need to free data here, it's done in the callback. */
g_task_set_task_data (task, data, NULL);
g_task_run_in_thread (task, io_writeback_job);
g_object_unref (task);
} else {
g_dbus_method_invocation_return_error (invocation,
TRACKER_DBUS_ERROR,
TRACKER_DBUS_ERROR_UNSUPPORTED,
"No module for rdf types");
}
g_free (rdf_types);
}
void
gimp_channel_select_vectors (GimpChannel *channel,
const gchar *undo_desc,
GimpVectors *vectors,
GimpChannelOps op,
gboolean antialias,
gboolean feather,
gdouble feather_radius_x,
gdouble feather_radius_y,
gboolean push_undo)
{
GimpScanConvert *scan_convert;
GList *stroke;
gboolean coords_added = FALSE;
g_return_if_fail (GIMP_IS_CHANNEL (channel));
g_return_if_fail (gimp_item_is_attached (GIMP_ITEM (channel)));
g_return_if_fail (undo_desc != NULL);
g_return_if_fail (GIMP_IS_VECTORS (vectors));
scan_convert = gimp_scan_convert_new ();
for (stroke = vectors->strokes; stroke; stroke = stroke->next)
{
GArray *coords;
gboolean closed;
coords = gimp_stroke_interpolate (GIMP_STROKE (stroke->data),
1.0, &closed);
if (coords && coords->len)
{
GimpVector2 *points;
gint i;
points = g_new0 (GimpVector2, coords->len);
for (i = 0; i < coords->len; i++)
{
points[i].x = g_array_index (coords, GimpCoords, i).x;
points[i].y = g_array_index (coords, GimpCoords, i).y;
}
gimp_scan_convert_add_polyline (scan_convert, coords->len,
points, TRUE);
coords_added = TRUE;
g_free (points);
}
if (coords)
g_array_free (coords, TRUE);
}
if (coords_added)
gimp_channel_select_scan_convert (channel, undo_desc, scan_convert, 0, 0,
op, antialias, feather,
feather_radius_x, feather_radius_y,
push_undo);
gimp_scan_convert_free (scan_convert);
}
void convert_tabfile(const char *filename, print_info_t print_info)
{
struct stat stats;
if (g_stat (filename, &stats) == -1)
{
print_info("File not exist!\n");
return;
}
gchar *basefilename = g_path_get_basename(filename);
gchar *ch = strrchr(basefilename, '.');
if (ch)
*ch = '\0';
gchar *dirname = g_path_get_dirname(filename);
FILE *tabfile;
tabfile = g_fopen(filename,"r");
gchar *buffer = (gchar *)g_malloc (stats.st_size + 1);
size_t readsize = fread (buffer, 1, stats.st_size, tabfile);
fclose (tabfile);
buffer[readsize] = '\0';
GArray *array = g_array_sized_new(FALSE,FALSE, sizeof(struct _worditem),20000);
gchar *p, *p1, *p2;
p = buffer;
if ((guchar)*p==0xEF && (guchar)*(p+1)==0xBB && (guchar)*(p+2)==0xBF) // UTF-8 order characters.
p+=3;
struct _worditem worditem;
glong linenum=1;
while (1) {
if (*p == '\0') {
print_info("Convert over.\n");
break;
}
p1 = strchr(p,'\n');
if (!p1) {
print_info("Error, no new line at the end\n");
return;
}
*p1 = '\0';
p1++;
p2 = strchr(p,'\t');
if (!p2) {
gchar *str = g_strdup_printf("Warning, no tab, %ld\n", linenum);
print_info(str);
g_free(str);
p= p1;
linenum++;
continue;
}
*p2 = '\0';
p2++;
worditem.word = p;
worditem.definition = p2;
my_strstrip(worditem.definition, linenum, print_info);
g_strstrip(worditem.word);
g_strstrip(worditem.definition);
if (!worditem.word[0]) {
gchar *str = g_strdup_printf("Warning: line %ld, bad word!\n", linenum);
print_info(str);
g_free(str);
p= p1;
linenum++;
continue;
}
if (!worditem.definition[0]) {
gchar *str = g_strdup_printf("Warning: line %ld, bad definition!\n", linenum);
print_info(str);
g_free(str);
p= p1;
linenum++;
continue;
}
g_array_append_val(array, worditem);
p= p1;
linenum++;
}
g_array_sort(array,comparefunc);
gchar ifofilename[256];
gchar idxfilename[256];
gchar dicfilename[256];
sprintf(ifofilename, "%s" G_DIR_SEPARATOR_S "%s.ifo", dirname, basefilename);
sprintf(idxfilename, "%s" G_DIR_SEPARATOR_S "%s.idx", dirname, basefilename);
sprintf(dicfilename, "%s" G_DIR_SEPARATOR_S "%s.dict", dirname, basefilename);
FILE *ifofile = g_fopen(ifofilename,"wb");
if (!ifofile) {
print_info("Write to ifo file failed!\n");
return;
}
FILE *idxfile = g_fopen(idxfilename,"wb");
if (!idxfile) {
print_info("Write to idx file failed!\n");
return;
}
FILE *dicfile = g_fopen(dicfilename,"wb");
if (!dicfile) {
print_info("Write to dict file failed!\n");
return;
}
guint32 offset_old;
guint32 tmpglong;
struct _worditem *pworditem;
gint definition_len;
gulong i;
for (i=0; i< array->len; i++) {
offset_old = ftell(dicfile);
pworditem = &g_array_index(array, struct _worditem, i);
definition_len = strlen(pworditem->definition);
fwrite(pworditem->definition, 1 ,definition_len,dicfile);
fwrite(pworditem->word,sizeof(gchar),strlen(pworditem->word)+1,idxfile);
tmpglong = g_htonl(offset_old);
fwrite(&(tmpglong),sizeof(guint32),1,idxfile);
tmpglong = g_htonl(definition_len);
fwrite(&(tmpglong),sizeof(guint32),1,idxfile);
}
fclose(idxfile);
fclose(dicfile);
gchar *str = g_strdup_printf("%s wordcount: %d\n", basefilename, array->len);
print_info(str);
g_free(str);
#ifndef _WIN32
gchar command[256];
sprintf(command, "dictzip %s", dicfilename);
system(command);
#endif
g_stat(idxfilename, &stats);
fprintf(ifofile, "StarDict's dict ifo file\nversion=2.4.2\nwordcount=%d\nidxfilesize=%ld\nbookname=%s\nsametypesequence=m\n", array->len, stats.st_size, basefilename);
fclose(ifofile);
g_free(buffer);
g_array_free(array,TRUE);
g_free(basefilename);
g_free(dirname);
}
static void
handle_nonlocal_move (NemoIconContainer *container,
GdkDragAction action,
int x, int y,
const char *target_uri,
gboolean icon_hit)
{
GList *source_uris, *p;
GArray *source_item_locations;
gboolean free_target_uri, is_rtl;
int index, item_x;
GtkAllocation allocation;
if (container->details->dnd_info->drag_info.selection_list == NULL) {
return;
}
source_uris = NULL;
for (p = container->details->dnd_info->drag_info.selection_list; p != NULL; p = p->next) {
/* do a shallow copy of all the uri strings of the copied files */
source_uris = g_list_prepend (source_uris, ((NemoDragSelectionItem *)p->data)->uri);
}
source_uris = g_list_reverse (source_uris);
is_rtl = nemo_icon_container_is_layout_rtl (container);
source_item_locations = g_array_new (FALSE, TRUE, sizeof (GdkPoint));
if (!icon_hit) {
/* Drop onto a container. Pass along the item points to allow placing
* the items in their same relative positions in the new container.
*/
source_item_locations = g_array_set_size (source_item_locations,
g_list_length (container->details->dnd_info->drag_info.selection_list));
for (index = 0, p = container->details->dnd_info->drag_info.selection_list;
p != NULL; index++, p = p->next) {
item_x = ((NemoDragSelectionItem *)p->data)->icon_x;
if (is_rtl)
item_x = -item_x - ((NemoDragSelectionItem *)p->data)->icon_width;
g_array_index (source_item_locations, GdkPoint, index).x = item_x;
g_array_index (source_item_locations, GdkPoint, index).y =
((NemoDragSelectionItem *)p->data)->icon_y;
}
}
free_target_uri = FALSE;
/* Rewrite internal desktop URIs to the normal target uri */
if (eel_uri_is_desktop (target_uri)) {
target_uri = nemo_get_desktop_directory_uri ();
free_target_uri = TRUE;
}
if (is_rtl) {
gtk_widget_get_allocation (GTK_WIDGET (container), &allocation);
x = CANVAS_WIDTH (container, allocation) - x;
}
/* start the copy */
g_signal_emit_by_name (container, "move_copy_items",
source_uris,
source_item_locations,
target_uri,
action,
x, y);
if (free_target_uri) {
g_free ((char *)target_uri);
}
g_list_free (source_uris);
g_array_free (source_item_locations, TRUE);
}
static void
free_string_array (GArray *array)
{
gchar** lines = (gchar**)g_array_free (array, FALSE);
g_strfreev (lines);
}
static JSBool
setDash_func(JSContext *context,
unsigned argc,
jsval *vp)
{
JS::CallArgs argv = JS::CallArgsFromVp (argc, vp);
JSObject *obj = JSVAL_TO_OBJECT(argv.thisv());
guint i;
cairo_t *cr;
JSObject *dashes;
double offset;
JSBool retval = JS_FALSE;
guint len;
GArray *dashes_c = NULL;
if (!gjs_parse_call_args(context, "setDash", "of", argv,
"dashes", &dashes, "offset", &offset))
return JS_FALSE;
JS_AddObjectRoot(context, &dashes);
if (!JS_IsArrayObject(context, dashes)) {
gjs_throw(context, "dashes must be an array");
goto out;
}
if (!JS_GetArrayLength(context, dashes, &len)) {
gjs_throw(context, "Can't get length of dashes");
goto out;
}
dashes_c = g_array_sized_new (FALSE, FALSE, sizeof(double), len);
for (i = 0; i < len; ++i) {
jsval elem;
double b;
elem = JSVAL_VOID;
if (!JS_GetElement(context, dashes, i, &elem)) {
goto out;
}
if (JSVAL_IS_VOID(elem))
continue;
if (!JS_ValueToNumber(context, elem, &b))
goto out;
if (b <= 0) {
gjs_throw(context, "Dash value must be positive");
goto out;
}
g_array_append_val(dashes_c, b);
}
cr = gjs_cairo_context_get_context(context, obj);
cairo_set_dash(cr, (double*)dashes_c->data, dashes_c->len, offset);
argv.rval().set(JSVAL_VOID);
retval = JS_TRUE;
out:
if (dashes_c != NULL)
g_array_free (dashes_c, TRUE);
JS_RemoveObjectRoot(context, &dashes);
return retval;
}
static CK_RV
wrap_C_Initialize (CK_VOID_PTR init_args)
{
CK_FUNCTION_LIST_PTR funcs;
GArray *mappings = NULL;
CK_SLOT_ID_PTR slots;
Mapping mapping;
CK_ULONG i, count;
CK_RV rv = CKR_OK;
GList *l;
mappings = g_array_new (FALSE, TRUE, sizeof (Mapping));
G_LOCK (wrap_layer);
if (wrap_mappings)
rv = CKR_CRYPTOKI_ALREADY_INITIALIZED;
for (l = wrap_modules; rv == CKR_OK && l != NULL; l = g_list_next (l)) {
funcs = l->data;
/* Initialize each module */
rv = (funcs->C_Initialize) (init_args);
if (rv == CKR_CRYPTOKI_ALREADY_INITIALIZED)
rv = CKR_OK;
if (rv != CKR_OK)
break;
/* And then ask it for its slots */
rv = (funcs->C_GetSlotList) (FALSE, NULL, &count);
if (rv != CKR_OK)
break;
if (!count)
continue;
slots = g_new0 (CK_SLOT_ID, count);
rv = (funcs->C_GetSlotList) (FALSE, slots, &count);
if (rv != CKR_OK) {
g_free (slots);
break;
}
/* And now add a mapping for each of those slots */
for (i = 0; i < count; ++i) {
memset (&mapping, 0, sizeof (mapping));
mapping.wrap_slot = mappings->len + PLEX_MAPPING_OFFSET;
mapping.real_slot = slots[i];
mapping.funcs = funcs;
g_array_append_val (mappings, mapping);
}
g_free (slots);
}
/* If failed, then finalize all the ones that succeeded */
if (rv != CKR_OK && l != NULL) {
for (l = g_list_previous (l); l; l = g_list_previous (l)) {
funcs = l->data;
(funcs->C_Finalize) (NULL);
}
}
/* If succeeded then swap in mappings */
if (rv == CKR_OK) {
g_assert (!wrap_mappings);
n_wrap_mappings = mappings->len;
wrap_mappings = (Mapping*)g_array_free (mappings, FALSE);
mappings = NULL;
wrap_sessions = g_hash_table_new_full (g_direct_hash, g_direct_equal, NULL, g_free);
}
G_UNLOCK (wrap_layer);
/* If failed or somehow unused then free */
if (mappings)
g_array_free (mappings, TRUE);
return rv;
}
static void
pgd_annots_update_selected_text (PgdAnnotsDemo *demo)
{
PopplerRectangle doc_area, *rects = NULL, *r = NULL;
gdouble width, height;
GArray *quads_array = NULL;
guint n_rects;
gint i, lines = 0;
GList *l_rects = NULL, *list;
poppler_page_get_size (demo->page, &width, &height);
doc_area.x1 = demo->start.x;
doc_area.y1 = demo->start.y;
doc_area.x2 = demo->stop.x;
doc_area.y2 = demo->stop.y;
if (! poppler_page_get_text_layout_for_area (demo->page, &doc_area,
&rects, &n_rects))
return;
r = g_slice_new (PopplerRectangle);
r->x1 = G_MAXDOUBLE; r->y1 = G_MAXDOUBLE;
r->x2 = G_MINDOUBLE; r->y2 = G_MINDOUBLE;
for (i = 0; i < n_rects; i++) {
/* Check if the rectangle belongs to the same line.
On a new line, start a new target rectangle.
On the same line, make an union of rectangles at
the same line */
if (ABS(r->y2 - rects[i].y2) > 0.0001) {
if (i > 0)
l_rects = g_list_append (l_rects, r);
r = g_slice_new (PopplerRectangle);
r->x1 = rects[i].x1;
r->y1 = rects[i].y1;
r->x2 = rects[i].x2;
r->y2 = rects[i].y2;
lines++;
} else {
r->x1 = MIN(r->x1, rects[i].x1);
r->y1 = MIN(r->y1, rects[i].y1);
r->x2 = MAX(r->x2, rects[i].x2);
r->y2 = MAX(r->y2, rects[i].y2);
}
}
l_rects = g_list_append (l_rects, r);
l_rects = g_list_reverse (l_rects);
quads_array = g_array_sized_new (TRUE, TRUE,
sizeof (PopplerQuadrilateral),
lines);
g_array_set_size (quads_array, lines);
for (list = l_rects, i = 0; list; list = list->next, i++) {
PopplerQuadrilateral *quad;
quad = &g_array_index (quads_array, PopplerQuadrilateral, i);
r = (PopplerRectangle *)list->data;
quad->p1.x = r->x1;
quad->p1.y = height - r->y1;
quad->p2.x = r->x2;
quad->p2.y = height - r->y1;
quad->p3.x = r->x1;
quad->p3.y = height - r->y2;
quad->p4.x = r->x2;
quad->p4.y = height - r->y2;
g_slice_free (PopplerRectangle, r);
}
poppler_annot_text_markup_set_quadrilaterals (POPPLER_ANNOT_TEXT_MARKUP (demo->active_annot), quads_array);
g_array_free (quads_array, TRUE);
g_free (rects);
g_list_free (l_rects);
}
void g_byte_array_free (GByteArray *array,
gboolean free_segment)
{
g_array_free ((GArray*) array, free_segment);
}
/*
* Order the windows on the X server to be the same as in our structure.
* We do this using XRestackWindows if we don't know the previous order,
* or XConfigureWindow on a few particular windows if we do and can figure
* out the minimum set of changes. After that, we set __NET_CLIENT_LIST
* and __NET_CLIENT_LIST_STACKING.
*
* FIXME: Now that we have a good view of the stacking order on the server
* with MetaStackTracker it should be possible to do a simpler and better
* job of computing the minimal set of stacking requests needed.
*/
static void
stack_sync_to_server (MetaStack *stack)
{
GArray *stacked;
GArray *root_children_stacked;
GList *tmp;
GArray *all_hidden;
int n_override_redirect = 0;
int n_unmanaging = 0;
/* Bail out if frozen */
if (stack->freeze_count > 0)
return;
meta_topic (META_DEBUG_STACK, "Syncing window stack to server\n");
stack_ensure_sorted (stack);
/* Create stacked xwindow arrays.
* Painfully, "stacked" is in bottom-to-top order for the
* _NET hints, and "root_children_stacked" is in top-to-bottom
* order for XRestackWindows()
*/
stacked = g_array_new (FALSE, FALSE, sizeof (Window));
root_children_stacked = g_array_new (FALSE, FALSE, sizeof (Window));
all_hidden = g_array_new (FALSE, FALSE, sizeof (Window));
/* The screen guard window sits above all hidden windows and acts as
* a barrier to input reaching these windows. */
g_array_append_val (all_hidden, stack->screen->guard_window);
meta_topic (META_DEBUG_STACK, "Top to bottom: ");
meta_push_no_msg_prefix ();
for (tmp = stack->sorted; tmp != NULL; tmp = tmp->next)
{
MetaWindow *w = tmp->data;
Window top_level_window;
if (w->unmanaging)
{
n_unmanaging ++;
continue;
}
meta_topic (META_DEBUG_STACK, "%u:%d - %s ",
w->layer, w->stack_position, w->desc);
/* remember, stacked is in reverse order (bottom to top) */
if (w->override_redirect)
n_override_redirect++;
else
g_array_prepend_val (stacked, w->xwindow);
if (w->frame)
top_level_window = w->frame->xwindow;
else
top_level_window = w->xwindow;
/* We don't restack hidden windows along with the rest, though they are
* reflected in the _NET hints. Hidden windows all get pushed below
* the screens fullscreen guard_window. */
if (w->hidden)
{
g_array_append_val (all_hidden, top_level_window);
continue;
}
/* build XRestackWindows() array from top to bottom */
g_array_append_val (root_children_stacked, top_level_window);
}
meta_topic (META_DEBUG_STACK, "\n");
meta_pop_no_msg_prefix ();
/* All windows should be in some stacking order */
if (stacked->len != stack->windows->len - n_override_redirect - n_unmanaging)
meta_bug ("%u windows stacked, %u windows exist in stack\n",
stacked->len, stack->windows->len);
/* Sync to server */
meta_topic (META_DEBUG_STACK, "Restacking %u windows\n",
root_children_stacked->len);
meta_error_trap_push (stack->screen->display);
if (stack->last_root_children_stacked == NULL)
{
/* Just impose our stack, we don't know the previous state.
* This involves a ton of circulate requests and may flicker.
*/
meta_topic (META_DEBUG_STACK, "Don't know last stack state, restacking everything\n");
if (root_children_stacked->len > 0)
{
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
(Window *) root_children_stacked->data,
root_children_stacked->len,
XNextRequest (stack->screen->display->xdisplay));
XRestackWindows (stack->screen->display->xdisplay,
(Window *) root_children_stacked->data,
root_children_stacked->len);
}
}
else if (root_children_stacked->len > 0)
{
/* Try to do minimal window moves to get the stack in order */
/* A point of note: these arrays include frames not client windows,
* so if a client window has changed frame since last_root_children_stacked
* was saved, then we may have inefficiency, but I don't think things
* break...
*/
const Window *old_stack = (Window *) stack->last_root_children_stacked->data;
const Window *new_stack = (Window *) root_children_stacked->data;
const int old_len = stack->last_root_children_stacked->len;
const int new_len = root_children_stacked->len;
const Window *oldp = old_stack;
const Window *newp = new_stack;
const Window *old_end = old_stack + old_len;
const Window *new_end = new_stack + new_len;
Window last_window = None;
while (oldp != old_end &&
newp != new_end)
{
if (*oldp == *newp)
{
/* Stacks are the same here, move on */
++oldp;
last_window = *newp;
++newp;
}
else if (meta_display_lookup_x_window (stack->screen->display,
*oldp) == NULL)
{
/* *oldp is no longer known to us (probably destroyed),
* so we can just skip it
*/
++oldp;
}
else
{
/* Move *newp below last_window */
if (last_window == None)
{
meta_topic (META_DEBUG_STACK, "Using window 0x%lx as topmost (but leaving it in-place)\n", *newp);
raise_window_relative_to_managed_windows (stack->screen,
*newp);
}
else
{
/* This means that if last_window is dead, but not
* *newp, then we fail to restack *newp; but on
* unmanaging last_window, we'll fix it up.
*/
XWindowChanges changes;
changes.sibling = last_window;
changes.stack_mode = Below;
meta_topic (META_DEBUG_STACK, "Placing window 0x%lx below 0x%lx\n",
*newp, last_window);
meta_stack_tracker_record_lower_below (stack->screen->stack_tracker,
*newp, last_window,
XNextRequest (stack->screen->display->xdisplay));
XConfigureWindow (stack->screen->display->xdisplay,
*newp,
CWSibling | CWStackMode,
&changes);
}
last_window = *newp;
++newp;
}
}
if (newp != new_end)
{
/* Restack remaining windows */
meta_topic (META_DEBUG_STACK, "Restacking remaining %d windows\n",
(int) (new_end - newp));
/* We need to include an already-stacked window
* in the restack call, so we get in the proper position
* with respect to it.
*/
if (newp != new_stack)
--newp;
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
(Window *) newp, new_end - newp,
XNextRequest (stack->screen->display->xdisplay));
XRestackWindows (stack->screen->display->xdisplay,
(Window *) newp, new_end - newp);
}
}
/* Push hidden windows to the bottom of the stack under the guard window */
meta_stack_tracker_record_lower (stack->screen->stack_tracker,
stack->screen->guard_window,
XNextRequest (stack->screen->display->xdisplay));
XLowerWindow (stack->screen->display->xdisplay, stack->screen->guard_window);
meta_stack_tracker_record_restack_windows (stack->screen->stack_tracker,
(Window *)all_hidden->data,
all_hidden->len,
XNextRequest (stack->screen->display->xdisplay));
XRestackWindows (stack->screen->display->xdisplay,
(Window *)all_hidden->data,
all_hidden->len);
g_array_free (all_hidden, TRUE);
meta_error_trap_pop (stack->screen->display);
/* on error, a window was destroyed; it should eventually
* get removed from the stacking list when we unmanage it
* and we'll fix stacking at that time.
*/
/* Sync _NET_CLIENT_LIST and _NET_CLIENT_LIST_STACKING */
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST,
XA_WINDOW,
32, PropModeReplace,
(unsigned char *)stack->windows->data,
stack->windows->len);
XChangeProperty (stack->screen->display->xdisplay,
stack->screen->xroot,
stack->screen->display->atom__NET_CLIENT_LIST_STACKING,
XA_WINDOW,
32, PropModeReplace,
(unsigned char *)stacked->data,
stacked->len);
g_array_free (stacked, TRUE);
if (stack->last_root_children_stacked)
g_array_free (stack->last_root_children_stacked, TRUE);
stack->last_root_children_stacked = root_children_stacked;
/* That was scary... */
}
/* Free linker wrapper and return the linker array. */
void *bios_linker_loader_cleanup(GArray *linker)
{
return g_array_free(linker, false);
}
void
_pygi_marshal_cleanup_from_py_array (PyGIInvokeState *state,
PyGIArgCache *arg_cache,
PyObject *py_arg,
gpointer data,
gboolean was_processed)
{
if (was_processed) {
GArray *array_ = NULL;
GPtrArray *ptr_array_ = NULL;
PyGISequenceCache *sequence_cache = (PyGISequenceCache *)arg_cache;
if (sequence_cache->array_type == GI_ARRAY_TYPE_PTR_ARRAY) {
ptr_array_ = (GPtrArray *) data;
} else {
array_ = (GArray *) data;
}
/* clean up items first */
if (sequence_cache->item_cache->from_py_cleanup != NULL) {
gsize i;
guint len = (array_ != NULL) ? array_->len : ptr_array_->len;
PyGIMarshalCleanupFunc cleanup_func =
sequence_cache->item_cache->from_py_cleanup;
for (i = 0; i < len; i++) {
gpointer item;
PyObject *py_item = NULL;
/* case 1: GPtrArray */
if (ptr_array_ != NULL)
item = g_ptr_array_index (ptr_array_, i);
/* case 2: C array or GArray with object pointers */
else if (sequence_cache->item_cache->is_pointer)
item = g_array_index (array_, gpointer, i);
/* case 3: C array or GArray with simple types or structs */
else {
item = array_->data + i * sequence_cache->item_size;
/* special-case hack: GValue array items do not get slice
* allocated in _pygi_marshal_from_py_array(), so we must
* not try to deallocate it as a slice and thus
* short-circuit cleanup_func. */
if (cleanup_func == _pygi_marshal_cleanup_from_py_interface_struct_gvalue) {
g_value_unset ((GValue*) item);
continue;
}
}
py_item = PySequence_GetItem (py_arg, i);
cleanup_func (state, sequence_cache->item_cache, py_item, item, TRUE);
Py_XDECREF (py_item);
}
}
/* Only free the array when we didn't transfer ownership */
if (sequence_cache->array_type == GI_ARRAY_TYPE_C) {
/* always free the GArray wrapper created in from_py marshaling and
* passed back as cleanup_data
*/
g_array_free (array_, arg_cache->transfer == GI_TRANSFER_NOTHING);
} else {
if (array_ != NULL)
g_array_unref (array_);
else
g_ptr_array_unref (ptr_array_);
}
}
}
/*
* recurse == 1: don't expand '@(command)@'
* recurse == 2: don't expand '@<java script>@'
*/
gchar*
expand(const char* s, guint recurse) {
enum exp_type etype;
char* end_simple_var = "\t^°!\"§$%&/()=?'`'+~*'#-:,;@<>| \\{}[]¹²³¼½";
char* ret = NULL;
char* vend = NULL;
GError* err = NULL;
gchar* cmd_stdout = NULL;
gchar* mycmd = NULL;
GString* buf = g_string_new("");
GString* js_ret = g_string_new("");
while (s && *s) {
switch(*s) {
case '\\':
g_string_append_c(buf, *++s);
s++;
break;
case '@':
etype = get_exp_type(s);
s++;
switch(etype) {
case EXP_SIMPLE_VAR:
vend = strpbrk(s, end_simple_var);
if(!vend) vend = strchr(s, '\0');
break;
case EXP_BRACED_VAR:
s++;
vend = strchr(s, '}');
if(!vend) vend = strchr(s, '\0');
break;
case EXP_EXPR:
s++;
vend = strstr(s, ")@");
if(!vend) vend = strchr(s, '\0');
break;
case EXP_JS:
s++;
vend = strstr(s, ">@");
if(!vend) vend = strchr(s, '\0');
break;
case EXP_ESCAPE:
s++;
vend = strstr(s, "]@");
if(!vend) vend = strchr(s, '\0');
break;
/*@notreached@*/
case EXP_ERR:
break;
}
assert(vend);
ret = g_strndup(s, vend-s);
if(etype == EXP_SIMPLE_VAR ||
etype == EXP_BRACED_VAR) {
expand_variable(buf, ret);
if(etype == EXP_SIMPLE_VAR)
s = vend;
else
s = vend+1;
}
else if(recurse != 1 &&
etype == EXP_EXPR) {
/* execute program directly */
if(ret[0] == '+') {
mycmd = expand(ret+1, 1);
g_spawn_command_line_sync(mycmd, &cmd_stdout, NULL, NULL, &err);
g_free(mycmd);
}
/* execute program through shell, quote it first */
else {
mycmd = expand(ret, 1);
gchar *quoted = g_shell_quote(mycmd);
gchar *tmp = g_strdup_printf("%s %s",
uzbl.behave.shell_cmd?uzbl.behave.shell_cmd:"/bin/sh -c",
quoted);
g_spawn_command_line_sync(tmp, &cmd_stdout, NULL, NULL, &err);
g_free(mycmd);
g_free(quoted);
g_free(tmp);
}
if (err) {
g_printerr("error on running command: %s\n", err->message);
g_error_free (err);
}
else if (*cmd_stdout) {
size_t len = strlen(cmd_stdout);
if(len > 0 && cmd_stdout[len-1] == '\n')
cmd_stdout[--len] = '\0'; /* strip trailing newline */
g_string_append(buf, cmd_stdout);
g_free(cmd_stdout);
}
s = vend+2;
}
else if(recurse != 2 &&
etype == EXP_JS) {
/* read JS from file */
if(ret[0] == '+') {
GArray *tmp = g_array_new(TRUE, FALSE, sizeof(gchar *));
mycmd = expand(ret+1, 2);
g_array_append_val(tmp, mycmd);
run_external_js(uzbl.gui.web_view, tmp, js_ret);
g_array_free(tmp, TRUE);
}
/* JS from string */
else {
mycmd = expand(ret, 2);
eval_js(uzbl.gui.web_view, mycmd, js_ret, "(command)");
g_free(mycmd);
}
if(js_ret->str) {
g_string_append(buf, js_ret->str);
g_string_free(js_ret, TRUE);
js_ret = g_string_new("");
}
s = vend+2;
}
else if(etype == EXP_ESCAPE) {
mycmd = expand(ret, 0);
char *escaped = g_markup_escape_text(mycmd, strlen(mycmd));
g_string_append(buf, escaped);
g_free(escaped);
g_free(mycmd);
s = vend+2;
}
g_free(ret);
ret = NULL;
break;
default:
g_string_append_c(buf, *s);
s++;
break;
}
}
g_string_free(js_ret, TRUE);
return g_string_free(buf, FALSE);
}
gint reaxmd_parse_properties(FILE *fp, struct model_pak *model, gpointer import)
{
gint i, j, k, n=1, time_column=0, num_tokens, num_properties;
gdouble frame_time=0.0, time, start, stop, value;
gchar *line, *label, **buff;
const gchar *xlabel, *ylabel;
GSList *item, *list;
GArray **property_array;
#if DEBUG_REAXMD_PARSE_PROPERTIES
printf("file_reaxmd(): parsing energy file...\n");
#endif
/* checks */
if (!fp)
return(FALSE);
if (!import)
return(FALSE);
/* setup internal frame counter */
if (model)
{
n = g_list_length(model->animate_list);
i=0;
frame_time = str_to_float(animate_frame_property_get(i, "Time", model));
}
// NB: file_read_line() skips comments by default, so it'll auto skip the header line
file_skip_comment(FALSE);
// process first line for column locations of time, energy, etc ...
line = file_read_line(fp);
// error handling
if (!line)
{
return(FALSE);
}
if (strlen(line) < 2)
{
return(FALSE);
}
buff = g_strsplit(&line[1], "|", -1);
list = NULL;
if (buff)
{
j=0;
while (buff[j])
{
label = g_strstrip(buff[j]);
if (strlen(label))
{
if (g_strrstr(label, "Time"))
{
time_column = j;
}
list = g_slist_prepend(list, g_strdup(label));
}
j++;
}
}
g_strfreev(buff);
g_free(line);
line = file_read_line(fp);
list = g_slist_reverse(list);
#if DEBUG_REAXMD_PARSE_PROPERTIES
for (item=list ; item ; item=g_slist_next(item))
{
printf("[%s]\n", (gchar *) item->data);
}
printf("Allocating %d property arrays, with start size %d\n", g_slist_length(list), n);
#endif
// NB: exclude the first - time
/* init arrays for properties */
num_properties = g_slist_length(list);
property_array = g_malloc(num_properties * sizeof(GArray));
for (k=0 ; k<num_properties ; k++)
{
property_array[k] = g_array_sized_new(FALSE, FALSE, sizeof(gdouble), n);
}
/* iterate over all output data lines */
while (line)
{
buff = tokenize(line, &num_tokens);
if (num_tokens > time_column)
{
time = str_to_float(buff[time_column]);
/* NEW - grab all values for property graphs */
for (j=0 ; j<num_tokens ; j++)
{
if (j < num_properties)
{
value = str_to_float(buff[j]);
g_array_append_val(property_array[j], value);
}
}
/* if output data time matches internal frame frame - store */
if (model)
{
if (time >= frame_time)
{
/* add current output data to the internally stored frame */
item = list;
for (j=0 ; j<num_tokens ; j++)
{
if (item)
{
//printf("[%d][%s][%s]\n", i, (gchar *) item->data, buff[j]);
// add to actual model property list (reference frame only)
// leave this out now, since we're auto constructing graphs anyway
/*
if (!i)
{
property_add_ranked(j, item->data, buff[j], model);
}
*/
animate_frame_property_put(i, item->data, buff[j], model);
}
else
break;
item = g_slist_next(item);
}
/* update the internal frame count */
i++;
frame_time = str_to_float(animate_frame_property_get(i, "Time", model));
}
}
}
g_strfreev(buff);
g_free(line);
line = file_read_line(fp);
}
/* iterate property arrays and construct graphs */
xlabel = g_slist_nth_data(list, time_column);
for (j=0 ; j<num_properties ; j++)
{
// don't graph time column
if (j != time_column)
{
gpointer data, graph;
k = property_array[j]->len;
data = g_array_free(property_array[j], FALSE);
start = g_array_index(property_array[time_column],gdouble,0);
stop = g_array_index(property_array[time_column],gdouble,k-1);
#if DEBUG_REAXMD_PARSE_PROPERTIES
printf("Building graph for: %s with %d data points and ", (gchar *) g_slist_nth_data(list, j), k);
printf("range: %f - %f\n", start, stop);
#endif
/* add graph if no ! prefix */
ylabel = g_slist_nth_data(list, j);
if (!g_strrstr(ylabel, "!"))
{
/* create and attach graph object */
label = g_strndup(ylabel, 8);
graph = graph_new(label);
g_free(label);
graph_set_data(k, data, start, stop, graph);
graph_x_label_set(xlabel, graph);
graph_y_label_set(ylabel, graph);
import_object_add(IMPORT_GRAPH, graph, import);
}
}
}
g_array_free(property_array[time_column], TRUE);
g_free(property_array);
/* cleanup */
free_slist(list);
return(0);
}
static int do_tree_check(struct print_manager *pm)
{
//printf("Checking abs_off tree\n");
pm->lookup_offset = pm->current_offset;
g_tree_foreach(pm->abs_tree, (GTraverseFunc) abs_tree_check, pm);
if (pm->destroy_array != NULL)
{
for (int i = 0; i < pm->destroy_array->len; i++)
{
long long off = g_array_index(pm->destroy_array, long long, i);
GNode *node = (GNode *) g_tree_lookup(pm->abs_tree, &off);
save_children(pm, node);
g_tree_remove(pm->abs_tree, &off);
}
g_array_free(pm->destroy_array, TRUE);
pm->destroy_array = NULL;
}
if (pm->print_array != NULL)
{
for (int i = 0; i < pm->print_array->len; i++)
{
long long off = g_array_index(pm->print_array, long long, i);
GNode *node = (GNode *) g_tree_lookup(pm->abs_tree, &off);
print_and_process_tree(pm, node);
g_tree_remove(pm->abs_tree, &off);
}
g_array_free(pm->print_array, TRUE);
pm->print_array = NULL;
}
//printf("Checking continuation tree\n");
g_tree_foreach(pm->continuation_tree, (GTraverseFunc) continuation_tree_check, pm);
if (pm->destroy_array != NULL)
{
for (int i = 0; i < pm->destroy_array->len; i++)
{
block_range_t br = g_array_index(pm->destroy_array, block_range_t, i);
gboolean ret = g_tree_remove(pm->continuation_tree, br);
prong_assert(ret == TRUE);
block_range_close(br);
}
g_array_free(pm->destroy_array, TRUE);
pm->destroy_array = NULL;
}
if (pm->print_array != NULL)
{
for (int i = 0; i < pm->print_array->len; i++)
{
block_range_t br = g_array_index(pm->print_array, block_range_t, i);
struct continuation_node *node = (struct continuation_node *) g_tree_lookup(pm->continuation_tree, br);
prong_assert(node != NULL);
if (node->is_constant == 1)
{
pm->print_handler->print_const_continuation((unsigned long long) pm->current_offset * pm->block_size, (unsigned long long) node->owner_offset * pm->block_size, node->path);
//printf("%13lld %13lld Constant\n", pm->current_offset * pm->block_size, node->owner_offset * pm->block_size);
} else
{
pm->print_handler->print_continuation((unsigned long long) pm->current_offset * pm->block_size, (unsigned long long) node->owner_offset * pm->block_size, node->brief_description);
//printf("%13lld %13lld (Continuation of %s)\n", pm->current_offset * pm->block_size, node->owner_offset * pm->block_size, node->brief_description);
}
//printf("Incremented current offset\n");
pm->current_offset++;
block_range_close(br);
}
g_array_free(pm->print_array, TRUE);
pm->print_array = NULL;
return 1;
}
return 0;
}
static gboolean
process_nduseropt_rdnss (NMIP6Device *device, struct nd_opt_hdr *opt)
{
size_t opt_len;
struct nd_opt_rdnss *rdnss_opt;
time_t now = time (NULL);
struct in6_addr *addr;
GArray *new_servers;
NMIP6RDNSS server, *cur_server;
gboolean changed = FALSE;
guint i;
opt_len = opt->nd_opt_len;
if (opt_len < 3 || (opt_len & 1) == 0)
return FALSE;
rdnss_opt = (struct nd_opt_rdnss *) opt;
new_servers = g_array_new (FALSE, FALSE, sizeof (NMIP6RDNSS));
/* Pad the DNS server expiry somewhat to give a bit of slack in cases
* where one RA gets lost or something (which can happen on unreliable
* links like WiFi where certain types of frames are not retransmitted).
* Note that 0 has special meaning and is therefore not adjusted.
*/
server.expires = ntohl (rdnss_opt->nd_opt_rdnss_lifetime);
if (server.expires > 0)
server.expires += now + 10;
for (addr = (struct in6_addr *) (rdnss_opt + 1); opt_len >= 2; addr++, opt_len -= 2) {
char buf[INET6_ADDRSTRLEN + 1];
if (!inet_ntop (AF_INET6, addr, buf, sizeof (buf))) {
nm_log_warn (LOGD_IP6, "(%s): received invalid RA-provided nameserver", device->iface);
continue;
}
/* Update the cached timeout if we already saw this server */
for (i = 0; i < device->rdnss_servers->len; i++) {
cur_server = &(g_array_index (device->rdnss_servers, NMIP6RDNSS, i));
if (!IN6_ARE_ADDR_EQUAL (addr, &cur_server->addr))
continue;
cur_server->expires = server.expires;
if (server.expires > 0) {
nm_log_dbg (LOGD_IP6, "(%s): refreshing RA-provided nameserver %s (expires in %ld seconds)",
device->iface, buf,
server.expires - now);
break;
}
nm_log_dbg (LOGD_IP6, "(%s): removing RA-provided nameserver %s on router request",
device->iface, buf);
g_array_remove_index (device->rdnss_servers, i);
changed = TRUE;
break;
}
if (server.expires == 0)
continue;
if (i < device->rdnss_servers->len)
continue;
nm_log_dbg (LOGD_IP6, "(%s): found RA-provided nameserver %s (expires in %ld seconds)",
device->iface, buf, server.expires - now);
server.addr = *addr;
g_array_append_val (new_servers, server);
}
/* New servers must be added in the order they are listed in the
* RA option and before any existing servers.
*
* Note: This is the place to remove servers if we want to cap the
* number of resolvers. The RFC states that the one to expire
* first of the existing servers should be removed.
*/
if (new_servers->len) {
g_array_prepend_vals (device->rdnss_servers,
new_servers->data, new_servers->len);
changed = TRUE;
}
g_array_free (new_servers, TRUE);
/* Timeouts may have changed even if IPs didn't */
set_rdnss_timeout (device);
return changed;
}
gboolean
gimp_paint_core_start (GimpPaintCore *core,
GimpDrawable *drawable,
GimpPaintOptions *paint_options,
const GimpCoords *coords,
GError **error)
{
GimpItem *item;
g_return_val_if_fail (GIMP_IS_PAINT_CORE (core), FALSE);
g_return_val_if_fail (GIMP_IS_DRAWABLE (drawable), FALSE);
g_return_val_if_fail (gimp_item_is_attached (GIMP_ITEM (drawable)), FALSE);
g_return_val_if_fail (GIMP_IS_PAINT_OPTIONS (paint_options), FALSE);
g_return_val_if_fail (coords != NULL, FALSE);
g_return_val_if_fail (error == NULL || *error == NULL, FALSE);
item = GIMP_ITEM (drawable);
if (core->stroke_buffer)
{
g_array_free (core->stroke_buffer, TRUE);
core->stroke_buffer = NULL;
}
core->stroke_buffer = g_array_sized_new (TRUE, TRUE,
sizeof (GimpCoords),
STROKE_BUFFER_INIT_SIZE);
core->cur_coords = *coords;
if (! GIMP_PAINT_CORE_GET_CLASS (core)->start (core, drawable,
paint_options,
coords, error))
{
return FALSE;
}
/* Allocate the undo structure */
if (core->undo_buffer)
g_object_unref (core->undo_buffer);
core->undo_buffer = gegl_buffer_dup (gimp_drawable_get_buffer (drawable));
/* Allocate the saved proj structure */
if (core->saved_proj_buffer)
{
g_object_unref (core->saved_proj_buffer);
core->saved_proj_buffer = NULL;
}
if (core->use_saved_proj)
{
GimpImage *image = gimp_item_get_image (item);
GimpPickable *pickable = GIMP_PICKABLE (gimp_image_get_projection (image));
GeglBuffer *buffer = gimp_pickable_get_buffer (pickable);
core->saved_proj_buffer = gegl_buffer_dup (buffer);
}
/* Allocate the canvas blocks structure */
if (core->canvas_buffer)
g_object_unref (core->canvas_buffer);
core->canvas_buffer =
gegl_buffer_new (GEGL_RECTANGLE (0, 0,
gimp_item_get_width (item),
gimp_item_get_height (item)),
babl_format ("Y u8"));
/* Get the initial undo extents */
core->x1 = core->x2 = core->cur_coords.x;
core->y1 = core->y2 = core->cur_coords.y;
core->last_paint.x = -1e6;
core->last_paint.y = -1e6;
{
GimpImage *image;
GimpChannel *mask;
GeglBuffer *mask_buffer = NULL;
gint offset_x = 0;
gint offset_y = 0;
image = gimp_item_get_image (item);
mask = gimp_image_get_mask (image);
/* don't apply the mask to itself and don't apply an empty mask */
if (GIMP_DRAWABLE (mask) == drawable || gimp_channel_is_empty (mask))
mask = NULL;
if (mask)
{
mask_buffer = gimp_drawable_get_buffer (GIMP_DRAWABLE (mask));
gimp_item_get_offset (item, &offset_x, &offset_y);
}
core->applicator =
gimp_applicator_new (gimp_drawable_get_buffer (drawable),
gimp_drawable_get_active_mask (drawable),
mask_buffer,
-offset_x, -offset_y);
}
/* Freeze the drawable preview so that it isn't constantly updated. */
gimp_viewable_preview_freeze (GIMP_VIEWABLE (drawable));
return TRUE;
}
/**
* g_byte_array_free:
* @array: a #GByteArray.
* @free_segment: if %TRUE the actual byte data is freed as well.
* @Returns: the element data if @free_segment is %FALSE, otherwise
* %NULL. The element data should be freed using g_free().
*
* Frees the memory allocated by the #GByteArray. If @free_segment is
* %TRUE it frees the actual byte data. If the reference count of
* @array is greater than one, the #GByteArray wrapper is preserved but
* the size of @array will be set to zero.
**/
guint8* g_byte_array_free (GByteArray *array,
gboolean free_segment)
{
return (guint8*) g_array_free ((GArray*) array, free_segment);
}
void
gimp_paint_core_finish (GimpPaintCore *core,
GimpDrawable *drawable,
gboolean push_undo)
{
GimpImage *image;
g_return_if_fail (GIMP_IS_PAINT_CORE (core));
g_return_if_fail (GIMP_IS_DRAWABLE (drawable));
g_return_if_fail (gimp_item_is_attached (GIMP_ITEM (drawable)));
if (core->applicator)
{
g_object_unref (core->applicator);
core->applicator = NULL;
}
if (core->stroke_buffer)
{
g_array_free (core->stroke_buffer, TRUE);
core->stroke_buffer = NULL;
}
image = gimp_item_get_image (GIMP_ITEM (drawable));
/* Determine if any part of the image has been altered--
* if nothing has, then just return...
*/
if ((core->x2 == core->x1) || (core->y2 == core->y1))
{
gimp_viewable_preview_thaw (GIMP_VIEWABLE (drawable));
return;
}
if (push_undo)
{
GeglBuffer *buffer;
gint x, y, width, height;
gimp_rectangle_intersect (core->x1, core->y1,
core->x2 - core->x1, core->y2 - core->y1,
0, 0,
gimp_item_get_width (GIMP_ITEM (drawable)),
gimp_item_get_height (GIMP_ITEM (drawable)),
&x, &y, &width, &height);
gimp_image_undo_group_start (image, GIMP_UNDO_GROUP_PAINT,
core->undo_desc);
GIMP_PAINT_CORE_GET_CLASS (core)->push_undo (core, image, NULL);
buffer = gegl_buffer_new (GEGL_RECTANGLE (0, 0, width, height),
gimp_drawable_get_format (drawable));
gegl_buffer_copy (core->undo_buffer,
GEGL_RECTANGLE (x, y, width, height),
buffer,
GEGL_RECTANGLE (0, 0, 0, 0));
gimp_drawable_push_undo (drawable, NULL,
buffer, x, y, width, height);
g_object_unref (buffer);
gimp_image_undo_group_end (image);
}
g_object_unref (core->undo_buffer);
core->undo_buffer = NULL;
if (core->saved_proj_buffer)
{
g_object_unref (core->saved_proj_buffer);
core->saved_proj_buffer = NULL;
}
gimp_viewable_preview_thaw (GIMP_VIEWABLE (drawable));
}
GpStatus
GdipPathIterNextSubpathPath (GpPathIterator *iterator, int *resultCount, GpPath *path, BOOL *isClosed)
{
int index = 0;
GpPointF point;
BYTE currentType;
if (!iterator || !resultCount || !isClosed)
return InvalidParameter;
/* There are no subpaths or we are done with all the subpaths */
if (!path || !iterator->path || (iterator->path->count == 0) ||
(iterator->subpathPosition == iterator->path->count)) {
*resultCount = 0;
*isClosed = TRUE;
return Ok;
}
/* Clear the existing values from path */
if (path->count > 0) {
g_array_free (path->points, TRUE);
g_byte_array_free (path->types, TRUE);
path->points = g_array_new (FALSE, FALSE, sizeof (GpPointF));
path->types = g_byte_array_new ();
path->count = 0;
}
/* Copy the starting point */
currentType = g_array_index (iterator->path->types, BYTE, iterator->subpathPosition);
point = g_array_index (iterator->path->points, GpPointF, iterator->subpathPosition);
g_array_append_val (path->points, point);
g_byte_array_append (path->types, ¤tType, 1);
path->count++;
/* Check for next start point */
for (index = iterator->subpathPosition + 1; index < iterator->path->count; index++) {
currentType = g_array_index (iterator->path->types, BYTE, index);
/* Copy the start point till next start point */
if (currentType == PathPointTypeStart)
break;
point = g_array_index (iterator->path->points, GpPointF, index);
g_array_append_val (path->points, point);
g_byte_array_append (path->types, ¤tType, 1);
path->count++;
}
*resultCount = index - iterator->subpathPosition;
/* set positions for next iteration */
iterator->pathTypePosition = iterator->subpathPosition;
iterator->subpathPosition = index;
/* Check if last subpath was closed */
currentType = g_array_index (iterator->path->types, BYTE, index - 1);
if (currentType & PathPointTypeCloseSubpath)
*isClosed = TRUE;
else
*isClosed = FALSE;
return Ok;
}
static void
list_selection_changed_cb (GdauiRawGrid *grid, gpointer user_data)
{
DsnConfigPrivate *priv;
GdaDataModel *model;
GArray *selection;
gchar *str;
const GValue *cvalue;
GtkWidget *win = gtk_widget_get_toplevel (GTK_WIDGET (grid));
if (gtk_widget_is_toplevel (win)) {
g_simple_action_set_enabled (G_SIMPLE_ACTION (g_action_map_lookup_action (G_ACTION_MAP (win),
"DatasourceDelete")), FALSE);
}
priv = g_object_get_data (G_OBJECT (user_data), DSN_CONFIG_DATA);
selection = gdaui_data_selector_get_selected_rows (GDAUI_DATA_SELECTOR (priv->dsn_list));
if (!selection) {
gtk_stack_set_visible_child_name (GTK_STACK (priv->stack), ST_NOPROP);
return;
}
model = gdaui_data_selector_get_model (GDAUI_DATA_SELECTOR (priv->dsn_list));
if (!GDA_IS_DATA_MODEL (model)) {
g_array_free (selection, TRUE);
gtk_stack_set_visible_child_name (GTK_STACK (priv->stack), ST_NOPROP);
return;
}
cvalue = gda_data_model_get_value_at (model, 0, g_array_index (selection, gint, 0), NULL);
g_array_free (selection, TRUE);
if (!cvalue) {
gtk_stack_set_visible_child_name (GTK_STACK (priv->stack), ST_NOPROP);
return;
}
str = gda_value_stringify ((GValue *) cvalue);
g_print ("==> %s\n", str);
GdaDsnInfo *dsn_info;
dsn_info = gda_config_get_dsn_info (str);
g_free (str);
if (!dsn_info) {
/* something went wrong here... */
gtk_stack_set_visible_child_name (GTK_STACK (priv->stack), ST_NOPROP);
return;
}
gdaui_dsn_editor_set_dsn (priv->dsn_editor, dsn_info);
if (gdaui_dsn_editor_need_authentication (priv->dsn_editor))
gtk_widget_show (GTK_WIDGET (priv->view_buttons [GDAUI_DSN_EDITOR_PANE_AUTH]));
else
gtk_widget_hide (GTK_WIDGET (priv->view_buttons [GDAUI_DSN_EDITOR_PANE_AUTH]));
gtk_toggle_button_set_active (priv->view_buttons [GDAUI_DSN_EDITOR_PANE_DEFINITION], TRUE);
gtk_stack_set_visible_child_name (GTK_STACK (priv->stack), ST_PROP);
if (gtk_widget_is_toplevel (win)) {
g_simple_action_set_enabled (G_SIMPLE_ACTION (g_action_map_lookup_action (G_ACTION_MAP (win),
"DatasourceDelete")), TRUE);
}
}
