void IMSelectorGetCands(IMSelector* imselector)
{
FcitxInstance* instance = imselector->owner;
FcitxInputState *input = FcitxInstanceGetInputState(instance);
FcitxIM* pim;
UT_array* imes = FcitxInstanceGetIMEs(instance);
FcitxInstanceCleanInputWindow(instance);
FcitxCandidateWordSetPageSize(FcitxInputStateGetCandidateList(input), 10);
FcitxCandidateWordSetChoose(FcitxInputStateGetCandidateList(input), DIGIT_STR_CHOOSE);
FcitxInputStateSetShowCursor(input, false);
FcitxInputContext* ic = FcitxInstanceGetCurrentIC(instance);
FcitxInputContext2* ic2 = (FcitxInputContext2*) ic;
if (!ic)
return;
FcitxMessagesAddMessageStringsAtLast(FcitxInputStateGetAuxUp(input),
MSG_TIPS, imselector->global ?
_("Select global input method: ") :
_("Select local input method: "));
if (ic2->imname) {
int idx = FcitxInstanceGetIMIndexByName(instance, ic2->imname);
FcitxIM* im = (FcitxIM*) utarray_eltptr(imes, idx);
if (im) {
FcitxMessagesAddMessageAtLast(FcitxInputStateGetAuxUp(input), MSG_TIPS, _("Current local input method is %s"), im->strName);
}
}
else {
FcitxMessagesAddMessageStringsAtLast(FcitxInputStateGetAuxUp(input),
MSG_TIPS,
_("No local input method"));
}
for (pim = (FcitxIM *) utarray_front(imes);
pim != NULL;
pim = (FcitxIM *) utarray_next(imes, pim)) {
FcitxCandidateWord candWord;
candWord.callback = IMSelectorGetCand;
candWord.owner = imselector;
candWord.strExtra = NULL;
if (ic2->imname && strcmp(ic2->imname, pim->uniqueName) == 0) {
candWord.priv = NULL;
candWord.strWord = strdup(_("Clear local input method"));
}
else {
candWord.priv = strdup(pim->uniqueName);
candWord.strWord = strdup(pim->strName);
}
candWord.wordType = MSG_OTHER;
FcitxCandidateWordAppend(FcitxInputStateGetCandidateList(input), &candWord);
}
}
void hook_add(char *group, char *event, char *pattern, char *expr, int id)
{
log_msg("HOOK", "ADD");
log_msg("HOOK", "<%s> %s `%s`", event, pattern, expr);
EventHandler *evh = get_event(event_idx(event));
if (!evh)
return;
expr = strip_quotes(expr);
Pattern *pat = NULL;
if (pattern)
pat = regex_pat_new(pattern);
Hook hook = { id, HK_CMD, NULL, NULL, NULL, pat, .data.cmd = expr };
augroup_insert(group, &hook);
utarray_push_back(evh->hooks, &hook);
}
static void hook_delete(EventHandler *evh, Augroup *aug)
{
for (int i = 0; i < utarray_len(evh->hooks); i++) {
Hook *it = (Hook*)utarray_eltptr(evh->hooks, i);
if (it->type == HK_CMD && it->aug == aug) {
free(it->data.cmd);
utarray_erase(evh->hooks, i, 1);
}
}
}
void hook_remove(char *group, char *event, char *pattern)
{
log_msg("HOOK", "REMOVE");
log_msg("HOOK", "<%s> %s `%s`", event, pattern, group);
Augroup *aug = NULL;
if (group)
HASH_FIND_STR(aug_tbl, group, aug);
if (event) {
EventHandler *evh = get_event(event_idx(event));
if (!evh)
return;
return hook_delete(evh, aug);
}
EventHandler *it;
for (it = default_events; it != NULL; it = it->hh.next)
hook_delete(it, aug);
}
FCITX_EXPORT_API
void FcitxInstanceGetWindowPosition(FcitxInstance* instance, FcitxInputContext* ic, int* x, int* y)
{
if (ic == NULL)
return;
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, ic->frontendid);
if (pfrontend == NULL)
return;
FcitxFrontend* frontend = (*pfrontend)->frontend;
if (frontend->GetWindowPosition)
frontend->GetWindowPosition((*pfrontend)->addonInstance, ic, x, y);
}
/* Add a sub-category to an existing or new category
* IN: parent_name, name of the parent category
* IN: child_name, name of the child category
*/
int MPIR_T_cat_add_subcat(const char *parent_name, const char *child_name)
{
int mpi_errno = MPI_SUCCESS;
int parent_index, child_index;
name2index_hash_t *hash_entry;
cat_table_entry_t *parent;
/* NULL or empty string are allowed */
if (parent_name == NULL || *parent_name == '\0' ||
child_name == NULL || *child_name == '\0')
{
goto fn_exit;
}
/* Find or create parent */
HASH_FIND_STR(cat_hash, parent_name, hash_entry);
if (hash_entry != NULL) {
/* Found parent in cat_table */
parent_index = hash_entry->idx;
} else {
/* parent is a new category */
MPIR_T_cat_create(parent_name);
parent_index = utarray_len(cat_table) - 1;
}
/* Find or create child */
HASH_FIND_STR(cat_hash, child_name, hash_entry);
if (hash_entry != NULL) {
/* Found child in cat_table */
child_index = hash_entry->idx;
} else {
/* child is a new category */
MPIR_T_cat_create(child_name);
child_index = utarray_len(cat_table) - 1;
}
/* Connect parent and child */
parent = (cat_table_entry_t *)utarray_eltptr(cat_table, parent_index);
utarray_push_back(parent->subcat_indices, &child_index);
/* Notify categories have been changed */
cat_stamp++;
fn_exit:
return mpi_errno;
fn_fail:
goto fn_exit;
}
void hook_clear_host(int id)
{
log_msg("HOOK", "CLEAR HOST");
EventHandler *evh;
for (evh = default_events; evh != NULL; evh = evh->hh.next) {
for (int i = 0; i < utarray_len(evh->hooks); i++) {
Hook *it = (Hook*)utarray_eltptr(evh->hooks, i);
if (it->bufno == id) {
if (it->type == HK_CMD)
free(it->data.cmd);
utarray_erase(evh->hooks, i, 1);
}
}
}
}
void device_consistency_signature_list_free(device_consistency_signature_list *list)
{
unsigned int size;
unsigned int i;
device_consistency_signature **p;
if(list) {
size = utarray_len(list->values);
for (i = 0; i < size; i++) {
p = (device_consistency_signature **)utarray_eltptr(list->values, i);
SIGNAL_UNREF(*p);
}
utarray_free(list->values);
free(list);
}
}
void LoadSkinDirectory(FcitxClassicUI* classicui)
{
UT_array* skinBuf = &classicui->skinBuf;
utarray_clear(skinBuf);
int i ;
DIR *dir;
struct dirent *drt;
struct stat fileStat;
size_t len;
char *pathBuf;
char **skinPath = FcitxXDGGetPathWithPrefix(&len, "skin");
for (i = 0; i < len; i++) {
dir = opendir(skinPath[i]);
if (dir == NULL)
continue;
while ((drt = readdir(dir)) != NULL) {
if (strcmp(drt->d_name , ".") == 0 || strcmp(drt->d_name, "..") == 0)
continue;
asprintf(&pathBuf, "%s/%s", skinPath[i], drt->d_name);
int statresult = stat(pathBuf, &fileStat);
free(pathBuf);
if (statresult == -1) {
continue;
}
if (fileStat.st_mode & S_IFDIR) {
/* check duplicate name */
int j = 0;
for (; j < skinBuf->i; j++) {
char **name = (char**) utarray_eltptr(skinBuf, j);
if (strcmp(*name, drt->d_name) == 0)
break;
}
if (j == skinBuf->i) {
char *temp = drt->d_name;
utarray_push_back(skinBuf, &temp);
}
}
}
closedir(dir);
}
FcitxXDGFreePath(skinPath);
return;
}
END_TEST
START_TEST (test_ports)
{
const zcr_port_t test_data[] = {
{PROTO_TCP, ACCESS_ALLOW, htons(21), 1},
{PROTO_TCP, ACCESS_ALLOW, htons(22), 1},
{PROTO_UDP, ACCESS_ALLOW, htons(23), 1},
{PROTO_UDP, ACCESS_ALLOW, htons(24), 1},
{PROTO_TCP, ACCESS_DENY, htons(25), 1},
{PROTO_TCP, ACCESS_DENY, htons(26), 1},
{PROTO_UDP, ACCESS_DENY, htons(27), 1},
{PROTO_UDP, ACCESS_DENY, htons(28), 1},
{PROTO_TCP, ACCESS_ALLOW, htons(29), 0},
{PROTO_TCP, ACCESS_ALLOW, htons(30), 0},
{PROTO_UDP, ACCESS_ALLOW, htons(31), 0},
{PROTO_UDP, ACCESS_ALLOW, htons(32), 0},
{PROTO_TCP, ACCESS_DENY, htons(33), 0},
{PROTO_TCP, ACCESS_DENY, htons(34), 0},
{PROTO_UDP, ACCESS_DENY, htons(35), 0},
{PROTO_UDP, ACCESS_DENY, htons(36), 0},
};
zclient_rule_parser_t *parser = zclient_rule_parser_new();
zclient_rules_t rules;
zclient_rules_init(&rules);
fail_if(!zclient_rule_parse(parser, &rules, "ports.allow.tcp.21.22"));
fail_if(!zclient_rule_parse(parser, &rules, "ports.allow.udp.23.24"));
fail_if(!zclient_rule_parse(parser, &rules, "ports.deny.tcp.25.26"));
fail_if(!zclient_rule_parse(parser, &rules, "ports.deny.udp.27.28"));
fail_if(!zclient_rule_parse(parser, &rules, "rmports.allow.tcp.29.30"));
fail_if(!zclient_rule_parse(parser, &rules, "rmports.allow.udp.31.32"));
fail_if(!zclient_rule_parse(parser, &rules, "rmports.deny.tcp.33.34"));
fail_if(!zclient_rule_parse(parser, &rules, "rmports.deny.udp.35.36"));
fail_if(!rules.have.port_rules);
fail_if(ARRAYSIZE(test_data) != utarray_len(&rules.port_rules));
for (size_t i = 0; i < ARRAYSIZE(test_data); i++) {
zcr_port_t *rule = *(zcr_port_t **) utarray_eltptr(&rules.port_rules, i);
fail_if(test_data[i].add != rule->add, "ports idx=%u add flag fail", i);
fail_if(test_data[i].proto != rule->proto, "ports idx=%u proto fail", i);
fail_if(test_data[i].policy != rule->policy, "ports idx=%u policy fail", i);
fail_if(test_data[i].port != rule->port, "ports idx=%u port fail", i);
}
zclient_rules_destroy(&rules);
}
int ATP_arrayGetArray(const ATP_Array *p_array, unsigned int p_index, ATP_Array **p_value)
{
Value *l_entry = (Value *) utarray_eltptr(CCAST(p_array), p_index);
if (l_entry == NULL)
{
ERR("Index out of bounds\n");
return 0;
}
if (l_entry->m_type == e_ATP_ValueType_array)
{
*p_value = &l_entry->m_value.m_array;
return 1;
}
return 0;
}
FCITX_EXPORT_API
FcitxInputContext* FcitxInstanceFindIC(FcitxInstance* instance, int frontendid, void *filter)
{
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, frontendid);
if (pfrontend == NULL)
return NULL;
FcitxFrontend* frontend = (*pfrontend)->frontend;
FcitxInputContext *rec = instance->ic_list;
while (rec != NULL) {
if (rec->frontendid == frontendid && frontend->CheckIC((*pfrontend)->addonInstance, rec, filter))
return rec;
rec = rec->next;
}
return NULL;
}
int ATP_arrayGetString(const ATP_Array *p_array, unsigned int p_index, const char **p_value)
{
Value *l_entry = (Value *) utarray_eltptr(CCAST(p_array), p_index);
if (l_entry == NULL)
{
ERR("Index out of bounds\n");
return 0;
}
if (l_entry->m_type == e_ATP_ValueType_string)
{
*p_value = utstring_body(&l_entry->m_value.m_string);
return 1;
}
return 0;
}
END_TEST
START_TEST (test_ports)
{
const struct zrule_port test_data[] = {
{PROTO_TCP, PORT_ALLOW, htons(21), 1},
{PROTO_TCP, PORT_ALLOW, htons(22), 1},
{PROTO_UDP, PORT_ALLOW, htons(23), 1},
{PROTO_UDP, PORT_ALLOW, htons(24), 1},
{PROTO_TCP, PORT_DENY, htons(25), 1},
{PROTO_TCP, PORT_DENY, htons(26), 1},
{PROTO_UDP, PORT_DENY, htons(27), 1},
{PROTO_UDP, PORT_DENY, htons(28), 1},
{PROTO_TCP, PORT_ALLOW, htons(29), 0},
{PROTO_TCP, PORT_ALLOW, htons(30), 0},
{PROTO_UDP, PORT_ALLOW, htons(31), 0},
{PROTO_UDP, PORT_ALLOW, htons(32), 0},
{PROTO_TCP, PORT_DENY, htons(33), 0},
{PROTO_TCP, PORT_DENY, htons(34), 0},
{PROTO_UDP, PORT_DENY, htons(35), 0},
{PROTO_UDP, PORT_DENY, htons(36), 0},
};
struct zcrules rules;
crules_init(&rules);
fail_if(0 != crules_parse(&rules, "ports.allow.tcp.21.22"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "ports.allow.udp.23.24"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "ports.deny.tcp.25.26"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "ports.deny.udp.27.28"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "rmports.allow.tcp.29.30"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "rmports.allow.udp.31.32"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "rmports.deny.tcp.33.34"), "ports parse fail");
fail_if(0 != crules_parse(&rules, "rmports.deny.udp.35.36"), "ports parse fail");
fail_if(!rules.have.port_rules, "ports have fail");
fail_if(sizeof(test_data) / sizeof(test_data[0]) != utarray_len(&rules.port_rules), "ports count fail");
for (size_t i = 0; i < sizeof(test_data) / sizeof(test_data[0]); i++) {
struct zrule_port *rule = *(struct zrule_port **) utarray_eltptr(&rules.port_rules, i);
fail_if(test_data[i].add != rule->add, "ports idx=%u add flag fail", i);
fail_if(test_data[i].proto != rule->proto, "ports idx=%u proto fail", i);
fail_if(test_data[i].type != rule->type, "ports idx=%u type fail", i);
fail_if(test_data[i].port != rule->port, "ports idx=%u port fail", i);
}
crules_free(&rules);
}
FCITX_EXPORT_API
void FcitxInstanceUpdateClientSideUI(FcitxInstance* instance, FcitxInputContext* ic)
{
if (ic == NULL)
return;
if (!(ic->contextCaps & CAPACITY_CLIENT_SIDE_UI))
return;
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, ic->frontendid);
if (pfrontend == NULL)
return;
FcitxFrontend* frontend = (*pfrontend)->frontend;
if (frontend->UpdateClientSideUI)
frontend->UpdateClientSideUI((*pfrontend)->addonInstance, ic);
}
void LoadSkinDirectory(FcitxClassicUI* classicui)
{
UT_array* skinBuf = &classicui->skinBuf;
utarray_clear(skinBuf);
int i ;
DIR *dir;
struct dirent *drt;
size_t len;
char **skinPath = FcitxXDGGetPathWithPrefix(&len, "skin");
for (i = 0; i < len; i++) {
dir = opendir(skinPath[i]);
if (dir == NULL)
continue;
while ((drt = readdir(dir)) != NULL) {
if (strcmp(drt->d_name , ".") == 0 ||
strcmp(drt->d_name, "..") == 0)
continue;
char *pathBuf;
fcitx_utils_alloc_cat_str(pathBuf, skinPath[i], "/", drt->d_name, "/fcitx_skin.conf");
boolean result = fcitx_utils_isreg(pathBuf);
free(pathBuf);
if (result) {
/* check duplicate name */
int j = 0;
for (; j < skinBuf->i; j++) {
char **name = (char**) utarray_eltptr(skinBuf, j);
if (strcmp(*name, drt->d_name) == 0)
break;
}
if (j == skinBuf->i) {
char *temp = drt->d_name;
utarray_push_back(skinBuf, &temp);
}
}
}
closedir(dir);
}
FcitxXDGFreePath(skinPath);
return;
}
FCITX_EXPORT_API
void FcitxInstanceSetICStateFromSameApplication(FcitxInstance* instance, int frontendid, FcitxInputContext *ic)
{
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, frontendid);
if (pfrontend == NULL)
return;
FcitxFrontend* frontend = (*pfrontend)->frontend;
if (!frontend->CheckICFromSameApplication)
return;
FcitxInputContext *rec = instance->ic_list;
while (rec != NULL) {
if (rec->frontendid == frontendid && frontend->CheckICFromSameApplication((*pfrontend)->addonInstance, rec, ic)) {
ic->state = rec->state;
break;
}
rec = rec->next;
}
}
FCITX_EXPORT_API
void FcitxInstanceUpdatePreedit(FcitxInstance* instance, FcitxInputContext* ic)
{
if (!instance->profile->bUsePreedit)
return;
if (ic == NULL)
return;
if (!(ic->contextCaps & CAPACITY_PREEDIT))
return;
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, ic->frontendid);
if (pfrontend == NULL)
return;
FcitxFrontend* frontend = (*pfrontend)->frontend;
frontend->UpdatePreedit((*pfrontend)->addonInstance, ic);
}
int MPII_Genutil_sched_sink(MPII_Genutil_sched_t * sched)
{
MPL_DBG_MSG_FMT(MPIR_DBG_COLL, VERBOSE,
(MPL_DBG_FDEST, "Gentran: sched [sink] total=%d", sched->total_vtcs));
vtx_t *vtxp;
int i, n_in_vtcs = 0, vtx_id;
int *in_vtcs;
int mpi_errno = MPI_SUCCESS;
MPIR_CHKLMEM_DECL(1);
/* assign a new vertex */
vtx_id = MPII_Genutil_vtx_create(sched, &vtxp);
vtxp->vtx_kind = MPII_GENUTIL_VTX_KIND__SINK;
MPIR_CHKLMEM_MALLOC(in_vtcs, int *, sizeof(int) * vtx_id,
mpi_errno, "in_vtcs buffer", MPL_MEM_COLL);
/* record incoming vertices */
for (i = vtx_id - 1; i >= 0; i--) {
vtx_t *sched_fence = (vtx_t *) utarray_eltptr(sched->vtcs, i);
MPIR_Assert(sched_fence != NULL);
if (sched_fence->vtx_kind == MPII_GENUTIL_VTX_KIND__FENCE)
/* no need to record this and any vertex before fence.
* Dependency on the last fence call will be added by
* the subsequent call to MPIC_Genutil_vtx_add_dependencies function */
break;
else {
in_vtcs[vtx_id - 1 - i] = i;
n_in_vtcs++;
}
}
MPII_Genutil_vtx_add_dependencies(sched, vtx_id, n_in_vtcs, in_vtcs);
fn_exit:
MPIR_CHKLMEM_FREEALL();
return vtx_id;
fn_fail:
goto fn_exit;
}
END_TEST
START_TEST (test_fwd)
{
const zcr_forward_t test_data[] = {
{PROTO_TCP, htons(53), 0x04030201, 0, 1},
{PROTO_UDP, htons(53), 0x08070605, 0, 1},
{PROTO_TCP, htons(80), 0x0C0B0A09, htons(83), 1},
{PROTO_UDP, htons(80), 0x100F0E0D, htons(83), 1},
{PROTO_TCP, htons(53), 0, 0, 0},
{PROTO_UDP, htons(53), 0, 0, 0},
{PROTO_TCP, htons(80), 0, 0, 0},
{PROTO_UDP, htons(80), 0, 0, 0},
};
zclient_rule_parser_t *parser = zclient_rule_parser_new();
zclient_rules_t rules;
zclient_rules_init(&rules);
fail_if(!zclient_rule_parse(parser, &rules, "fwd.tcp.53.1.2.3.4"));
fail_if(!zclient_rule_parse(parser, &rules, "fwd.udp.53.5.6.7.8"));
fail_if(!zclient_rule_parse(parser, &rules, "fwd.tcp.80.9.10.11.12:83"));
fail_if(!zclient_rule_parse(parser, &rules, "fwd.udp.80.13.14.15.16:83"));
fail_if(!zclient_rule_parse(parser, &rules, "rmfwd.tcp.53"));
fail_if(!zclient_rule_parse(parser, &rules, "rmfwd.udp.53"));
fail_if(!zclient_rule_parse(parser, &rules, "rmfwd.tcp.80"));
fail_if(!zclient_rule_parse(parser, &rules, "rmfwd.udp.80"));
fail_if(!rules.have.fwd_rules, "fwd have fail");
fail_if(ARRAYSIZE(test_data) != utarray_len(&rules.fwd_rules));
for (size_t i = 0; i < ARRAYSIZE(test_data); i++) {
zcr_forward_t *rule = *(zcr_forward_t **) utarray_eltptr(&rules.fwd_rules, i);
fail_if(test_data[i].add != rule->add, "fwd idx=%u add flag fail", i);
fail_if(test_data[i].proto != rule->proto, "fwd idx=%u proto fail", i);
fail_if(test_data[i].port != rule->port, "fwd idx=%u port fail", i);
fail_if(test_data[i].fwd_ip != rule->fwd_ip, "fwd idx=%u fwd_ip fail (0x%X)", i, rule->fwd_ip);
fail_if(test_data[i].fwd_port != rule->fwd_port, "fwd idx=%u fwd_port fail", i);
}
zclient_rules_destroy(&rules);
}
static Value *findOrCreateEntry(ATP_Array *p_array, unsigned int p_index)
{
Value *l_entry;
unsigned int l_length = utarray_len(CAST(p_array));
if (p_index > l_length)
{
ERR("Index out of bounds\n");
return NULL;
}
else if (p_index == l_length)
{
utarray_extend_back(CAST(p_array));
l_entry = (Value *) utarray_back(CAST(p_array));
}
else
{
l_entry = (Value *) utarray_eltptr(CAST(p_array), p_index);
}
return l_entry;
}
void call_hooks(EventHandler *evh, Plugin *host, Plugin *caller, HookArg *hka)
{
if (!evh)
return;
int count = utarray_len(evh->hooks);
for (int i = 0; i < count; i++) {
Hook *it = (Hook*)utarray_eltptr(evh->hooks, i);
if (it->type == HK_CMD) {
int id = id_from_plugin(host);
if (it->bufno == -1 || (host && id == it->bufno))
call_cmd_hook(it, hka);
continue;
}
if (it->host != host && it->type != HK_TMP)
continue;
call_intl_hook(it, host, caller, hka);
}
}
END_TEST
START_TEST (test_fwd)
{
const struct zrule_fwd test_data[] = {
{PROTO_TCP, htons(53), 0x04030201, 0, 1},
{PROTO_UDP, htons(53), 0x08070605, 0, 1},
{PROTO_TCP, htons(80), 0x0C0B0A09, htons(83), 1},
{PROTO_UDP, htons(80), 0x100F0E0D, htons(83), 1},
{PROTO_TCP, htons(53), 0, 0, 0},
{PROTO_UDP, htons(53), 0, 0, 0},
{PROTO_TCP, htons(80), 0, 0, 0},
{PROTO_UDP, htons(80), 0, 0, 0},
};
struct zcrules rules;
crules_init(&rules);
fail_if(0 != crules_parse(&rules, "fwd.tcp.53.1.2.3.4"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "fwd.udp.53.5.6.7.8"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "fwd.tcp.80.9.10.11.12:83"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "fwd.udp.80.13.14.15.16:83"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "rmfwd.tcp.53"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "rmfwd.udp.53"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "rmfwd.tcp.80"), "fwd parse fail");
fail_if(0 != crules_parse(&rules, "rmfwd.udp.80"), "fwd parse fail");
fail_if(!rules.have.fwd_rules, "fwd have fail");
fail_if(sizeof(test_data) / sizeof(test_data[0]) != utarray_len(&rules.fwd_rules), "fwd count fail");
for (size_t i = 0; i < sizeof(test_data) / sizeof(test_data[0]); i++) {
struct zrule_fwd *rule = *(struct zrule_fwd **) utarray_eltptr(&rules.fwd_rules, i);
fail_if(test_data[i].add != rule->add, "fwd idx=%u add flag fail", i);
fail_if(test_data[i].proto != rule->proto, "fwd idx=%u proto fail", i);
fail_if(test_data[i].port != rule->port, "fwd idx=%u port fail", i);
fail_if(test_data[i].fwd_ip != rule->fwd_ip, "fwd idx=%u fwd_ip fail (0x%X)", i, rule->fwd_ip);
fail_if(test_data[i].fwd_port != rule->fwd_port, "fwd idx=%u fwd_port fail", i);
}
crules_free(&rules);
}
FCITX_EXPORT_API
FcitxInputContext* FcitxInstanceCreateIC(FcitxInstance* instance, int frontendid, void * priv)
{
UT_array* frontends = &instance->frontends;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, frontendid);
if (pfrontend == NULL)
return NULL;
FcitxFrontend* frontend = (*pfrontend)->frontend;
FcitxInputContext *rec;
if (instance->free_list != NULL) {
rec = instance->free_list;
instance->free_list = instance->free_list->next;
} else
rec = malloc(sizeof(FcitxInputContext));
memset(rec, 0, sizeof(FcitxInputContext));
rec->frontendid = frontendid;
rec->offset_x = -1;
rec->offset_y = -1;
switch (instance->config->shareState) {
case ShareState_All:
rec->state = instance->globalState;
break;
case ShareState_None:
case ShareState_PerProgram:
rec->state = instance->config->defaultIMState;
break;
default:
break;
}
frontend->CreateIC((*pfrontend)->addonInstance, rec, priv);
rec->next = instance->ic_list;
instance->ic_list = rec;
return rec;
}
void scan_spool(int do_unlink) {
int i;
glob_t g;
struct stat sb;
UT_array *files;
UT_array *xtras;
utarray_new(files,&ut_str_icd);
utarray_new(xtras,&xtra_icd);
char **f, *file;
file_xtra x, *xp;
if (chdir(dir) == -1) exit(-1);
glob(wild, 0, NULL, &g);
for(i=0; i < g.gl_pathc; i++) {
utarray_push_back(files, &g.gl_pathv[i]);
}
utarray_sort(files, strsort);
f=NULL;
while ( (f=(char**)utarray_next(files,f))) {
file = *f;
stat(file,&sb);
if (do_unlink) unlink(file);
x.file_idx = utarray_eltidx(files,f);
x.file_len = sb.st_size;
utarray_push_back(xtras, &x);
}
utarray_sort(xtras, xtrasort);
xp=NULL;
while ( (xp=(file_xtra*)utarray_next(xtras,xp))) {
f = (char**)utarray_eltptr(files,xp->file_idx);
file = *f;
printf("file %s, len %d\n", blot(file),xp->file_len);
}
globfree(&g);
utarray_free(files);
utarray_free(xtras);
}
device_consistency_signature_list *device_consistency_signature_list_copy(const device_consistency_signature_list *list)
{
int result = 0;
device_consistency_signature_list *result_list = 0;
unsigned int size;
unsigned int i;
device_consistency_signature **p;
result_list = device_consistency_signature_list_alloc();
if(!result_list) {
result = SG_ERR_NOMEM;
goto complete;
}
size = utarray_len(list->values);
utarray_reserve(result_list->values, size);
for (i = 0; i < size; i++) {
p = (device_consistency_signature **)utarray_eltptr(list->values, i);
result = device_consistency_signature_list_push_back(result_list, *p);
if(result < 0) {
goto complete;
}
}
complete:
if(result < 0) {
if(result_list) {
device_consistency_signature_list_free(result_list);
}
return 0;
}
else {
return result_list;
}
}
FCITX_EXPORT_API
void FcitxInstanceCommitString(FcitxInstance* instance, FcitxInputContext* ic, char* str)
{
if (str == NULL)
return ;
if (ic == NULL)
return;
UT_array* frontends = &instance->frontends;
char *pstr = FcitxInstanceProcessCommitFilter(instance, str);
if (pstr != NULL)
str = pstr;
FcitxAddon** pfrontend = (FcitxAddon**) utarray_eltptr(frontends, ic->frontendid);
if (pfrontend == NULL)
return;
FcitxFrontend* frontend = (*pfrontend)->frontend;
frontend->CommitString((*pfrontend)->addonInstance, ic, str);
if (pstr)
free(pstr);
}
FCITX_EXPORT_API
void FcitxInstanceEnd(FcitxInstance* instance)
{
/* avoid duplicate destroy */
if (instance->destroy)
return;
if (!instance->initialized) {
if (!instance->loadingFatalError) {
if (!instance->quietQuit)
FcitxLog(ERROR, "Exiting.");
instance->loadingFatalError = true;
sem_post(instance->sem);
}
return;
}
instance->destroy = true;
FcitxProfileSave(instance->profile);
FcitxInstanceSaveAllIM(instance);
if (instance->uinormal && instance->uinormal->ui->Destroy)
instance->uinormal->ui->Destroy(instance->uinormal->addonInstance);
if (instance->uifallback && instance->uifallback->ui->Destroy)
instance->uifallback->ui->Destroy(instance->uifallback->addonInstance);
instance->uifallback = NULL;
instance->ui = NULL;
instance->uinormal = NULL;
/* handle exit */
FcitxAddon** pimclass;
FcitxAddon** pfrontend;
FcitxFrontend* frontend;
FcitxInputContext* rec = NULL;
for (pimclass = (FcitxAddon**) utarray_front(&instance->imeclasses);
pimclass != NULL;
pimclass = (FcitxAddon**) utarray_next(&instance->imeclasses, pimclass)
) {
if ((*pimclass)->imclass->Destroy)
(*pimclass)->imclass->Destroy((*pimclass)->addonInstance);
}
for (rec = instance->ic_list; rec != NULL; rec = rec->next) {
pfrontend = (FcitxAddon**) utarray_eltptr(&instance->frontends, rec->frontendid);
frontend = (*pfrontend)->frontend;
frontend->CloseIM((*pfrontend)->addonInstance, rec);
}
for (rec = instance->ic_list; rec != NULL; rec = rec->next) {
pfrontend = (FcitxAddon**) utarray_eltptr(&instance->frontends, rec->frontendid);
frontend = (*pfrontend)->frontend;
frontend->DestroyIC((*pfrontend)->addonInstance, rec);
}
for (pfrontend = (FcitxAddon**) utarray_front(&instance->frontends);
pfrontend != NULL;
pfrontend = (FcitxAddon**) utarray_next(&instance->frontends, pfrontend)
) {
if (pfrontend == NULL)
continue;
FcitxFrontend* frontend = (*pfrontend)->frontend;
frontend->Destroy((*pfrontend)->addonInstance);
}
FcitxAddon** pmodule;
for (pmodule = (FcitxAddon**) utarray_front(&instance->modules);
pmodule != NULL;
pmodule = (FcitxAddon**) utarray_next(&instance->modules, pmodule)
) {
if (pmodule == NULL)
return;
FcitxModule* module = (*pmodule)->module;
if (module->Destroy)
module->Destroy((*pmodule)->addonInstance);
}
sem_post(instance->sem);
/* don't return to main loop, wait for exit */
int countDown = 5;
while(countDown--) {
sleep(1000);
}
exit(0);
}
void* RunInstance(void* arg)
{
FcitxInstance* instance = (FcitxInstance*) arg;
instance->initialized = true;
int64_t curtime = 0;
while (1) {
FcitxAddon** pmodule;
uint8_t signo = 0;
while (read(instance->fd, &signo, sizeof(char)) > 0) {
if (signo == SIGINT || signo == SIGTERM || signo == SIGQUIT)
FcitxInstanceEnd(instance);
else if (signo == SIGHUP)
fcitx_utils_launch_restart();
else if (signo == SIGUSR1)
FcitxInstanceReloadConfig(instance);
}
do {
instance->uiflag = UI_NONE;
for (pmodule = (FcitxAddon**) utarray_front(&instance->eventmodules);
pmodule != NULL;
pmodule = (FcitxAddon**) utarray_next(&instance->eventmodules, pmodule)) {
FcitxModule* module = (*pmodule)->module;
module->ProcessEvent((*pmodule)->addonInstance);
}
struct timeval current_time;
gettimeofday(¤t_time, NULL);
curtime = (current_time.tv_sec * 1000LL) + (current_time.tv_usec / 1000LL);
int idx = 0;
while(idx < utarray_len(&instance->timeout))
{
TimeoutItem* ti = (TimeoutItem*) utarray_eltptr(&instance->timeout, idx);
uint64_t id = ti->idx;
if (ti->time + ti->milli <= curtime) {
ti->callback(ti->arg);
ti = (TimeoutItem*) utarray_eltptr(&instance->timeout, idx);
/* faster remove */
if (ti && ti->idx == id)
utarray_remove_quick(&instance->timeout, idx);
else {
FcitxInstanceRemoveTimeoutById(instance, id);
idx = 0;
}
}
else {
idx++;
}
}
if (instance->uiflag & UI_MOVE)
FcitxUIMoveInputWindowReal(instance);
if (instance->uiflag & UI_UPDATE)
FcitxUIUpdateInputWindowReal(instance);
} while (instance->uiflag != UI_NONE);
FD_ZERO(&instance->rfds);
FD_ZERO(&instance->wfds);
FD_ZERO(&instance->efds);
instance->maxfd = 0;
if (instance->fd > 0) {
instance->maxfd = instance->fd;
FD_SET(instance->fd, &instance->rfds);
}
for (pmodule = (FcitxAddon**) utarray_front(&instance->eventmodules);
pmodule != NULL;
pmodule = (FcitxAddon**) utarray_next(&instance->eventmodules, pmodule)) {
FcitxModule* module = (*pmodule)->module;
module->SetFD((*pmodule)->addonInstance);
}
if (instance->maxfd == 0)
break;
struct timeval tval;
struct timeval* ptval = NULL;
if (utarray_len(&instance->timeout) != 0) {
long int min_time = LONG_MAX;
TimeoutItem* ti;
for (ti = (TimeoutItem*) utarray_front(&instance->timeout);
ti != NULL;
ti = (TimeoutItem*) utarray_next(&instance->timeout, ti))
{
if (ti->time + ti->milli - curtime < min_time) {
min_time = ti->time + ti->milli - curtime;
}
}
tval.tv_usec = (min_time % 1000) * 1000;
tval.tv_sec = min_time / 1000;
ptval = &tval;
}
select(instance->maxfd + 1, &instance->rfds, &instance->wfds, &instance->efds, ptval);
}
return NULL;
}
/*@
MPI_T_pvar_get_info - Get the inforamtion about a performance variable
Input/Output Parameters:
+ name_len - length of the string and/or buffer for name (integer)
- desc_len - length of the string and/or buffer for desc (integer)
Input Parameters:
. pvar_index - index of the performance variable to be queried between 0 and num_pvar-1 (integer)
Output Parameters:
+ name - buffer to return the string containing the name of the performance variable (string)
. verbosity - verbosity level of this variable (integer)
. var_class - class of performance variable (integer)
. datatype - MPI type of the information stored in the performance variable (handle)
. enumtype - optional descriptor for enumeration information (handle)
. desc - buffer to return the string containing a description of the performance variable (string)
. binding - type of MPI object to which this variable must be bound (integer)
. readonly - flag indicating whether the variable can be written/reset (integer)
. continuous - flag indicating whether the variable can be started and stopped or is continuously active (integer)
- atomic - flag indicating whether the variable can be atomically read and reset (integer)
.N ThreadSafe
.N Errors
.N MPI_SUCCESS
.N MPI_T_ERR_NOT_INITIALIZED
.N MPI_T_ERR_INVALID_INDEX
@*/
int MPI_T_pvar_get_info(int pvar_index, char *name, int *name_len, int *verbosity,
int *var_class, MPI_Datatype *datatype, MPI_T_enum *enumtype, char *desc,
int *desc_len, int *binding, int *readonly, int *continuous, int *atomic)
{
int mpi_errno = MPI_SUCCESS;
const pvar_table_entry_t *entry;
const pvar_table_entry_t *info;
MPID_MPI_STATE_DECL(MPID_STATE_MPI_T_PVAR_GET_INFO);
MPIR_ERRTEST_MPIT_INITIALIZED(mpi_errno);
MPIR_T_THREAD_CS_ENTER();
MPID_MPI_FUNC_ENTER(MPID_STATE_MPI_T_PVAR_GET_INFO);
/* Validate parameters */
# ifdef HAVE_ERROR_CHECKING
{
MPID_BEGIN_ERROR_CHECKS
{
MPIR_ERRTEST_PVAR_INDEX(pvar_index, mpi_errno);
/* Do not do _TEST_ARGNULL for other arguments, since this is
* allowed or will be allowed by MPI_T standard.
*/
}
MPID_END_ERROR_CHECKS
}
# endif /* HAVE_ERROR_CHECKING */
/* ... body of routine ... */
entry = (pvar_table_entry_t *) utarray_eltptr(pvar_table, pvar_index);
if (!entry->active) {
mpi_errno = MPI_T_ERR_INVALID_INDEX;
goto fn_fail;
}
info = (pvar_table_entry_t *) utarray_eltptr(pvar_table, pvar_index);
MPIR_T_strncpy(name, info->name, name_len);
MPIR_T_strncpy(desc, info->desc, desc_len);
if (verbosity != NULL)
*verbosity = info->verbosity;
if (var_class != NULL)
*var_class = info->varclass;
if (datatype != NULL)
*datatype = info->datatype;
if (enumtype != NULL)
*enumtype = info->enumtype;
if (binding != NULL)
*binding = info->bind;
if (readonly != NULL)
*readonly = info->flags & MPIR_T_PVAR_FLAG_READONLY;
if (continuous != NULL)
*continuous = info->flags & MPIR_T_PVAR_FLAG_CONTINUOUS;
if (atomic != NULL)
*atomic = info->flags & MPIR_T_PVAR_FLAG_ATOMIC;
/* ... end of body of routine ... */
fn_exit:
MPID_MPI_FUNC_EXIT(MPID_STATE_MPI_T_PVAR_GET_INFO);
MPIR_T_THREAD_CS_EXIT();
return mpi_errno;
fn_fail:
/* --BEGIN ERROR HANDLING-- */
# ifdef HAVE_ERROR_CHECKING
{
mpi_errno = MPIR_Err_create_code(
mpi_errno, MPIR_ERR_RECOVERABLE, FCNAME, __LINE__, MPI_ERR_OTHER,
"**mpi_t_pvar_get_info", "**mpi_t_pvar_get_info %d %p %p %p %p %p %p %p %p %p %p %p %p",
pvar_index, name, name_len, verbosity, var_class, datatype, enumtype, desc, desc_len,
binding, readonly, continuous, atomic);
}
# endif
mpi_errno = MPIR_Err_return_comm(NULL, FCNAME, mpi_errno);
goto fn_exit;
/* --END ERROR HANDLING-- */
}
int MPIR_T_pvar_handle_alloc_impl(MPI_T_pvar_session session, int pvar_index,
void *obj_handle, MPI_T_pvar_handle *handle,int *count)
{
int mpi_errno = MPI_SUCCESS;
int cnt, extra, bytes;
int is_sum, is_watermark;
const pvar_table_entry_t *info;
MPIR_T_pvar_handle_t *hnd;
MPIR_CHKPMEM_DECL(1);
info = (pvar_table_entry_t *) utarray_eltptr(pvar_table, pvar_index);
if (info->get_count == NULL) {
cnt = info->count;
} else {
info->get_count(info->addr, obj_handle, &cnt);
}
bytes = MPID_Datatype_get_basic_size(info->datatype);
is_sum = FALSE;
is_watermark = FALSE;
extra = 0;
if (info->varclass == MPI_T_PVAR_CLASS_COUNTER ||
info->varclass == MPI_T_PVAR_CLASS_AGGREGATE ||
info->varclass == MPI_T_PVAR_CLASS_TIMER)
{
/* Extra memory for accum, offset, current */
is_sum = TRUE;
extra = bytes * cnt * 3;
} else if (info->varclass == MPI_T_PVAR_CLASS_HIGHWATERMARK ||
info->varclass == MPI_T_PVAR_CLASS_LOWWATERMARK)
{
is_watermark = TRUE;
}
/* Allocate memory and bzero it */
MPIR_CHKPMEM_CALLOC(hnd, MPIR_T_pvar_handle_t*, sizeof(*hnd) + extra,
mpi_errno, "performance variable handle");
#ifdef HAVE_ERROR_CHECKING
hnd->kind = MPIR_T_PVAR_HANDLE;
#endif
/* Setup the common fields */
if (is_sum)
hnd->flags |= MPIR_T_PVAR_FLAG_SUM;
else if (is_watermark)
hnd->flags |= MPIR_T_PVAR_FLAG_WATERMARK;
hnd->addr = info->addr;
hnd->datatype = info->datatype;
hnd->count = cnt;
hnd->varclass = info->varclass;
hnd->flags = info->flags;
hnd->session = session;
hnd->info = info;
hnd->obj_handle = obj_handle;
hnd->get_value = info->get_value;
hnd->bytes = bytes;
hnd->count = cnt;
/* Init pointers to cache buffers for a SUM */
if (MPIR_T_pvar_is_sum(hnd)) {
hnd->accum = (char*)(hnd) + sizeof(*hnd);
hnd->offset = (char*)(hnd) + sizeof(*hnd) + bytes*cnt;
hnd->current = (char*)(hnd) + sizeof(*hnd) + bytes*cnt*2;
}
if (MPIR_T_pvar_is_continuous(hnd))
MPIR_T_pvar_set_started(hnd);
/* Set starting value of a continuous SUM */
if (MPIR_T_pvar_is_continuous(hnd) && MPIR_T_pvar_is_sum(hnd)) {
/* Cache current value of a SUM in offset.
* accum is zero since we called CALLOC before.
*/
if (hnd->get_value == NULL)
MPIR_Memcpy(hnd->offset, hnd->addr, bytes*cnt);
else
hnd->get_value(hnd->addr, hnd->obj_handle, hnd->count, hnd->offset);
}
/* Link a WATERMARK handle to its pvar & set starting value if continuous */
if (MPIR_T_pvar_is_watermark(hnd)) {
MPIR_T_pvar_watermark_t *mark = (MPIR_T_pvar_watermark_t *)hnd->addr;
if (!mark->first_used) {
/* Use the special handle slot for optimization if available */
mark->first_used = TRUE;
MPIR_T_pvar_set_first(hnd);
/* Set starting value */
if (MPIR_T_pvar_is_continuous(hnd)) {
mark->first_started = TRUE;
mark->watermark = mark->current;
} else {
mark->first_started = FALSE;
}
} else {
/* If the special handle slot is unavailable, link it to hlist */
if (mark->hlist == NULL) {
hnd->prev2 = hnd;
mark->hlist = hnd;
} else {
hnd->prev2 = hnd;
hnd->next2 = mark->hlist;
mark->hlist->prev2 = hnd;
mark->hlist = hnd;
}
/* Set starting value */
if (MPIR_T_pvar_is_continuous(hnd))
hnd->watermark = mark->current;
}
}
/* Link the handle in its session and return it */
MPL_DL_APPEND(session->hlist, hnd);
*handle = hnd;
*count = cnt;
MPIR_CHKPMEM_COMMIT();
fn_exit:
return mpi_errno;
fn_fail:
MPIR_CHKPMEM_REAP();
goto fn_exit;
}
compl_item* compl_idx_match(fn_compl *cmpl, int idx)
{
return (compl_item*)utarray_eltptr(cmpl->matches, idx);
}
