static int init_keyset (scs_t *ctx, scs_keyset_t *ks, const char *tid, int comp,
scs_cipherset_t cipherset, const uint8_t *key, const uint8_t *hkey)
{
if (set_tid(ctx, ks, tid))
return SCS_ERR_BAD_TID;
/* Set the compression flag as requested. In case zlib is not available
* on the platform, ignore user request and set to false. */
ks->comp = have_libz ? comp : 0;
/* Setup keyset and cipherset. */
switch ((ks->cipherset = cipherset))
{
case AES_128_CBC_HMAC_SHA1:
ks->key_sz = ks->block_sz = 16;
ks->hkey_sz = 20;
break;
default:
return SCS_ERR_WRONG_CIPHERSET;
}
/* Create or attach new HMAC and cipher keys. */
if (new_key(ks->key, key, ks->key_sz)
|| new_key(ks->hkey, hkey, ks->hkey_sz))
return SCS_ERR_CRYPTO;
return SCS_OK;
}
/**
* Refresh current keyset with the supplied keying material.
*
* Update the current keyset with the supplied keying material (both HMAC and
* encryption keys must be given at once) and associate it with the supplied
* TID. Note that the TID string must be different from the one currently in
* use. In case of error, the current keyset is kept in use.
*
* \param ctx The scs_t object that will be refreshed.
* \param new_tid The new TID string.
* \param key Encryption key; it is assumed to be of the correct size,
* i.e. 16 bytes for AES 128.
* \param hkey HMAC key; it is assumed to be of the correct size, i.e. 20
* bytes for SHA1-based HMAC.
*
* \return \c 0 on success, \c -1 if an error occurs.
*/
int scs_refresh_keyset (scs_t *ctx, const char *new_tid, const uint8_t *key,
const uint8_t *hkey)
{
time_t now;
scs_keyset_t *ks = &ctx->cur_keyset;
scs_keyset_t *cur = &ctx->cur_keyset, *prev = &ctx->prev_keyset, tmp;
tmp = *prev;
*prev = *cur;
/* Get current timestamp. */
if (what_time_is_it(ctx, &now))
return -1;
/* Create new keying material. */
if (new_key(ks->key, key, ks->key_sz)
|| new_key(ks->hkey, hkey, ks->hkey_sz))
{
scs_set_error(ctx, SCS_ERR_CRYPTO, "keyset update failed.");
goto recover;
}
/* Set new tid name. */
if (set_tid(ctx, cur, new_tid))
return -1;
return 0;
recover:
*cur = *prev;
*prev = tmp;
return -1;
}
void test_hash_table_free_functions(void)
{
HashTable *hash_table;
int *key;
int *value;
int i;
/* Create a hash table, fill it with values */
hash_table = hash_table_new(int_hash, int_equal);
hash_table_register_free_functions(hash_table, free_key, free_value);
allocated_values = 0;
for (i=0; i<NUM_TEST_VALUES; ++i) {
key = new_key(i);
value = new_value(99);
hash_table_insert(hash_table, key, value);
}
assert(allocated_keys == NUM_TEST_VALUES);
assert(allocated_values == NUM_TEST_VALUES);
/* Check that removing a key works */
i = NUM_TEST_VALUES / 2;
hash_table_remove(hash_table, &i);
assert(allocated_keys == NUM_TEST_VALUES - 1);
assert(allocated_values == NUM_TEST_VALUES - 1);
/* Check that replacing an existing key works */
key = new_key(NUM_TEST_VALUES / 3);
value = new_value(999);
assert(allocated_keys == NUM_TEST_VALUES);
assert(allocated_values == NUM_TEST_VALUES);
hash_table_insert(hash_table, key, value);
assert(allocated_keys == NUM_TEST_VALUES - 1);
assert(allocated_values == NUM_TEST_VALUES - 1);
/* A free of the hash table should free all of the keys and values */
hash_table_free(hash_table);
assert(allocated_keys == 0);
assert(allocated_values == 0);
}
void
Sender_exec_i::write_many ()
{
DDS4CCM_TEST_DEBUG << "Sender_exec_i::write_many" << std::endl;
uint32_t nr_samples = this->keys_ * this->iterations_;
UnkeyedWriterTest::UnkeyedWriterMessageSeq write_many_no_excep;
write_many_no_excep.resize (nr_samples);
//write with no exception
for (uint32_t i = 1; i < nr_samples + 1; ++i)
{
OctetSeq reply_mesg (1);
UnkeyedWriterTest::UnkeyedWriterMessage new_key ("KEY_1", 1, reply_mesg);
write_many_no_excep[i-1] = new_key;
}
try
{
IDL::traits < UnkeyedWriterTest::UnkeyedWriterMessageConnector::Writer >::ref_type writer =
this->context_->get_connection_info_write_data ();
writer->write_many (write_many_no_excep);
DDS4CCM_TEST_DEBUG << "write_many : written <"
<< write_many_no_excep.size () << "> samples."
<< std::endl;
}
catch (const CCM_DDS::InternalError& ex)
{
DDS4CCM_TEST_ERROR << "ERROR: Internal Error while write many writer "
<< ex << std::endl;
}
start_new_assignment (WRITER_ASSIGNMENT::TEST_EXCEPTION);
}
//@@{__RIDL_REGEN_MARKER__} - BEGIN : CIAO_CFT_EL_Test_Sender_Impl::Sender_exec_i[src_user_public_ops]
void
Sender_exec_i::start_publishing ()
{
for (uint16_t i = 1; i < this->keys_ + 1; ++i)
{
std::string const key ("KEY_" + std::to_string (i));
CFT_EL_Message new_key (key, 0);
this->samples_[key] = new_key;
}
this->last_key_ = this->samples_.begin ();
// calculate the interval time
long const usec = 1000000 / this->rate_;
if (this->reactor ()->schedule_timer (
this->ticker_.get (),
0,
ACE_Time_Value (0, usec),
ACE_Time_Value (0, usec)) == -1)
{
DDS4CCM_TEST_ERROR << "Sender_exec_i::start_publishing : Error scheduling timer." << std::endl;
}
else
DDS4CCM_TEST_DEBUG << "Sender_exec_i::start_publishing : Started timer." << std::endl;
}
event_node_ptr fake_event_source::release_key(const size_t time, const SDLKey key, const SDLMod mod)
{
SDL_Event event = make_key_event(SDL_KEYUP, key, mod);
event_node_ptr new_key(new event_node_keyboard(time, event));
add_event(new_key);
return new_key;
}
int main (int argc, char *argv[])
{
char buff[1024];
char *s;
struct sig **lastsig = NULL;
struct uid **lastuid = NULL;
struct key *k = new_key();
lastuid = &k->uids;
if (argc == 2 && !strcmp (argv[1], "-S"))
DontRequireSelfSig = 1;
while (fgets (buff, sizeof (buff), stdin))
{
if ((s = strtok (buff, ":")))
{
if (!strcmp (s, "pub"))
{
do_key (k);
k->rev = 0;
k->uids = new_uid();
lastuid = &k->uids->next;
lastsig = &k->uids->sigs;
strtok (NULL, ":");
strtok (NULL, ":");
strtok (NULL, ":");
sprintf (k->id, "%s", strtok (NULL, ":"));
}
else if (!strcmp (s, "rev"))
k->rev = 1;
else if (!strcmp (s, "uid"))
{
struct uid *uid = *lastuid = new_uid();
lastuid = &(*lastuid)->next;
lastsig = &uid->sigs;
}
else if (!strcmp (s, "sig"))
{
struct sig *sig = *lastsig = new_sig();
lastsig = &sig->next;
sprintf (sig->id, "%s", strtok (NULL, ":"));
}
}
}
do_key (k);
return 0;
}
/* special interface to new_key for the default key bindings */
static void snew_key (int meta, unsigned chr, char *what)
{
int i;
int j;
if ((j = lookup_function(what, &i)) == 1)
new_key(meta, chr, i, 0, NULL);
#if 0
else
ircpanic("Something bogus passed to snew_key");
#endif
}
/*
* Process a key block
*/
static int
process_key(struct state *cur, struct block *info,
const char *name, scconf_block *blk)
{
unsigned int type, id;
struct state state;
if (get_authid(cur, name, &type, &id))
return 1;
init_state(cur, &state);
state.key = new_key(cur->profile, type, id);
return process_block(&state, info, name, blk);
}
int ConnServer::prepare_snd_conv(const sockaddr* addr, uv_udp_t* handle, uint32_t n) {
_addr = *addr;
_udp = handle;
_n = n;
_conv = new_conv();
_next_snd_conv_tick = 0;
_snd_conv.conv = CONV_SND_CONV;
_snd_conv.n = n;
_snd_conv.new_conv = _conv;
_snd_conv.key = new_key();
_key = _snd_conv.key;
_status = CONV_SND_CONV;
return init_kcp(_conv);
}
shard map(MYSQL* conn, long long schema_id, long long column_id, std::string key_value) {
std::string sql;
sql = "select shard_name from shard_map_string join shards on shard_id = shards.id where column_id =" + std::to_string(column_id) + " and key_value = '" + key_value + "'";
if(int err = mysql_query(conn, sql.c_str())) {
std::cerr << "ERROR: " << err << ", " << mysql_error(conn) << "\n";
exit(-1);
}
MYSQL_RES *result = mysql_store_result(conn);
MYSQL_ROW row = mysql_fetch_row(result);
if(!row) {
if(!depth) return(new_key(conn, schema_id, column_id, key_value));
std::cerr << "ERROR: recusive mapping failed after new key creation failed. Invalid state.\n";
exit(-1);
}
shard s = populate_shard(row);
mysql_free_result(result);
return s;
}
static void snew_key_from_str (uc *string, char *what)
{
int i;
int meta;
int old_display;
uc chr;
old_display = window_display;
window_display = 0;
if ((meta = parse_key(string, &chr)) == -1)
return;
window_display = old_display;
if (lookup_function(what, &i) == 1)
new_key(meta, chr, i, 0, NULL);
return;
}
Handle<ScopedEVP_PKEY> JwkEc::To(int &key_type) {
LOG_FUNC();
LOG_INFO("Check key_type");
if (!(key_type == NODESSL_KT_PRIVATE || key_type == NODESSL_KT_PUBLIC)) {
THROW_ERROR("Wrong value of key_type");
}
LOG_INFO("import EC from JWK");
ScopedEC_KEY ec_key(EC_KEY_new());
LOG_INFO("set public key");
ScopedEC_GROUP group(EC_GROUP_new_by_curve_name(this->crv));
if (group.isEmpty()) {
THROW_OPENSSL("EC_GROUP_new_by_curve_name");
}
EC_KEY_set_group(ec_key.Get(), group.Get());
ScopedBIGNUM x(BN_dup(this->x.Get()));
ScopedBIGNUM y(BN_dup(this->y.Get()));
if (EC_KEY_set_public_key_affine_coordinates(ec_key.Get(), x.Get(), y.Get()) != 1) {
THROW_OPENSSL("EC_KEY_set_public_key_affine_coordinates");
}
x.unref();
y.unref();
if (key_type == NODESSL_KT_PRIVATE) {
LOG_INFO("set private key");
ScopedBIGNUM d(BN_dup(this->d.Get()));
if (EC_KEY_set_private_key(ec_key.Get(), d.Get()) != 1) {
THROW_OPENSSL("EC_KEY_set_private_key");
}
d.unref();
}
LOG_INFO("set internal key");
Handle<ScopedEVP_PKEY> new_key(new ScopedEVP_PKEY(EVP_PKEY_new()));
EVP_PKEY_assign_EC_KEY(new_key->Get(), ec_key.Get());
ec_key.unref();
return new_key;
}
void
Sender_exec_i::start_publishing ()
{
std::lock_guard<std::mutex> __guard (this->mutex_);
for (uint16_t i = 1; i < this->keys_ + 1; ++i)
{
std::string key("KEY_" + std::to_string (i));
OctetSeq seq (1);
UnkeyedWriterTest::UnkeyedWriterMessage new_key (
key, 1, seq);
this->ktests_[key] = new_key;
DDS4CCM_TEST_DEBUG << "Created key : " << new_key << std::endl;
}
this->last_key_ = this->ktests_.begin ();
reset_iterations ();
this->start ();
}
void LayoutParser::parseKey(const TagRowPtr &row)
{
static const QStringList styleValues(QString::fromLatin1("normal,special,deadkey").split(','));
static const QStringList widthValues(QString::fromLatin1("small,medium,large,x-large,xx-large,stretched").split(','));
const QXmlStreamAttributes attributes(m_xml.attributes());
const TagKey::Style style(enumValue("style", styleValues, TagKey::Normal));
const TagKey::Width width(enumValue("width", widthValues, TagKey::Medium));
const bool rtl(boolValue(attributes.value(QLatin1String("rtl")), false));
const QString id(attributes.value(QLatin1String("id")).toString());
TagKeyPtr new_key(new TagKey(style, width, rtl, id));
row->appendElement(new_key);
while (m_xml.readNextStartElement()) {
const QStringRef name(m_xml.name());
if (name == QLatin1String("binding")) {
if (not new_key->binding()) {
parseBinding(new_key);
} else {
error(QString::fromLatin1("Expected only one '<binding>', but got another one."));
}
} else if (name == QLatin1String("extended")) {
if (not new_key->extended()) {
parseExtended(new_key);
} else {
error(QString::fromLatin1("Expected only one '<extended>', but got another one."));
}
} else {
error(QString::fromLatin1("Expected '<binding>' or '<extended>', but got '<%1>'.").arg(name.toString()));
}
}
if (not new_key->binding()) {
error(QString::fromLatin1("Expected exactly one '<binding>' but got none."));
}
}
bool INIFile::setLine(LineIterator line_it, const String& line)
{
// section lines cannot be changed with this method
if (!isValid(line_it) || (*line_it)[0] == '[')
{
return false;
}
String new_key(line.before("="));
new_key.trim();
if ((*line_it).hasSubstring("=", 1))
{
// oh, this line had a key :(
String old_key((*line_it).before("="));
old_key.trim();
if (old_key == new_key)
{
line_it.setLine_(line);
return true;
}
// its a new key: delete the old one.
line_it.getSection()->key_map_.remove(old_key);
}
line_it.setLine_(line);
if (line.hasSubstring("=", 1))
{
// oh, the new line has a key :(
line_it.getSection()->key_map_[new_key] = line_it.getPosition();
}
return true;
}
// returns all skies referenced by the day cycle, with their final names
// side effect: applies changes to all internal structures!
std::map<LLWLParamKey, LLWLParamSet> LLWLParamManager::finalizeFromDayCycle(LLWLParamKey::EScope scope)
{
lldebugs << "mDay before finalizing:" << llendl;
{
for (std::map<F32, LLWLParamKey>::iterator iter = mDay.mTimeMap.begin(); iter != mDay.mTimeMap.end(); ++iter)
{
LLWLParamKey& key = iter->second;
lldebugs << iter->first << "->" << key.name << llendl;
}
}
std::map<LLWLParamKey, LLWLParamSet> final_references;
// Move all referenced to desired scope, renaming if necessary
// First, save skies referenced
std::map<LLWLParamKey, LLWLParamSet> current_references; // all skies referenced by the day cycle, with their current names
// guard against skies with same name and different scopes
std::set<std::string> inserted_names;
std::map<std::string, unsigned int> conflicted_names; // integer later used as a count, for uniquely renaming conflicts
LLWLDayCycle& cycle = mDay;
for(std::map<F32, LLWLParamKey>::iterator iter = cycle.mTimeMap.begin();
iter != cycle.mTimeMap.end();
++iter)
{
LLWLParamKey& key = iter->second;
std::string desired_name = key.name;
replace_newlines_with_whitespace(desired_name); // already shouldn't have newlines, but just in case
if(inserted_names.find(desired_name) == inserted_names.end())
{
inserted_names.insert(desired_name);
}
else
{
// make exist in map
conflicted_names[desired_name] = 0;
}
current_references[key] = mParamList[key];
}
// forget all old skies in target scope, and rebuild, renaming as needed
clearParamSetsOfScope(scope);
for(std::map<LLWLParamKey, LLWLParamSet>::iterator iter = current_references.begin(); iter != current_references.end(); ++iter)
{
const LLWLParamKey& old_key = iter->first;
std::string desired_name(old_key.name);
replace_newlines_with_whitespace(desired_name);
LLWLParamKey new_key(desired_name, scope); // name will be replaced later if necessary
// if this sky is one with a non-unique name, rename via appending a number
// an existing preset of the target scope gets to keep its name
if (scope != old_key.scope && conflicted_names.find(desired_name) != conflicted_names.end())
{
std::string& new_name = new_key.name;
do
{
// if this executes more than once, this is an absurdly pathological case
// (e.g. "x" repeated twice, but "x 1" already exists, so need to use "x 2")
std::stringstream temp;
temp << desired_name << " " << (++conflicted_names[desired_name]);
new_name = temp.str();
} while (inserted_names.find(new_name) != inserted_names.end());
// yay, found one that works
inserted_names.insert(new_name); // track names we consume here; shouldn't be necessary due to ++int? but just in case
// *TODO factor out below into a rename()?
LL_INFOS("Windlight") << "Renamed " << old_key.name << " (scope" << old_key.scope << ") to "
<< new_key.name << " (scope " << new_key.scope << ")" << LL_ENDL;
// update name in sky
iter->second.mName = new_name;
// update keys in day cycle
for(std::map<F32, LLWLParamKey>::iterator frame = cycle.mTimeMap.begin(); frame != cycle.mTimeMap.end(); ++frame)
{
if (frame->second == old_key)
{
frame->second = new_key;
}
}
// add to master sky map
mParamList[new_key] = iter->second;
}
final_references[new_key] = iter->second;
}
lldebugs << "mDay after finalizing:" << llendl;
{
for (std::map<F32, LLWLParamKey>::iterator iter = mDay.mTimeMap.begin(); iter != mDay.mTimeMap.end(); ++iter)
{
LLWLParamKey& key = iter->second;
lldebugs << iter->first << "->" << key.name << llendl;
}
}
return final_references;
}
/*
* A lot of magic goes on in this function. The general purpose of this
* function is to take a "key-description" of any form, and canonicalize
* it down into a resulting meta map (which is the return value), and return
* the final character in 'term'. Older algorithms only allowed you to
* specify META(X)-(Y), where X is the meta value to be returned and Y is
* the character, and anything else was an error. Now we allow you to specify
* any arbitrary string -- if the leading part of the string is already bound
* to a META key, then we can deal with that. If the leading part of the
* string is NOT bound to anything in particular, then we will bind it FOR
* you, and the resulting meta state is returned. This allows things like
* this to work:
*
* /BIND META2-C BIND-ACTION (Specify a meta map directly)
* /BIND ^[[A BIND-ACTION (^[[ is bound to META2 by default)
* /BIND ^[[11~ BIND-ACTION (Force us to make suer ^[[11 is bound
* to a meta map before returning.)
*/
static int parse_key (const uc *sequence, uc *term)
{
uc *copy;
uc *end;
int return_meta = 0;
int meta;
uc last_character;
uc terminal_character;
int last;
int somethingN;
#ifdef GUI
int mouse;
#endif
/*
* Make a local copy of the string to be bound. Redux all of
* the ^x modifers to their literal control characters.
*/
copy = alloca(strlen(sequence) + 4);
copy_redux(sequence, copy);
end = copy + strlen(copy) - 1;
#ifdef GUI
for( mouse = 0; mouse < MAX_MOUSE; mouse++)
{
if (!my_strnicmp(sequence, mouse_actions[mouse], strlen(mouse_actions[mouse])))
{
*term=(char)mouse;
return MAX_META;
}
}
#endif
if (x_debug & DEBUG_AUTOKEY)
yell("Starting with COPY := [%s]", copy);
/*
* Remove any leading META description
*/
if ((meta = grok_meta(copy, (const uc **)©)) == -1)
meta = 0;
if (x_debug & DEBUG_AUTOKEY)
yell("After META grokked, COPY := [%s]", copy);
/*
* Remove any leading characters that also comprise a META
* description
*/
while (copy[0] && copy[1])
{
if (keys[meta] && KEY(meta, *copy) &&
KEY(meta, *copy)->key_index < 0)
{
meta = -(KEY(meta, *copy)->key_index);
copy++;
if (x_debug & DEBUG_AUTOKEY)
{
yell("First character of COPY switches to meta [%d]", meta);
yell("After META grokked, COPY := [%s]", copy);
}
continue;
}
break;
}
if (x_debug & DEBUG_AUTOKEY)
yell("After ALL META grokked, COPY := [%s]", copy);
/*
* Check to see if the entire sequence was just a meta modifier
* or if it is a META-KEY modifier. Either way, we're done.
*/
if (!copy[0] || !copy[1])
{
*term = copy[0];
return meta;
}
/*
* Right now the input boils down to this:
*
* input := SOME_CHARACTERS + TERMINAL_CHARACTER + LAST_CHARACTER
* SOME_CHARACTERS := <key>*
* TERMINAL_CHARACTER := <key>
* LAST_CHARACTER := <key>
*
* The previous check assures that 'terminal character' is not
* an empty value at this point.
*/
last_character = *end;
*end-- = 0;
terminal_character = *end;
*end-- = 0;
if (x_debug & DEBUG_AUTOKEY)
{
yell("Starting to work on the string:");
yell("SOME_CHARACTERS := [%s] (%d)", copy, strlen(copy));
yell("TERMINAL_CHARACTER := [%c]", terminal_character);
yell("LAST_CHARACTER := [%c]", last_character);
}
/*
* Our ultimate goal is to return when the operation:
* /bind META<something>-LAST_CHARACTER <binding>
* will succeed. So we need to find a place to put LAST_CHARACTER.
*/
last = return_meta = find_meta_map(last_character);
if (x_debug & DEBUG_AUTOKEY)
{
yell("FIND_META_MAP says we can put [%c] in META [%d]",
last_character, return_meta);
}
/*
* So now we need to work backwards through the string linking
* each of the characters to the next one. Starting with
* TERMINAL_CHARACTER, we find a meta map where that can be linked
* from (that map is somethingN1). We then do:
*
* /bind META<somethingN1>-TERMINAL_CHARACTER META<LAST>
*
* Where 'last' is the most previous meta map we linked to, starting
* with 'something'.
*/
while (*copy)
{
if (x_debug & DEBUG_AUTOKEY)
{
yell("COPY: [%s] (%d)", copy, strlen(copy));
yell("Now we are going to bind the [%c] character to meta [%d] somehow.",
terminal_character, last);
}
/*
* <something> is any meta map such that:
* /bind META<somethingN>-[TERMINAL CHARACTER] META<something>
*/
somethingN = find_meta_map(terminal_character);
if (x_debug & DEBUG_AUTOKEY)
yell("FIND_META_MAP says we can do this in META [%d]", somethingN);
new_key(somethingN, terminal_character, -last, 1, NULL);
show_binding(somethingN, terminal_character);
/*
* Now we walk backwards in the string: 'last' now becomes
* the meta map we just linked, and we pop TERMINAL_CHARACTER
* off the end of SOME_CHARACTERS. We repeat this until
* SOME_CHARACTERS is empty.
*/
last = somethingN;
terminal_character = *end;
*end-- = 0;
}
/*
* Make the final link from the initial meta state to our newly
* constructed chain...
*/
new_key(meta, terminal_character, -last, 1, NULL);
show_binding(meta, terminal_character);
/*
* Return the interesting information
*/
*term = last_character;
return return_meta;
#if 0
/* The rest of this isnt finished, hense is unsupported */
say("The bind cannot occur because the character sequence to bind contains a leading substring that is bound to something else.");
return -1;
#endif
}
void process_site_event(OUTPUT* output) {
// Get next site event to process.
site_event_type site_event = *site_event_iterator_;
// Move site iterator.
site_event_iterator_type last = site_event_iterator_ + 1;
// If a new site is an end point of some segment,
// remove temporary nodes from the beach line data structure.
if (!site_event.is_segment()) {
while (!end_points_.empty() &&
end_points_.top().first == site_event.point0()) {
beach_line_iterator b_it = end_points_.top().second;
end_points_.pop();
beach_line_.erase(b_it);
}
} else {
while (last != site_events_.end() &&
last->is_segment() && last->point0() == site_event.point0())
++last;
}
// Find the node in the binary search tree with left arc
// lying above the new site point.
key_type new_key(*site_event_iterator_);
beach_line_iterator right_it = beach_line_.lower_bound(new_key);
for (; site_event_iterator_ != last; ++site_event_iterator_) {
site_event = *site_event_iterator_;
beach_line_iterator left_it = right_it;
// Do further processing depending on the above node position.
// For any two neighboring nodes the second site of the first node
// is the same as the first site of the second node.
if (right_it == beach_line_.end()) {
// The above arc corresponds to the second arc of the last node.
// Move the iterator to the last node.
--left_it;
// Get the second site of the last node
const site_event_type& site_arc = left_it->first.right_site();
// Insert new nodes into the beach line. Update the output.
right_it = insert_new_arc(
site_arc, site_arc, site_event, right_it, output);
// Add a candidate circle to the circle event queue.
// There could be only one new circle event formed by
// a new bisector and the one on the left.
activate_circle_event(left_it->first.left_site(),
left_it->first.right_site(),
site_event, right_it);
} else if (right_it == beach_line_.begin()) {
// The above arc corresponds to the first site of the first node.
const site_event_type& site_arc = right_it->first.left_site();
// Insert new nodes into the beach line. Update the output.
left_it = insert_new_arc(
site_arc, site_arc, site_event, right_it, output);
// If the site event is a segment, update its direction.
if (site_event.is_segment()) {
site_event.inverse();
}
// Add a candidate circle to the circle event queue.
// There could be only one new circle event formed by
// a new bisector and the one on the right.
activate_circle_event(site_event, right_it->first.left_site(),
right_it->first.right_site(), right_it);
right_it = left_it;
} else {
// The above arc corresponds neither to the first,
// nor to the last site in the beach line.
const site_event_type& site_arc2 = right_it->first.left_site();
const site_event_type& site3 = right_it->first.right_site();
// Remove the candidate circle from the event queue.
deactivate_circle_event(&right_it->second);
--left_it;
const site_event_type& site_arc1 = left_it->first.right_site();
const site_event_type& site1 = left_it->first.left_site();
// Insert new nodes into the beach line. Update the output.
beach_line_iterator new_node_it =
insert_new_arc(site_arc1, site_arc2, site_event, right_it, output);
// Add candidate circles to the circle event queue.
// There could be up to two circle events formed by
// a new bisector and the one on the left or right.
activate_circle_event(site1, site_arc1, site_event, new_node_it);
// If the site event is a segment, update its direction.
if (site_event.is_segment()) {
site_event.inverse();
}
activate_circle_event(site_event, site_arc2, site3, right_it);
right_it = new_node_it;
}
}
}
/*
* Add a new key entry to the keymap pointed to by current. Entry
* contains the character to add to the keymap, type is the type of
* entry to add (either multikey or leaf) and symbol is the symbolic
* value for a leaf type entry. The function returns a pointer to the
* new keymap entry.
*/
static key_entry_t *
add_new_key(keymap_t *current, char chr, int key_type, int symbol)
{
key_entry_t *the_key;
int i, ki;
#ifdef DEBUG
__CTRACE(__CTRACE_MISC,
"Adding character %s of type %d, symbol 0x%x\n",
unctrl(chr), key_type, symbol);
#endif
if (current->mapping[(unsigned char) chr] < 0) {
if (current->mapping[(unsigned char) chr] == MAPPING_UNUSED) {
/* first time for this char */
current->mapping[(unsigned char) chr] =
current->count; /* map new entry */
ki = current->count;
/* make sure we have room in the key array first */
if ((current->count & (KEYMAP_ALLOC_CHUNK - 1)) == 0)
{
if ((current->key =
realloc(current->key,
ki * sizeof(key_entry_t *)
+ KEYMAP_ALLOC_CHUNK * sizeof(key_entry_t *))) == NULL) {
fprintf(stderr,
"Could not malloc for key entry\n");
exit(1);
}
the_key = new_key();
for (i = 0; i < KEYMAP_ALLOC_CHUNK; i++) {
current->key[ki + i] = &the_key[i];
}
}
} else {
/* the mapping was used but freed, reuse it */
ki = - current->mapping[(unsigned char) chr];
current->mapping[(unsigned char) chr] = ki;
}
current->count++;
/* point at the current key array element to use */
the_key = current->key[ki];
the_key->type = key_type;
switch (key_type) {
case KEYMAP_MULTI:
/* need for next key */
#ifdef DEBUG
__CTRACE(__CTRACE_MISC, "Creating new keymap\n");
#endif
the_key->value.next = new_keymap();
the_key->enable = TRUE;
break;
case KEYMAP_LEAF:
/* the associated symbol for the key */
#ifdef DEBUG
__CTRACE(__CTRACE_MISC, "Adding leaf key\n");
#endif
the_key->value.symbol = symbol;
the_key->enable = TRUE;
break;
default:
fprintf(stderr, "add_new_key: bad type passed\n");
exit(1);
}
} else {
/* the key is already known - just return the address. */
#ifdef DEBUG
__CTRACE(__CTRACE_MISC, "Keymap already known\n");
#endif
the_key = current->key[current->mapping[(unsigned char) chr]];
}
return the_key;
}
