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traffic_agent_cycle_time.h @ 1134

Revision 1129, 10.5 kB (checked in by jabu, 15 years ago)

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1	#include "traffic_agent.cpp"
2	const string testMessage = "test_message";
3	const double measurement_cycle_time = 90; // s
4	const double saturated_stream = 0.5; // car/s
5	const int sample_cycles = 5;
6
7
8	class SignalGroup {
9	public:
10	string name;
11	Array <Lane*> lanes;
12	double green_time_ratio;
13	int average_queue_length;
14	string queue_name;
15	int cycle_counter;
16
17	SignalGroup () {
18	average_queue_length = 0;
19	}
20
21	void adapt() {
22	if ( (cycle_counter +1)% sample_cycles == 0 )
23	average_queue_length = 0;
24	}
25
26
27	int getSumCarsWaitingTime ( double time_cycle ) {
28	int q = average_queue_length/sample_cycles; // pomocna delka fronty - UPRAVIT - pocitat s vetsi nez prumernou?
29	int cars_per_green = time_cycle * green_time_ratio * lanes.length() * saturated_stream; // pocet aut ktere projedou na zelenou
30	int sum_cars_waiting_time = 0; // suma aut * cekacich casu
31	int i = 0; // iterator
32	while ( q > cars_per_green ) {
33	q -= cars_per_green;
34	sum_cars_waiting_time += q*time_cycle;
35	i ++;
36	}
37	// + zbytek fronty + prvni nezapocitana vlna
38	if ( i > 0 ) {
39	sum_cars_waiting_time += qtime_cycle + cars_per_green(1.0-green_time_ratio)time_cycle0,5;
40	//cout << "delsi fronta " << q << " ";
41	}
42
43	// pocet aut * stredni hodnota cekaci doby pri volne krizovatces
44	else {
45	sum_cars_waiting_time += (0.5(1.0-green_time_ratio))(time_cycle*q);
46	//cout << "kratsi fronta " << q << " ";
47	}
48
49	//cout << "signal group " << name << " tc " << time_cycle << " cekani " << sum_cars_waiting_time << " fronta " << average_queue_length << endl;
50
51	return sum_cars_waiting_time;
52	}
53
54	void addQueue( int q ) {
55
56	if ( q > 0 )
57	average_queue_length += q;
58	}
59
60
61	};
62
63	class TrafficAgentCycleTime : public BaseTrafficAgent {
64	public:
65	int Tc;
66	int minTc;
67	int maxTc;
68	int stepTc;
69	int idealTc;
70	static const int d_Tc = 3; // pocet navrhovanych delek cyklu
71	int cycle_counter;
72	int max_profit;
73	unsigned int n_of_broadcast;
74	Array <int> lane_sum;
75	Array <SignalGroup*> signal_groups;
76	Array <int> received_Tcs;
77	Array <int> received_profit_sum;
78
79	// POMOCNE FUNKCE
80
81	void printVector ( RV rv_vector, vec vector, string description ) {
82	cout << endl << description << " " << name << endl;
83	int k = 0;
84	for ( int i = 0; i < rv_vector.length(); i ++ ) {
85	cout << rv_vector.name(i) << " : ";
86	for ( int j = 0; j < rv_vector.size(i); j ++ ) {
87	cout << vector(k) << " ";
88	k ++;
89	}
90	cout << endl;
91	}
92	cout << endl;
93	}
94
95	void echo ( string message ) {
96	cout << name << " hlasi: " << message << endl;
97	}
98
99	unsigned int find_index ( RV rv_vector, string index_string ) {
100	for ( unsigned int i = 0; i < (int) rv_vector.length(); i ++) {
101	if ( rv_vector.name(i) == index_string )
102	return i;
103	}
104	return rv_vector.length();
105	}
106
107	unsigned int find_index ( Array <string> arr, string index_string ) {
108	for ( unsigned int i = 0; i < (int) arr.length(); i ++) {
109	if ( arr(i) == index_string )
110	return i;
111	}
112	return arr.length();
113	}
114
115	// VYPOCETNI FUNKCE
116
117	int getSumCarsWaitingTime ( double time_cycle ) {
118	int sum = 0;
119	SignalGroup * sg;
120	for ( int i = 0; i < signal_groups.length(); i ++ ) {
121	sg = signal_groups(i);
122	sum += sg->getSumCarsWaitingTime( time_cycle );
123	}
124	return sum;
125	}
126
127	int getQueue () {
128	int queue = 0;
129	SignalGroup *sg;
130	for ( int i = 0; i < signal_groups.length(); i ++ ) {
131	sg = signal_groups(i);
132	queue += sg->average_queue_length;
133	}
134	return queue;
135	}
136
137	// NEPOUZIVAT?
138	//int getIdealTc() {
139	// int min_waiting_time = getSumCarsWaitingTime(Tc);
140	// int waiting_time;
141	// int idealTc = Tc;
142	// cout << name << " Tc wt" << endl;
143	// for ( int t_c = Tc - 2stepTc; t_c <= Tc + 2stepTc; t_c += stepTc ) {
144	// waiting_time = getSumCarsWaitingTime(t_c);
145	// cout << t_c << " " << waiting_time << endl;
146	// if ( waiting_time < min_waiting_time ) {
147	// min_waiting_time = waiting_time;
148	// idealTc = t_c;
149	// }
150	// }
151	// cout << "IDEAL " << idealTc << endl;
152	// return idealTc;
153	//}
154
155	int getIdealTc() {
156
157	}
158
159
160	void send2neighbour( Setting &set, int i, string messageName, double messageValue ) {
161	if ( i < neighbours.length() ) {
162	Setting &msg =set.add(Setting::TypeGroup);
163	UI::save( neighbours(i), msg, "to" );
164	UI::save (name,msg,"from");
165	UI::save( messageName, msg, "what" );
166	UI::save( messageValue, msg, "value" );
167	}
168	else {
169	//throw new Exception("soused "+((string)i)+" neexistuje");
170	//cout << endl << endl << "soused " << i << mimo
171	std::stringstream out;
172	out << "soused " << i << " neexistuje";
173	//throw out.str();
174	cout << out.str();
175	}
176	}
177
178	void send2allNeighbours ( Setting &set, string messageName, double messageValue ) {
179	for ( int i = 0; i < neighbours.length(); i++ ) {
180	send2neighbour( set, i, messageName, messageValue );
181	}
182	}
183
184	int getProfit( int time_cycle ) {
185	if ( Tc != time_cycle )
186	return getSumCarsWaitingTime( Tc ) - getSumCarsWaitingTime ( time_cycle );
187	else
188	return 0;
189	}
190
191
192	// FUNKCE VOLANE V main_loop NA ZACATKU
193	void from_setting( Setting &set ) {
194	BaseTrafficAgent::from_setting(set);
195	//TrafficAgentCycleTime::Tc = 80;
196	}
197
198	void validate (){
199	rv_action = RV("Tc",1);
200	rv_action.add( RV( stage_names, ones_i(stage_names.length()) ) );
201	Tc = 80;
202	minTc = 60;
203	maxTc = 120;
204	stepTc = 5;
205	max_profit = 0;
206	received_profit_sum.set_length( 2*d_Tc +1 );
207	received_Tcs.set_length( 2*d_Tc +1 );
208	cycle_counter = 0;
209
210	BaseTrafficAgent::validate();
211	// inicializace signalnich skupin
212	for ( int i = 0; i < lanes.length(); i ++ ) {
213	Lane * l = & lanes(i);
214	int sg_index = -1;
215	for ( int j = 0; j < signal_groups.length(); j ++ ) {
216	SignalGroup * sg;
217	sg = signal_groups(j);
218	if ( sg->name == l->sg )
219	sg_index = j;
220	}
221	SignalGroup * sg;
222	if ( sg_index >= 0 ) {
223	sg = signal_groups(sg_index);
224	}
225	else {
226	sg = new SignalGroup();
227	sg->name = l->sg;
228	sg->average_queue_length = 0;
229	signal_groups.set_size( signal_groups.length()+1, true );
230	signal_groups(signal_groups.length()-1) = sg;
231	}
232	sg->lanes.set_size(sg->lanes.length()+1, true);
233	sg->lanes(sg->lanes.length()-1) = l;
234	}
235	}
236
237	// FUNKCE VOLANE V main_loop V KAZDEM CYKLU
238
239	void adapt (const vec &glob_dt) {
240	// inicializes vars of cycle of broadcast
241	n_of_broadcast = 0;
242	max_profit = 0;
243	idealTc = Tc;
244
245	for ( int i = 0; i < signal_groups.length(); i ++ ) {
246	signal_groups(i)->adapt();
247	}
248
249	for ( int i = 0; i < received_profit_sum.length(); i++ ) {
250	received_profit_sum(i) = 0;
251	}
252
253	// nacteni dat do signalnich skupin
254	cout << endl << cycle_counter << " SG " << (cycle_counter%sample_cycles +1) << endl;
255	for ( int i = 0; i < rv_queues.length(); i ++ ) {
256	SignalGroup * sg;
257	sg = signal_groups(i);
258	sg->queue_name = rv_queues.name(i);
259	sg->addQueue(queues(i));
260	sg->green_time_ratio = green_times(i);
261	sg->cycle_counter = cycle_counter;
262	//cout << sg->name << " " << sg->getSumCarsWaitingTime(Tc) << " " << sg->average_queue_length << " " << sg->green_time_ratio*Tc << " " << sg->getTime2zeroQue() << endl;
263	cout << sg->name << " " << queues(i) << " " << sg->average_queue_length << " " << sg->average_queue_length / (cycle_counter%sample_cycles +1) << endl;
264	}
265
266	//suggestedTc = idealTc = getIdealTc();
267
268	//cout << endl << "CELKOVA FRONTA " << name << " " << getQueue() << endl;
269
270	BaseTrafficAgent::adapt(glob_dt);
271	}
272
273	void broadcast(Setting &set){
274
275	// 1. cycle of communication
276	// sends all tcs in range +- d_tc and expected profits according to tc
277	// format: tc_index, profit_index
278	if ( n_of_broadcast == 0 && ( cycle_counter % sample_cycles == 0 ) ) {
279	for ( int i = -d_Tc; i <= d_Tc; i++ ) {
280	int time_cycle = Tc + i*stepTc;
281	int profit = getProfit(time_cycle);
282
283	// send tc
284	stringstream time_cycle_stream;
285	time_cycle_stream << "tc_" << (i+d_Tc);
286	send2allNeighbours( set, time_cycle_stream.str(), time_cycle);
287
288	// send profit
289	stringstream profit_stream;
290	profit_stream << "profit_" << (i+d_Tc);
291	send2allNeighbours( set, profit_stream.str(), profit );
292
293	//cout << name << " tc " << time_cycle << " profit " << profit << " cekani " << getSumCarsWaitingTime(time_cycle) << endl;
294	}
295	//cout << endl;
296	}
297
298	n_of_broadcast ++;
299	}
300
301	void receive(const Setting& msg){
302	string what;
303	string from;
304	double val;
305	UI::get(what, msg, "what", UI::compulsory);
306	UI::get(from, msg, "from", UI::compulsory);
307	UI::get(val, msg, "value");
308
309	//cout << name << " receiving from " << from << " " << what << " : " << val<<endl;
310	if ( n_of_broadcast == 1 ) {
311	if ( what.substr(0,2) == "tc" ) {
312	istringstream tc_i( what.substr(3, what.length()-3) );
313	int index;
314	tc_i >> index;
315	received_Tcs( index ) = val;
316	//cout << "tc " << val << endl;
317	}
318	if ( what.substr(0,6) == "profit" ) {
319	istringstream profiti( what.substr(7, what.length()-7) );
320	int index;
321	profiti >> index;
322	received_profit_sum( index ) = received_profit_sum( index ) + val;
323	//cout << "profit " << val << endl;
324	}
325	}
326
327	if ( what == "new_stable_state" ) {
328	//echo("new_stable_state");
329	BaseTrafficAgent::receive(msg);
330	}
331
332	}
333
334	void act (vec &glob_ut){
335	if ( cycle_counter % sample_cycles == 0 ) {
336	// choose tc with max profit
337	for ( int i = 0; i < received_profit_sum.length(); i ++ ) {
338	int time_cycle = received_Tcs(i);
339	int profit = received_profit_sum(i) + getProfit(time_cycle);
340	if ( profit > max_profit ) {
341	max_profit = profit;
342	idealTc = time_cycle;
343	//cout << name << " idealni Tc " << time_cycle << " s celkovym ziskem " << profit << endl;
344	}
345	}
346	//cout << endl << name << " nastevuje TC na " << idealTc << endl;
347	Tc = idealTc;
348
349
350	// nastaveni delky cyklu na Tc
351	vec action;
352	action.set_size(rv_action._dsize());
353	int st;
354	int stage_time_sum = 0; // soucet delky fazi
355	action(find_index(rv_action, "Tc")) = Tc;
356	for ( int i =0; i < stage_names.length(); i ++) {
357	if ( (i+1) < stage_names.length() ) {
358	st = (stage_times(i)/80)*Tc;
359	stage_time_sum += st;
360	action(find_index(rv_action, stage_names(i))) = st;
361	}
362	else // dopocitani posledni faze - oprava zaokrouhlovaci chyby
363	action(find_index(rv_action, stage_names(i))) = Tc - stage_time_sum;
364	}
365	action2ds.filldown(action,glob_ut);
366	}
367	cycle_counter ++;
368	}
369
370
371	};
372	UIREGISTER(TrafficAgentCycleTime);

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