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foraminifera.inc @ 1152

Last change on this file since 1152 was 1152, checked in by Maciej Komosinski, 3 years ago
Foraminifera show has now smaller world compared to expdef (and adjusted other parameters), so it is better suited for visualization and demonstration
File size: 9.2 KB

Rev	Line
[401]	1
[559]	2	function create_genotype(proculus_size, number_of_chambers, rgbstring, lastchambergrowth) //lastchambergrowth is 0..1
[557]	3	{
[847]	4	const shift = 0.7;
	5	const angle_delta = 0.8;
	6	const angle_delta_delta = -0.01;
	7	const growing = 1.07; //7% growth
	8
[1074]	9	var str = "//0s\nm:Vstyle=foram\n";
[847]	10	var size = proculus_size;
	11	for(var i = 0; i < number_of_chambers; i++)
[557]	12	{
[847]	13	var effectivesize = size; //'effectivesize' is introduced only to consider the last chamber
	14	if (i == number_of_chambers - 1) //last chamber
[559]	15	{
[847]	16	effectivesize *= lastchambergrowth;
	17	size = size * (1.35 - 0.35 * lastchambergrowth); //last iteration: 'size' is only used for shifting (dx). The last chamber emerges at the surface of the previous one
	18	if (lastchambergrowth < 1)
	19	rgbstring = "0.9,0.9,0.9,i=\"growing=%g\"" % lastchambergrowth; //when the last chamber is growing, make it bright gray and add extra information in its "i" field
[559]	20	}
[1152]	21	effectivesize = Math.max(effectivesize, MIN_PART_SIZE);
[567]	22	str += "p:sh=1,sx=%g,sy=%g,sz=%g,rz=3.14159265358979,vr=%s\n" % effectivesize % effectivesize % effectivesize % rgbstring;
[847]	23	if (i > 0)
	24	str += "j:%d,%d,sh=1,dx=%g,rz=%g\n" % (i - 1) % i % (size * shift) % (angle_delta + i * angle_delta_delta);
	25	size *= growing;
[557]	26	}
	27	return str;
	28	}
	29
[422]	30	function setGenotype(mode)
	31	{
[554]	32	if (mode->opt == "growth")
[422]	33	{
[554]	34	mode->cr.data->genes = mode->parent_genes;
	35	mode->cr.data->lifeparams = mode->parent_lifeparams;
[422]	36	}
[554]	37
	38	else if (mode->opt == "birth")
[422]	39	{
[567]	40	foram_uid += 1;
[847]	41	var new_id = "c" + string(foram_uid);
[554]	42	mode->cr.data->genes = String.deserialize(String.serialize(mode->genes));
[847]	43	mode->cr.data->lifeparams = {"max_energy_level" : mode->energy0, "gen" : mode->gen, "hibernated" : 0, "species" : mode->species, "reproduce" : 0, "dir" : randomDir(), "dir_counter" : Math.random(int(secToSimSteps(ExpProperties.dir_change_sec))), "chamber_growth" : -1, "division_time" : -1, "uid" : new_id};
[554]	44
[567]	45	var oper = "cloning";
[573]	46	var inherit = [1.0];
[567]	47	if (mode->parentsuids.size > 1)
[847]	48	{
[567]	49	oper = "cross-over";
[573]	50	inherit = [0.5, 0.5];
[567]	51	}
[847]	52
	53	var dict = {"Time": Simulator.stepNumber, "FromIDs": mode->parentsuids, "ID": new_id, "Inherited": inherit, "Operation": oper, "Kind" : mode->gen};
[1100]	54	if (ExpProperties.print_evol_progress == 1)
[1098]	55	Simulator.print("[OFFSPRING] " + String.serialize(dict));
[422]	56	}
	57	}
	58
[567]	59	function getEnergy0(radius)
	60	{
[847]	61	return energyFromVolume(micronsToFrams(radius), 1);
[567]	62	}
	63
[479]	64	function gametsDivision(parent_energy, energy0)
	65	{
	66	var number = 1;
	67	var result = parent_energy;
[847]	68	while ((result - ExpProperties.divisionCost) >= energy0)
[479]	69	{
[847]	70	result = (result - ExpProperties.divisionCost) / 2;
[567]	71	number *= 2;
[479]	72	}
	73	//Simulator.print("parent: " + parent_energy + " result: " + result + " number " + number);
	74	return {"energy" : result, "number" : number};
	75	}
	76
[422]	77	function reproduce_haploid(parent, parent2, clone)
[847]	78	{
[476]	79	var number, energy0, new_genes, gen;
[422]	80	if (clone == 1)
	81	{
[847]	82	var offspring = gametsDivision(parent.energy, getEnergy0(getGene(parent, "energies0", 0)[0]));
[479]	83	energy0 = offspring->energy;
	84	number = offspring->number;
[476]	85	new_genes = parent.data->genes;
	86	parent.data->lifeparams->gen = 1 - parent.data->lifeparams->gen; //because of reversal of "gen" in createOffspring function
	87	gen = parent.data->lifeparams->gen;
[422]	88	}
	89	else
	90	{
[847]	91	var offspring1 = gametsDivision(parent.energy, getEnergy0(getGene(parent, "energies0", 0)[1]));
	92	var offspring2 = gametsDivision(parent2.energy, getEnergy0(getGene(parent2, "energies0", 0)[1]));
	93	energy0 = (offspring1->energy + offspring2->energy);
	94	number = ExpProperties.gametSuccessRate * (offspring1->number + offspring2->number) / 2;
[476]	95	new_genes = [parent.data->genes, parent2.data->genes];
	96	gen = 1 - parent.data->lifeparams->gen;
[493]	97
	98	if (ExpProperties.logging == 1)
	99	{
[847]	100	log(createLogVector(parent, parent.energy), ExpProperties.logPref + "repro_energies_log.txt");
	101	log(createLogVector(parent2, parent2.energy), ExpProperties.logPref + "repro_energies_log.txt");
	102	log(createLogVector(parent, number), ExpProperties.logPref + "repro_num_log.txt");
	103	log(createLogVector(parent, parent.lifespan), ExpProperties.logPref + "lifespan_log.txt");
	104	log(createLogVector(parent2, parent2.lifespan), ExpProperties.logPref + "lifespan_log.txt");
	105	}
[422]	106	}
	107
[567]	108	//Simulator.print("haploid number of offspring: " + number + " energ0: " + energy0);
[422]	109
[418]	110	for (var j = 0; j < number; j++)
[401]	111	{
[567]	112	createOffspring(create_genotype(ExpProperties.chamber_proculus_diplo, 1, colors[1], 1), energy0, new_genes, parent.data->lifeparams, [parent.data->lifeparams->uid, parent2.data->lifeparams->uid]);
[401]	113	}
	114	}
	115
[418]	116	function reproduce_diploid(parent)
[401]	117	{
[847]	118	var offspring = gametsDivision(parent.energy, getEnergy0(getGene(parent, "energies0", 0)[0]));
	119	var energy0 = offspring->energy;
[510]	120	var number = offspring->number;
[422]	121
[847]	122	if (ExpProperties.logging == 1)
	123	{
	124	log(createLogVector(parent, parent.energy), ExpProperties.logPref + "repro_energies_log.txt");
	125	log(createLogVector(parent, number), ExpProperties.logPref + "repro_num_log.txt");
	126	log(createLogVector(parent, parent.lifespan), ExpProperties.logPref + "lifespan_log.txt");
	127	}
[493]	128
[567]	129	//Simulator.print("diploid number of offspring: " + number+ " energ0: " + energy0);
[422]	130
[418]	131	for (var j = 0; j < number / 2; j++)
[401]	132	{
[418]	133	var crossed = 0;
	134	//crossover
[486]	135	if (Math.rnd01 < ExpProperties.crossprob)
[418]	136	{
[422]	137	crossover(parent, "min_repro_energies");
[418]	138	crossed = 1;
	139	}
[401]	140
[418]	141	for (var k = 0; k < 2; k++)
[404]	142	{
[847]	143	createOffspring(create_genotype(ExpProperties.chamber_proculus_haplo, 1, colors[0], 1), energy0, parent.data->genes[0], parent.data->lifeparams, [parent.data->lifeparams->uid]);
[404]	144	}
	145
[418]	146	//reverse of crossover for fossilization
	147	if (crossed == 1)
[401]	148	{
[422]	149	crossover(parent, "min_repro_energies");
[418]	150	crossed = 0;
[401]	151	}
[847]	152
[401]	153	}
[404]	154	}
	155
[422]	156	function reproduce_parents(species)
[404]	157	{
[847]	158	var parent1 = null;
	159	var parent2 = null;
	160	var pop = Populations[0];
	161	for (var i = pop.size - 1; i >= 0; i--)
	162	{
	163	if (pop[i].data->lifeparams->reproduce == 1 && pop[i].data->lifeparams->species == species)
[401]	164	{
[847]	165	if ((pop[i].data->lifeparams->gen == 1) \|\| ((pop[i].data->lifeparams->gen == 0) && ExpProperties.stress == 0))
	166	{
	167	continue;
	168	}
	169	else if (parent1 == null)
	170	{
	171	parent1 = pop[i];
	172	}
	173	else if (parent2 == null)
	174	{
	175	parent2 = pop[i];
	176	}
	177	if (parent1 != null && parent2 != null)
	178	{
	179	//when parents are ready for reproduction start gametogenesis
	180	if (parent1.data->lifeparams->division_time == -1 && parent2.data->lifeparams->division_time == -1)
[401]	181	{
[847]	182	var time = int(secToSimSteps(ExpProperties.gametoPeriodSec));
	183	parent1.data->lifeparams->division_time = time;
	184	parent2.data->lifeparams->division_time = time;
	185	parent1.idleen = 0;
	186	parent2.idleen = 0;
	187	//Simulator.print("parents "+parent1.uid + " " + parent2.uid + " ready to repro: "+Simulator.stepNumber);
[401]	188	}
[847]	189	//when gametogenesis is finished fuse gamets
	190	else if (parent1.data->lifeparams->division_time == 0 && parent2.data->lifeparams->division_time == 0)
[401]	191	{
[847]	192	reproduce_haploid(parent1, parent2, 0);
	193	//print_repro_info(parent1);
	194	//print_repro_info(parent2);
	195	pop.kill(parent1);
	196	pop.kill(parent2);
	197	parent1 = null;
	198	parent2 = null;
[401]	199	}
[847]	200	}
[401]	201	}
[847]	202	}
[422]	203	}
	204
	205	function readyToRepro(cr)
	206	{
	207	var reproduced = 1;
[567]	208
[476]	209	if (cr.data->lifeparams->gen == 1)
[422]	210	{
	211	reproduce_diploid(cr);
[401]	212	}
	213
[486]	214	else if (ExpProperties.stress == 0)
[401]	215	{
[422]	216	reproduce_haploid(cr, null, 1);
	217	}
	218
	219	else
	220	{
	221	if (cr.signals.size == 0)
[401]	222	{
[847]	223	cr.signals.add("repro" + cr.data->lifeparams->species);
[422]	224	cr.signals[0].power = 1;
[401]	225	}
[422]	226	reproduced = 0;
[476]	227	cr.data->lifeparams->reproduce = 1;
[401]	228	}
[422]	229
	230	if (reproduced == 1)
	231	{
[567]	232	//print_repro_info(cr);
[422]	233	Populations[0].kill(cr);
	234	}
	235
	236	return reproduced;
[401]	237	}
	238
[422]	239	function foramReproduce(cr)
	240	{
[847]	241	var properEnergy = cr.energy >= getGene(cr, "min_repro_energies", 0)[cr.data->lifeparams->gen];
	242	var reproduced = 0;
[422]	243
	244	//if creature has proper energy
[590]	245	if ( properEnergy )
[422]	246	{
	247	//reproduce with probability repro_prob
[486]	248	if (Math.rnd01 <= ExpProperties.repro_prob) //TODO env trigger
[421]	249	{
[422]	250	reproduced = readyToRepro(cr);
[421]	251	}
[847]	252	else if (cr.signals.receive("repro" + cr.data->lifeparams->species) > 0)
[421]	253	{
[422]	254	reproduced = readyToRepro(cr);
[421]	255	}
[422]	256	if (reproduced == 1)
[847]	257	return 1;
[421]	258	}
	259
[422]	260	else if (!properEnergy)
[421]	261	{
[422]	262	cr.signals.clear();
[847]	263	cr.data->lifeparams->reproduce = 0;
[421]	264	}
[430]	265
	266	return 0;
[422]	267	}
[421]	268
[422]	269	function crossover(parent, gene)
	270	{
[476]	271	var tmp = parent.data->genes[0][gene];
	272	parent.data->genes[0][gene] = parent.data->genes[1][gene];
	273	parent.data->genes[1][gene] = tmp;
[422]	274	}
[421]	275
[567]	276	function createOffspring(geno, energy, parent_genes, parent_lifeparams, parentsuids)
[422]	277	{
[847]	278	curColor = colors[1 - parent_lifeparams->gen];
	279	var cr = createAndRotate(geno, 0, 2 * Math.pi, 0);
[422]	280	cr.energy0 = energy;
	281	cr.energy = cr.energy0;
[567]	282	setGenotype({"opt" : "birth", "cr" : cr, "gen" : 1 - parent_lifeparams->gen, "species" : parent_lifeparams->species, "energy0" : cr.energy0, "genes" : parent_genes, "parentsuids" : parentsuids});
[422]	283	placeRandomlyNotColliding(cr);
[421]	284	}
[567]	285
	286	function print_repro_info(cr)
	287	{
[1100]	288	if (ExpProperties.print_evol_progress == 1)
[1098]	289	Simulator.print("Reproduced " + cr.data->lifeparams->gen + " of species " + cr.data->lifeparams->species + " energy: " + cr.energy);
[567]	290	}

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