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source: GTP/trunk/App/Demos/Vis/FriendlyCulling/src/SampleGenerator.cpp @ 3247

Revision 3247, 5.0 KB checked in by mattausch, 15 years ago (diff)
worked on obj loader played around with ssao sampling

Line
1	#include "SampleGenerator.h"
2	#include "common.h"
3
4
5	using namespace std;
6	using namespace CHCDemoEngine;
7
8
9	SampleGenerator::SampleGenerator(int numSamples, float radius):
10	mNumSamples(numSamples), mRadius(radius)
11	{
12	mHalton = new HaltonSequence(2);
13	}
14
15
16	SampleGenerator::~SampleGenerator()
17	{
18	DEL_PTR(mHalton);
19	}
20
21
22	PoissonDiscSampleGenerator2D::PoissonDiscSampleGenerator2D(int numSamples, float radius):
23	SampleGenerator(numSamples, radius)
24	{}
25
26
27	void PoissonDiscSampleGenerator2D::Generate(float *samples) const
28	{
29	// Poisson disc sampling generator using relaxation
30	// dart-throwing as proposed by McCool et al.
31	// the min distance requirement is relaxed if we are not
32	// able to place any dart for a number of tries
33	// the solution is a possion sampling with respect
34	// to the adjusted min distance
35	// this sampling scheme has the benefit that it is hierarchical
36	int maxTries = 1000;
37	const float f_reduction = 0.95f;
38
39	float r[2];
40
41	// the maximal possible radius: our radius is a fraction of this radius
42	// this is used as a measure of the quality of distribution of the point samples
43	const float rmax = 2.0f * mRadius * sqrt(1.0f / (2.0f * sqrt(3.0f) * mNumSamples));
44
45	// generates poisson distribution on disc
46	// start with some thresholds: all samples lie on the circumference of circle
47
48	float minDist = 2.0f * rmax;
49	float sqrMinDist = minDist * minDist;
50
51	int tries = 0;
52
53	//cout << "minDist before= " << minDist << endl;
54	Sample2 s = (Sample2 )samples;
55
56	// check if on disc
57	for (int i = 0; i < mNumSamples; ++ i)
58	{
59	// repeat until valid sample was found
60	while (1)
61	{
62	// q: should we use halton or does it conflict with the poisson disc properties?
63	r[0] = RandomValue(0, 1); r[1] = RandomValue(0, 1);
64	//mHalton->GetNext(r);
65
66	// scale to -1 .. 1
67	const float rx = r[0] * 2.0f - 1.0f;
68	const float ry = r[1] * 2.0f - 1.0f;
69
70	// check if in disk, else exit early
71	const float distanceSquared = rx * rx + ry * ry;
72
73	if ((rx * rx + ry * ry > mRadius * mRadius)
74	// also avoid case that sample exactly in center
75	//\|\| (distanceSquared <= 1e-3f)
76	)
77	continue;
78
79	bool sampleValid = true;
80
81	// check poisson property
82	for (int j = 0; ((j < i) && sampleValid); ++ j)
83	{
84	const float dist =
85	(s[j].x - rx) * (s[j].x - rx) +
86	(s[j].y - ry) * (s[j].y - ry);
87
88	if (dist < sqrMinDist)
89	sampleValid = false;
90	}
91
92	if (sampleValid)
93	{
94	s[i].x = rx;
95	s[i].y = ry;
96	break;
97	}
98
99	++ tries;
100
101	if (tries > maxTries)
102	{
103	minDist *= f_reduction;
104	sqrMinDist = minDist * minDist;
105
106	maxTries += 1000;
107	}
108	}
109	}
110
111	//cout << "minDist after= " << (float)minDist / mNumSamples<< " #tries: " << tries << endl;
112	}
113
114
115	RandomSampleGenerator2D::RandomSampleGenerator2D(int numSamples, float radius):
116	SampleGenerator(numSamples, radius)
117	{}
118
119
120	void RandomSampleGenerator2D::Generate(float *samples) const
121	{
122	Sample2 s = (Sample2 )samples;
123
124	int numSamples = 0;
125
126	float r[2];
127
128	while (numSamples < mNumSamples)
129	{
130	mHalton->GetNext(r);
131
132	const float rx = r[0] * 2.0f - 1.0f;
133	const float ry = r[1] * 2.0f - 1.0f;
134
135	// check if in disk, else exit early
136	if (rx * rx + ry * ry > mRadius * mRadius)
137	continue;
138
139	s[numSamples].x = rx;
140	s[numSamples].y = ry;
141
142	++ numSamples;
143	}
144	}
145
146
147	SphericalSampleGenerator3D::SphericalSampleGenerator3D(int numSamples, float radius):
148	SampleGenerator(numSamples, radius)
149	{}
150
151
152	void SphericalSampleGenerator3D::Generate(float *samples) const
153	{
154	float r[2];
155	Sample3 s = (Sample3 )samples;
156
157	for (int i = 0; i < mNumSamples; ++ i)
158	{
159	r[0] = RandomValue(0, 1);
160	r[1] = RandomValue(0, 1);
161
162	// create stratified samples over sphere
163	const float theta = 2.0f * acos(sqrt(1.0f - r[0]));
164	const float phi = 2.0f * M_PI * r[1];
165
166	s[i].x = mRadius * sin(theta) * cos(phi);
167	s[i].y = mRadius * sin(theta) * sin(phi);
168	s[i].z = mRadius * cos(theta);
169	}
170	}
171
172
173	QuadraticDiscSampleGenerator2D::QuadraticDiscSampleGenerator2D(int numSamples, float radius):
174	//PoissonDiscSampleGenerator2D(numSamples, radius)
175	RandomSampleGenerator2D(numSamples, radius)
176	{}
177
178
179	void QuadraticDiscSampleGenerator2D::Generate(float *samples) const
180	{
181	#if 0
182	float r[2];
183	Sample2 s = (Sample2 )samples;
184
185	for (int i = 0; i < mNumSamples; ++ i)
186	{
187	mHalton->GetNext(r);
188
189	// create samples over disc: the sample density
190	// decreases quadratically with the distance to the origin
191	s[i].x = mRadius * r[1] * sin(2.0f * M_PI * r[0]);
192	s[i].y = mRadius * r[1] * cos(2.0f * M_PI * r[0]);
193	}
194	#else
195
196	//PoissonDiscSampleGenerator2D::Generate(samples);
197	RandomSampleGenerator2D::Generate(samples);
198
199	Sample2 s = (Sample2 )samples;
200
201	// multiply with lenght to get quadratic dependence on the distance
202	for (int i = 0; i < mNumSamples; ++ i)
203	{
204	Sample2 &spl = s[i];
205
206	float len = sqrt(spl.x * spl.x + spl.y * spl.y);
207	spl.x = len mRadius;
208	spl.y = len mRadius;
209	}
210	#endif
211	}

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