//
// Lol Engine — Voronoi diagram tutorial
//
// Copyright © 2015—2019 Sam Hocevar <sam@hocevar.net>
// © 2011—2015 Benjamin “Touky” Huet <huet.benjamin@gmail.com>
//
// Lol Engine is free software. It comes without any warranty, to
// the extent permitted by applicable law. You can redistribute it
// and/or modify it under the terms of the Do What the Fuck You Want
// to Public License, Version 2, as published by the WTFPL Task Force.
// See http://www.wtfpl.net/ for more details.
//
#if HAVE_CONFIG_H
# include "config.h"
#endif
#include <memory>
#include <lol/engine.h>
#include "loldebug.h"
using namespace lol;
LOLFX_RESOURCE_DECLARE(12_voronoi);
LOLFX_RESOURCE_DECLARE(12_voronoi_setup);
LOLFX_RESOURCE_DECLARE(12_voronoi_distance);
LOLFX_RESOURCE_DECLARE(12_distance);
LOLFX_RESOURCE_DECLARE(12_texture_to_screen);
enum FboType
{
SrcVoronoiFbo,
VoronoiFbo,
DistanceVoronoiFbo,
DistanceFbo,
MaxFboType
};
class Voronoi : public WorldEntity
{
public:
Voronoi()
{
m_vertices << vec2( 1.0, 1.0);
m_vertices << vec2(-1.0, -1.0);
m_vertices << vec2( 1.0, -1.0);
m_vertices << vec2(-1.0, -1.0);
m_vertices << vec2( 1.0, 1.0);
m_vertices << vec2(-1.0, 1.0);
m_ready = false;
m_cur_fbo = 0;
m_time = .0f;
m_timer = -1.0f;
mode = 0;
}
virtual void tick_game(float seconds)
{
WorldEntity::tick_game(seconds);
auto keyboard = input::keyboard();
// Shutdown logic
if (keyboard->key_released(input::key::SC_Escape))
Ticker::Shutdown();
m_time += seconds;
m_hotspot = 0.4f * vec3((float)lol::sin(m_time * 4.0) + (float)lol::cos(m_time * 5.3),
(float)lol::sin(m_time * 5.7) + (float)lol::cos(m_time * 4.4),
(float)lol::sin(m_time * 5.0));
m_color = 0.25f * vec3(1.1f + (float)lol::sin(m_time * 2.5 + 1.0),
1.1f + (float)lol::sin(m_time * 2.8 + 1.3),
1.1f + (float)lol::sin(m_time * 2.7));
/* Saturate dot color */
float x = std::max(m_color.x, std::max(m_color.y, m_color.z));
m_color /= x;
}
virtual void tick_draw(float seconds, Scene &scene)
{
WorldEntity::tick_draw(seconds, scene);
if (!m_ready)
{
m_vdecl = std::make_shared<VertexDeclaration>(VertexStream<vec2>(VertexUsage::Position));
m_vbo = std::make_shared<VertexBuffer>(m_vertices.bytes());
m_vbo->set_data(m_vertices.data(), m_vertices.bytes());
m_screen_shader = Shader::Create(LOLFX_RESOURCE_NAME(12_texture_to_screen));
m_screen_coord = m_screen_shader->GetAttribLocation(VertexUsage::Position, 0);
m_screen_texture = m_screen_shader->GetUniformLocation("u_texture");
for (int i = 0; i < MaxFboType; ++i)
{
m_fbos.push(std::make_shared<Framebuffer>(Video::GetSize()), 0, array<ShaderUniform>(), array<ShaderAttrib>() );
if (i == SrcVoronoiFbo)
{
m_fbos[i].m2 = Shader::Create(LOLFX_RESOURCE_NAME(12_voronoi_setup));
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_texture");
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_source_point");
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_screen_res");
m_fbos[i].m4 << m_fbos[i].m2->GetAttribLocation(VertexUsage::Position, 0);
}
else if (i == VoronoiFbo)
{
m_fbos[i].m2 = Shader::Create(LOLFX_RESOURCE_NAME(12_voronoi));
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_texture");
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_step");
m_fbos[i].m3 << m_fbos[i].m2->GetUniformLocation("u_screen_res");
m_fbos[i].m4 << m_fbos[i].m2->GetAttribLocation(VertexUsage::Position, 0);
}
else if (i == DistanceVoronoiFbo)
{
m_fbos[i].m2 = Shader::Create(LOLFX_RESOURCE_NAME(12_voronoi_distance));
}
else if (i == DistanceFbo)
{
m_fbos[i].m2 = Shader::Create(LOLFX_RESOURCE_NAME(12_distance));
}
m_fbos.last().m1->Bind();
{
render_context rc(scene.get_renderer());
rc.clear_color(vec4(0.f, 0.f, 0.f, 1.f));
rc.clear_depth(1.f);
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
}
m_fbos.last().m1->Unbind();
}
temp_buffer = std::make_shared<Framebuffer>(Video::GetSize());
temp_buffer->Bind();
{
render_context rc(scene.get_renderer());
rc.clear_color(vec4(0.f, 0.f, 0.f, 1.f));
rc.clear_depth(1.f);
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
}
temp_buffer->Unbind();
m_ready = true;
/* FIXME: this object never cleans up */
//SRC SETUP
m_cur_fbo = VoronoiFbo;
}
auto keyboard = input::keyboard();
if (keyboard->key_released(input::key::SC_O))
voronoi_points.pop();
else if (keyboard->key_released(input::key::SC_P))
voronoi_points.push(vec3(rand<float>(512.f), rand<float>(512.f), .0f),
vec2(64.f + rand<float>(64.f), 64.f + rand<float>(64.f)));
else if (keyboard->key_released(input::key::SC_F1))
m_cur_fbo = SrcVoronoiFbo;
else if (keyboard->key_released(input::key::SC_F2))
m_cur_fbo = VoronoiFbo;
else if (keyboard->key_released(input::key::SC_F3))
{
voronoi_points.clear();
if (mode == 0)
{
int i = 4;
while (i-- > 0)
voronoi_points.push(vec3(rand<float>(512.f), rand<float>(512.f), .0f),
vec2(64.f + rand<float>(64.f), 64.f + rand<float>(64.f))
//vec2::zero
);
mode = 1;
}
else
{
mode = 0;
}
}
if (mode == 0)
{
voronoi_points.clear();
int maxi = 6;
for (int i = 0; i < maxi; ++i)
{
float mi = (float)maxi;
float j = (float)i;
float f_time = (float)m_time;
voronoi_points.push(vec3(256.f) + 196.f * vec3(lol::cos( f_time + j * 2.f * F_PI / mi), lol::sin( f_time + j * 2.f * F_PI / mi), .0f), vec2(.0f));
voronoi_points.push(vec3(256.f) + 128.f * vec3(lol::cos(-f_time + j * 2.f * F_PI / mi), lol::sin(-f_time + j * 2.f * F_PI / mi), .0f), vec2(.0f));
voronoi_points.push(vec3(256.f) + 64.f * vec3(lol::cos( f_time + j * 2.f * F_PI / mi), lol::sin( f_time + j * 2.f * F_PI / mi), .0f), vec2(.0f));
voronoi_points.push(vec3(256.f) + 32.f * vec3(lol::cos(-f_time + j * 2.f * F_PI / mi), lol::sin(-f_time + j * 2.f * F_PI / mi), .0f), vec2(.0f));
}
voronoi_points.push(vec3(256.f), vec2(0.f));
}
temp_buffer->Bind();
{
render_context rc(scene.get_renderer());
rc.clear_color(vec4(0.f, 0.f, 0.f, 1.f));
rc.clear_depth(1.f);
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
}
temp_buffer->Unbind();
{
vec2 limit(1.f, 511.f);
//SRC SETUP
for (int j = 0; j < voronoi_points.count(); ++j)
{
voronoi_points[j].m1 = vec3(voronoi_points[j].m1.xy + voronoi_points[j].m2 * seconds, voronoi_points[j].m1.z);
if (voronoi_points[j].m1.x >= limit.y || voronoi_points[j].m1.x <= limit.x)
{
voronoi_points[j].m2.x *= -1.f;
voronoi_points[j].m1.x = clamp(voronoi_points[j].m1.x, limit.x, limit.y);
}
if (voronoi_points[j].m1.y >= limit.y || voronoi_points[j].m1.y <= limit.x)
{
voronoi_points[j].m2.y *= -1.f;
voronoi_points[j].m1.y = clamp(voronoi_points[j].m1.y, limit.x, limit.y);
}
voronoi_points[j].m1.z = ((float)j + 1) / ((float)voronoi_points.count());
}
int f = SrcVoronoiFbo;
m_fbos[f].m1->Bind();
{
render_context rc(scene.get_renderer());
rc.clear_color(vec4(0.f, 0.f, 0.f, 1.f));
rc.clear_depth(1.f);
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
}
m_fbos[f].m1->Unbind();
int buf = voronoi_points.count() % 2;
for (int j = 0; j < voronoi_points.count(); ++j)
{
std::shared_ptr<Framebuffer> dst_buf, src_buf;
if (buf)
{
dst_buf = m_fbos[f].m1;
src_buf = temp_buffer;
}
else
{
src_buf = m_fbos[f].m1;
dst_buf = temp_buffer;
}
dst_buf->Bind();
/* FIXME: we should just disable depth test in the shader */
scene.get_renderer()->clear(ClearMask::Depth);
m_fbos[f].m2->Bind();
int i = 0;
m_fbos[f].m2->SetUniform(m_fbos[f].m3[i++], src_buf->GetTextureUniform(), 0); //"u_texture"
m_fbos[f].m2->SetUniform(m_fbos[f].m3[i++], voronoi_points[j].m1); //"u_source_point"
m_fbos[f].m2->SetUniform(m_fbos[f].m3[i++], vec2(512.f, 512.f)); //"u_screen_res"
m_vdecl->Bind();
m_vdecl->SetStream(m_vbo, m_fbos[f].m4.last());
m_vdecl->DrawElements(MeshPrimitive::Triangles, 0, 6);
m_vdecl->Unbind();
m_fbos[f].m2->Unbind();
dst_buf->Unbind();
buf = 1 - buf;
}
}
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
//FRAME BUFFER DRAW
m_timer -= seconds;
if (m_timer < .0f && m_cur_fbo != SrcVoronoiFbo)
{
//m_timer = 1.0f;
m_fbos[m_cur_fbo].m1->Bind();
{
render_context rc(scene.get_renderer());
rc.clear_color(vec4(0.f, 0.f, 0.f, 1.f));
rc.clear_depth(1.f);
scene.get_renderer()->clear(ClearMask::Color | ClearMask::Depth);
}
m_fbos[m_cur_fbo].m1->Unbind();
ivec2 curres = ivec2(512, 512) / 2;
int buf = 0;
while (1)
{
std::shared_ptr<Framebuffer> dst_buf, src_buf;
std::shared_ptr<Shader> shader;
if (curres == ivec2::zero)
shader = m_screen_shader;
else
shader = m_fbos[m_cur_fbo].m2;
if (curres.x == 256)
src_buf = m_fbos[SrcVoronoiFbo].m1;
else if (buf)
src_buf = m_fbos[m_cur_fbo].m1;
else
src_buf = temp_buffer;
if (buf)
dst_buf = temp_buffer;
else
dst_buf = m_fbos[m_cur_fbo].m1;
dst_buf->Bind();
/* FIXME: we should just disable depth test in the shader */
scene.get_renderer()->clear(ClearMask::Depth);
shader->Bind();
int i = 0;
if (curres == ivec2::zero)
m_screen_shader->SetUniform(m_screen_texture, src_buf->GetTextureUniform(), 0);
else if (m_cur_fbo == VoronoiFbo)
{
shader->SetUniform(m_fbos[m_cur_fbo].m3[i++], src_buf->GetTextureUniform(), 0); //"u_texture"
shader->SetUniform(m_fbos[m_cur_fbo].m3[i++], ((float)curres.x) / 512.f); //"u_step"
shader->SetUniform(m_fbos[m_cur_fbo].m3[i++], vec2(512.f, 512.f)); //"u_screen_res"
}
m_vdecl->Bind();
m_vdecl->SetStream(m_vbo, m_fbos[m_cur_fbo].m4.last());
m_vdecl->DrawElements(MeshPrimitive::Triangles, 0, 6);
m_vdecl->Unbind();
m_fbos[m_cur_fbo].m2->Unbind();
dst_buf->Unbind();
if (curres == ivec2::zero)
break;
if (curres == ivec2(1))
{
if (buf == 1)
curres = ivec2::zero;
else
break;
}
buf = 1 - buf;
curres /= 2;
}
}
//SCREEN DRAW
m_screen_shader->Bind();
m_screen_shader->SetUniform(m_screen_texture, m_fbos[m_cur_fbo].m1->GetTextureUniform(), 0);
m_vdecl->Bind();
m_vdecl->SetStream(m_vbo, m_screen_coord);
m_vdecl->DrawElements(MeshPrimitive::Triangles, 0, 6);
m_vdecl->Unbind();
m_screen_shader->Unbind();
}
private:
array<vec3, vec2> voronoi_points;
array<vec2> m_vertices;
std::shared_ptr<Shader> m_screen_shader;
ShaderAttrib m_screen_coord;
ShaderUniform m_screen_texture;
std::shared_ptr<VertexDeclaration> m_vdecl;
std::shared_ptr<VertexBuffer> m_vbo;
array<std::shared_ptr<Framebuffer>, std::shared_ptr<Shader>, array<ShaderUniform>, array<ShaderAttrib> > m_fbos;
std::shared_ptr<Framebuffer> temp_buffer;
int mode;
int m_cur_fbo;
double m_time;
vec3 m_hotspot, m_color;
bool m_ready;
float m_timer;
};
int main(int argc, char **argv)
{
sys::init(argc, argv);
Application app("Tutorial 12: Jump Flooding Algorithm & Voronoi", ivec2(512, 512), 60.0f);
new Voronoi();
app.Run();
return EXIT_SUCCESS;
}