source: trunk/tests/cachebuf_test/nv_cachebuf_test.cc @ 214

#include <nv/interface/vertex_buffer.hh>
#include <nv/gl/gl_device.hh>
#include <nv/gfx/image.hh>
#include <nv/interface/context.hh>
#include <nv/interface/window.hh>
#include <nv/interface/program.hh>
#include <nv/interface/texture2d.hh>
#include <nv/logging.hh>
#include <nv/logger.hh>
#include <glm/glm.hpp>
#include <glm/gtc/matrix_transform.hpp>
#include <glm/gtc/type_ptr.hpp>
#include <nv/string.hh>
#include <nv/interface/mesh.hh>
#include <cstdlib> // rand
#include <ctime> // time

#include <nv/gfx/sliced_buffer.hh>

#define INDEXED_TEST

struct vertex
{
        nv::ivec2 coord;
        nv::vec4  color;
        vertex() {}
        vertex( const nv::ivec2& coord, const nv::vec4& color )
                : coord( coord ), color( color ) {}
};

#ifndef INDEXED_TEST
struct quad
{
        vertex vtx[6];
        quad( const nv::ivec2& coorda, const nv::ivec2& coordb, const nv::vec4& color )
        {
                vtx[0].color = color;
                vtx[1].color = color;
                vtx[2].color = color;
                vtx[3].color = color;
                vtx[4].color = color;
                vtx[5].color = color;
                vtx[0].coord = coorda;
                vtx[1].coord = nv::ivec2( coorda.x, coordb.y );
                vtx[2].coord = coordb;
                vtx[3].coord = coordb;
                vtx[4].coord = nv::ivec2( coordb.x, coorda.y );
                vtx[5].coord = coorda;
        }
        quad( const nv::ivec2& coorda, const nv::ivec2& coordb, const nv::ivec2& coordc, const nv::ivec2& coordd, const nv::vec4& color )
        {
                vtx[0].color = color;
                vtx[1].color = color;
                vtx[2].color = color;
                vtx[3].color = color;
                vtx[4].color = color;
                vtx[5].color = color;
                vtx[0].coord = coorda;
                vtx[1].coord = coordb;
                vtx[2].coord = coordc;
                vtx[3].coord = coordc;
                vtx[4].coord = coordd;
                vtx[5].coord = coorda;
        }

};
#endif 

#ifdef INDEXED_TEST
typedef nv::indexed_sliced_buffer<vertex> gcache;
typedef nv::indexed_buffer_slice<vertex> gslice;
#else
typedef nv::sliced_buffer<quad> gcache;
typedef nv::buffer_slice<quad> gslice;
#endif

struct app_window
{
        app_window( gcache* cache, const glm::ivec2& a, const glm::ivec2& b, const glm::vec4& color )
                : m_slice( cache ), m_simple( false ), m_a( a ), m_b( b ), m_c( color )
        {
                create_complex();
        }

        void change_color( const glm::vec4& color )
        {
                m_c = color;
                glm::vec4 dcolor( color.x * 0.5, color.y * 0.5, color.z * 0.5, 1.0 );
                #ifdef INDEXED_TEST
                std::vector<vertex>& v = m_slice.lock_vertices();
                size_t size   = v.size();
                size_t dcount = 8;
                size_t dmin   = 8;
                size_t count  = size;
                #else
                std::vector<quad>& v = m_slice.lock();
                size_t size   = v.size();
                size_t dcount = (size - 1) * 6;
                size_t dmin   = 1;
                size_t count  = size * 6;
                #endif
                vertex* vtx = (vertex*)v.data();
                if ( size > dmin )
                {
                        for (size_t i = 0; i < dcount; ++i )
                                vtx[i].color = dcolor;
                        for (size_t i = dcount; i < count; ++i )
                                vtx[i].color = color;
                }
                else
                {
                        for (size_t i = 0; i < count; ++i )
                                vtx[i].color = color;
                }
        }

        void simplify_toggle()
        {
                if ( !m_simple )
                {
                        NV_LOG( nv::LOG_INFO, "Simplifing" );
                        create_simple();
                }
                else
                {
                        NV_LOG( nv::LOG_INFO, "Complexifing" );
                        create_complex();
                }
        }

        void create_simple()
        {
                #ifdef INDEXED_TEST
                std::vector<vertex>& v     = m_slice.lock_vertices();
                std::vector<nv::uint16>& i = m_slice.lock_indices();
                v.clear();
                i.clear();
                v.emplace_back( m_a, m_c );
                v.emplace_back( nv::ivec2( m_a.x, m_b.y ), m_c );
                v.emplace_back( m_b, m_c );
                v.emplace_back( nv::ivec2( m_b.x, m_a.y ), m_c );
                nv::uint16 tmp[] = { 0, 1, 2, 2, 3, 0 };
                i.insert( i.end(), tmp, std::end( tmp ) );
                #else
                std::vector<quad>& v = m_slice.lock();
                v.clear();
                v.emplace_back( m_a, m_b, m_c );
                #endif
                m_simple = true;
        }

        void create_complex()
        {
                glm::vec4 dcolor( m_c.x * 0.5, m_c.y * 0.5, m_c.z * 0.5, 1.0 );
                nv::ivec2 a2( m_a.x, m_b.y );
                nv::ivec2 b2( m_b.x, m_a.y );
                nv::ivec2 t1( 10, 10 );
                nv::ivec2 t2( -10, 10 );
                #ifdef INDEXED_TEST
                std::vector<vertex>& v     = m_slice.lock_vertices();
                std::vector<nv::uint16>& i = m_slice.lock_indices();
                v.clear();
                i.clear();
                v.emplace_back( m_a- t1, dcolor ); // 0
                v.emplace_back( a2 + t2, dcolor ); // 1
                v.emplace_back( m_b+ t1, dcolor ); // 2
                v.emplace_back( b2 - t2, dcolor ); // 3

                v.emplace_back( m_a, dcolor ); // 4
                v.emplace_back( a2, dcolor );  // 5
                v.emplace_back( m_b, dcolor ); // 6
                v.emplace_back( b2, dcolor );  // 7
                nv::uint16 tmp[] = { 
                        0, 4, 7, 7, 3, 0,
                        0, 1, 5, 5, 4, 0,
                        1, 2, 6, 6, 5, 1,
                        2, 3, 7, 7, 6, 2,
                };
                i.insert( i.end(), tmp, std::end( tmp ) );

                v.emplace_back( m_a, m_c );    // 8
                v.emplace_back( a2, m_c );     // 9
                v.emplace_back( m_b, m_c );    // 10
                v.emplace_back( b2, m_c );     // 11
                nv::uint16 tmp2[] = { 8, 9, 10, 10, 11, 8 };
                i.insert( i.end(), tmp2, std::end( tmp2 ) );

                #else
                std::vector<quad>& v = m_slice.lock();
                v.clear();
                v.emplace_back( m_a - t1, m_a,       b2, b2 - t2, dcolor );
                v.emplace_back( m_a - t1, a2 + t2, a2, m_a,       dcolor );
                v.emplace_back( a2 + t2, m_b + t1, m_b, a2, dcolor );
                v.emplace_back( m_b + t1, b2 - t2, b2, m_b, dcolor );
                v.emplace_back( m_a, m_b, m_c );
                #endif
                m_simple = false;
        }

        void draw()
        {
                m_slice.commit();
        }

        gslice m_slice;
        bool m_simple;
        nv::ivec2 m_a;
        nv::ivec2 m_b;
        nv::vec4 m_c;
};

class application
{
public:
        application();
        bool initialize();
        bool run();
        void kill_window();
        void spawn_window();
        void simplify_window();
        void recolor_window();
        ~application();
protected:
        nv::device* m_device;
        nv::window* m_window;
        nv::clear_state m_clear_state;
        nv::render_state m_render_state;
        
        gcache* m_quad_cache;
        std::vector<app_window>  m_windows;

        nv::program* m_program;
        nv::vertex_array* m_va;
        unsigned int m_count;
};

application::application()
{
        m_device = new nv::gl_device();
        m_window = m_device->create_window( 800, 600 );

        m_clear_state.buffers = nv::clear_state::COLOR_AND_DEPTH_BUFFER;
        m_render_state.depth_test.enabled = false;
        m_render_state.culling.enabled    = false;
        m_render_state.blending.enabled   = false;
        m_render_state.blending.src_rgb_factor   = nv::blending::SRC_ALPHA;
        m_render_state.blending.dst_rgb_factor   = nv::blending::ONE_MINUS_SRC_ALPHA;
        m_render_state.blending.src_alpha_factor = nv::blending::SRC_ALPHA;
        m_render_state.blending.dst_alpha_factor = nv::blending::ONE_MINUS_SRC_ALPHA;
}

bool application::initialize()
{
        { 
                m_program   = m_device->create_program( nv::slurp( "cachebuf.vert" ), nv::slurp( "cachebuf.frag" ) );
                m_va        = m_device->create_vertex_array();

                #ifdef INDEXED_TEST
                m_quad_cache = new gcache( m_device, nv::DYNAMIC_DRAW, 200, 200 );
                m_va->set_index_buffer( m_quad_cache->get_index_buffer(), nv::USHORT, false );
                nv::vertex_buffer* buffer = m_quad_cache->get_vertex_buffer();
                #else
                m_quad_cache = new gcache( m_device, nv::DYNAMIC_DRAW, 20, true );
                nv::vertex_buffer* buffer = (nv::vertex_buffer*)m_quad_cache->get_buffer();
                #endif

                m_va->add_vertex_buffer( nv::slot::POSITION, buffer, nv::INT,   2, 0, sizeof( vertex ), false );
                m_va->add_vertex_buffer( nv::slot::COLOR,    buffer, nv::FLOAT, 4, offset_of( &vertex::color ), sizeof( vertex ), false );
        }
        return true;
}

bool application::run()
{
        int keypress = 0;
        m_program->bind();
        glm::mat4 projection = glm::ortho( 0.0f, 800.0f, 600.0f, 0.0f, -1.0f, 1.0f );
        m_program->set_uniform( "nv_projection", glm::mat4(projection) );

        while(!keypress) 
        {
                for ( auto& w : m_windows )
                {
                        w.draw();
                }
                if (m_quad_cache->commit() )
                {
                        #ifdef INDEXED_TEST
                        m_va->set_index_buffer( m_quad_cache->get_index_buffer() );
                        nv::vertex_buffer* buffer = m_quad_cache->get_vertex_buffer();
                        #else
                        nv::vertex_buffer* buffer = (nv::vertex_buffer*)m_quad_cache->get_buffer();
                        #endif
                        m_va->update_vertex_buffer( nv::slot::POSITION, buffer, false );
                        m_va->update_vertex_buffer( nv::slot::COLOR,    buffer, false );
                }

                m_window->get_context()->clear( m_clear_state );
                m_program->bind();
//              m_program->set_uniform( "tex", 0 );
                #ifdef INDEXED_TEST
                size_t draw_size = m_quad_cache->get_index_size();
                #else
                size_t draw_size = m_quad_cache->get_size() * 6;
                #endif
                m_window->get_context()->draw( nv::TRIANGLES, m_render_state, m_program, m_va, draw_size );
                m_window->swap_buffers();

                nv::io_event event;
                while(m_window->poll_event(event)) 
                {      
                        switch (event.type) 
                        {
                        case nv::EV_QUIT:
                                keypress = 1;
                                break;
                        case nv::EV_KEY:
                                if (event.key.pressed)
                                {
                                        switch (event.key.code) 
                                        {
                                        case nv::KEY_N      : spawn_window(); break;
                                        case nv::KEY_S      : simplify_window(); break;
                                        case nv::KEY_C      : recolor_window(); break;
                                        case nv::KEY_K      : kill_window(); break;
                                        case nv::KEY_ESCAPE : keypress = 1; break;
                                        }
                                }
                                break;
                        }
                }
        }
        return true;
}

void application::spawn_window()
{
        glm::ivec2 a( std::rand() % 600, std::rand() % 400 );
        glm::ivec2 b( std::rand() % 200, std::rand() % 200 );
        NV_LOG( nv::LOG_INFO, "Spawn (" << a.x << "," << a.y << "x" << b.x << "," << b.y << ")" );
        m_windows.emplace_back( m_quad_cache, a, a + b, glm::vec4( 0, 0, 1, 1 ) );
}

void application::kill_window()
{
        if ( m_windows.size() == 0 ) return;
        size_t index = rand() % m_windows.size();
        m_windows.erase( m_windows.begin() + index );
}

void application::recolor_window()
{
        if ( m_windows.size() == 0 ) return;
        size_t index = rand() % m_windows.size();
        m_windows[ index ].change_color( nv::vec4( (float)rand() / float(RAND_MAX), (float)rand() / float(RAND_MAX), (float)rand() / float(RAND_MAX), 1.0 ) );
}

void application::simplify_window()
{
        if ( m_windows.size() == 0 ) return;
        size_t index = rand() % m_windows.size();
        NV_LOG( nv::LOG_INFO, "Simplify " << index );
        m_windows[ index ].simplify_toggle();
}

application::~application()
{
        m_windows.clear();
        delete m_quad_cache;

        delete m_program;
        delete m_va;
        delete m_window;
        delete m_device;
}


int main(int, char* [])
{
        std::srand((unsigned int) std::time(0) );
        nv::logger log(nv::LOG_TRACE);
        log.add_sink( new nv::log_file_sink("log.txt"), nv::LOG_TRACE );
        log.add_sink( new nv::log_console_sink(), nv::LOG_TRACE );
        
        NV_LOG( nv::LOG_NOTICE, "Logging started" );
        application app;
        if ( app.initialize() )
        {
                app.run();
        }
        NV_LOG( nv::LOG_NOTICE, "Logging stopped" );

        return 0;
}