#include <iostream>
#include <chrono>
#include <fstream>
#include <sstream>
#include <SFML/Graphics.hpp>


#ifdef linux
#include <CL/cl.h>
#include <CL/opencl.h>

#elif defined _WIN32
#include <CL/cl_gl.h>
#include <CL/cl.h>
#include <CL/opencl.h>
#include <windows.h>

#elif defined TARGET_OS_MAC
# include <OpenGL/OpenGL.h>
# include <OpenCL/opencl.h>
#include <OpenCL/cl_gl_ext.h>
#include <OpenCL/cl_ext.h>

#endif
#include "TestPlatform.cpp"
#include "Map.h"
#include "Curses.h"
#include "util.hpp"
#include "RayCaster.h"
#include "Clapper.h"

const int WINDOW_X = 150;
const int WINDOW_Y = 150;



int main(){

    Clapper c;
    c.acquire_platform_and_device();
    c.create_shared_context();

    c.compile_kernel("../kernels/kernel.txt", true, "hello");

};






float elap_time(){
	static std::chrono::time_point<std::chrono::system_clock> start;
	static bool started = false;

	if (!started){
		start = std::chrono::system_clock::now();
		started = true;
	}

	std::chrono::time_point<std::chrono::system_clock> now = std::chrono::system_clock::now();
	std::chrono::duration<double> elapsed_time = now - start;
	return elapsed_time.count();
}

sf::Sprite window_sprite;
sf::Texture window_texture;

// Y: -1.57 is straight up
// Y: 1.57 is straight down


int main0() {

    // Initialize the render window
	Curses curse(sf::Vector2i(5, 5), sf::Vector2i(WINDOW_X, WINDOW_Y));
    sf::RenderWindow window(sf::VideoMode(WINDOW_X, WINDOW_Y), "SFML");
	


    // The step size in milliseconds between calls to Update()
    // Lets set it to 16.6 milliseonds (60FPS)
    float step_size = 0.0166f;

    // Timekeeping values for the loop
    double  frame_time = 0.0,
            elapsed_time = 0.0,
            delta_time = 0.0,
            accumulator_time = 0.0,
            current_time = 0.0;

    fps_counter fps;

	// ============================= RAYCASTER SETUP ==================================
	
	// Setup the sprite and texture
	window_texture.create(WINDOW_X, WINDOW_Y);
	window_sprite.setPosition(0, 0);

	// State values
	sf::Vector3i map_dim(100, 100, 100);
	sf::Vector2i view_res(WINDOW_X, WINDOW_Y);
	sf::Vector3f cam_dir(1.0f, 0.0f, 1.57f);
	sf::Vector3f cam_pos(50, 50, 50);
	sf::Vector3f cam_vec(0, 0, 0);
	Map* map = new Map(map_dim);
	RayCaster ray_caster(map, map_dim, view_res);


	// ===============================================================================

	// Mouse capture
	sf::Vector2i deltas;
	sf::Vector2i fixed(window.getSize());
	bool mouse_enabled = true;

	while (window.isOpen()) {

		// Poll for events from the user
		sf::Event event;
		while (window.pollEvent(event)) {

			// If the user tries to exit the application via the GUI
			if (event.type == sf::Event::Closed)
				window.close();
		}

		cam_vec.x = 0;
		cam_vec.y = 0;
		cam_vec.z = 0;

		if (sf::Keyboard::isKeyPressed(sf::Keyboard::Q)) {
			cam_vec.z = 1;
		}
		if (sf::Keyboard::isKeyPressed(sf::Keyboard::E)) {
			cam_vec.z = -1;
		}
		if (sf::Keyboard::isKeyPressed(sf::Keyboard::W)) {
			cam_vec.y = 1;
		}
		if (sf::Keyboard::isKeyPressed(sf::Keyboard::S)) {
			cam_vec.y = -1;
		}
		if (sf::Keyboard::isKeyPressed(sf::Keyboard::A)) {
			cam_vec.x = 1;
		}
		if (sf::Keyboard::isKeyPressed(sf::Keyboard::D)) {
			cam_vec.x = -1;
		}
        if (sf::Keyboard::isKeyPressed(sf::Keyboard::Left)) {
            cam_dir.z = -0.1f;
        }
        if (sf::Keyboard::isKeyPressed(sf::Keyboard::Right)) {
            cam_vec.z = +0.1f;
        }
        if (sf::Keyboard::isKeyPressed(sf::Keyboard::Down)) {
            cam_vec.y = +0.1f;
        }
        if (sf::Keyboard::isKeyPressed(sf::Keyboard::Up)) {
            cam_vec.y = -0.1f;
        }

		deltas = fixed - sf::Mouse::getPosition();
		if (deltas != sf::Vector2i(0, 0) && mouse_enabled == true) {

			// Mouse movement
			sf::Mouse::setPosition(fixed);
			cam_dir.y -= deltas.y / 300.0f;
			cam_dir.z -= deltas.x / 300.0f;
		}

		cam_pos.x += cam_vec.x / 1.0;
		cam_pos.y += cam_vec.y / 1.0;
		cam_pos.z += cam_vec.z / 1.0;

//		if (cam_vec.x > 0.0f)
//			cam_vec.x -= 0.1;
//		else if (cam_vec.x < 0.0f)
//			cam_vec.x += 0.1;
//
//		if (cam_vec.y > 0.0f)
//			cam_vec.y -= 0.1;
//		else if (cam_vec.y < 0.0f)
//			cam_vec.y += 0.1;
//
//		if (cam_vec.z > 0.0f)
//			cam_vec.z -= 0.1;
//		else if (cam_vec.z < 0.0f)
//			cam_vec.z += 0.1;

		std::cout << cam_vec.x << " : " << cam_vec.y << " : " << cam_vec.z << std::endl;


        // Time keeping
		elapsed_time = elap_time();
		delta_time = elapsed_time - current_time;
		current_time = elapsed_time;
		if (delta_time > 0.2f)
			delta_time = 0.2f;
		accumulator_time += delta_time;
		while ((accumulator_time - step_size) >= step_size) {
            accumulator_time -= step_size;


            // Update cycle
            curse.Update(delta_time);


        }

        // Fps cycle
        // map->moveLight(sf::Vector2f(0.3, 0));
		
		window.clear(sf::Color::Black);

		// Cast the rays and get the image
		sf::Color* pixel_colors = ray_caster.CastRays(cam_dir, cam_pos);

		for (int i = 0; i < WINDOW_X * WINDOW_Y; i++) {
			
			Curses::Tile t(sf::Vector2i(i % WINDOW_X, i / WINDOW_X));
			Curses::Slot s(L'\u0045', pixel_colors[i], sf::Color::Black);
			t.push_back(s);
			curse.setTile(t);

		}


        // Cast it to an array of Uint8's
		auto out = (sf::Uint8*)pixel_colors;

        window_texture.update(out);
		window_sprite.setTexture(window_texture);
		window.draw(window_sprite);


		curse.Render();

		// Give the frame counter the frame time and draw the average frame time
		fps.frame(delta_time);
		fps.draw(&window);

		window.display();



	}
	return 0;

}