float DistanceBetweenPoints(float3 a, float3 b) {
	return fast_distance(a, b);
	//return sqrt(pow(a.x - b.x, 2) + pow(a.y - b.y, 2) + pow(a.z - b.z, 2));
}

float Distance(float3 a) {
	return fast_length(a);
	//return sqrt(pow(a.x, 2) + pow(a.y, 2) + pow(a.z, 2));
}

// Naive incident ray light
float4 white_light(float4 input, float3 light, int3 mask) {

	input.w = input.w + acos(
		dot(
			normalize(light),
			normalize(convert_float3(mask * (-mask)))
			)
		) / 32;

	input.w += 0.25f;

	return input;

}


// Phong + diffuse lighting function for g

//  0  1  2  3  4  5  6  7   8   9
// {r, g, b, i, x, y, z, x', y', z'}


float4 view_light(float4 in_color, float3 light, float4 light_color, float3 view, int3 mask) {

	float d = Distance(light) / 100.0f;
	d *= d;

	float diffuse = max(dot(normalize(convert_float3(mask)), normalize(light)), 0.0f);
	in_color += diffuse * light_color * 0.5f / d;

	if (dot(light, normalize(convert_float3(mask))) > 0.0f)
	{
		float3 halfwayVector = normalize(normalize(light) + normalize(view));
		float specTmp = max(dot(normalize(convert_float3(mask)), halfwayVector), 0.0f);
		in_color += pow(specTmp, 8.0f) * light_color * 0.5f / d;
	}
	if (in_color.w > 1.0f){
		in_color.xyz *= in_color.w;
	}

	return in_color;
}


int rand(int* seed) // 1 <= *seed < m
{
	int const a = 16807; //ie 7**5
	int const m = 2147483647; //ie 2**31-1

	*seed = ((*seed) * a) % m;
	return(*seed);
}



// =================================== Boolean ray intersection ============================
// =========================================================================================

bool cast_light_intersection_ray(
	global char* map,
	global int3* map_dim,
	 float3 ray_dir,
	 float3 ray_pos,
	global float* lights,
	global int* light_count

	){

	float distance_to_light = DistanceBetweenPoints(ray_pos, (float3)(lights[4], lights[5], lights[6]));
	//if (distance_to_light > 200.0f){
	//	return false;
	//}

	// Setup the voxel step based on what direction the ray is pointing
	int3 voxel_step = { 1, 1, 1 };
	voxel_step *= (ray_dir > 0) - (ray_dir < 0);

	// Setup the voxel coords from the camera origin
	int3 voxel = convert_int3(ray_pos);

	// Delta T is the units a ray must travel along an axis in order to traverse an integer split
	float3 delta_t = fabs(1.0f / ray_dir);

	// Compute intersection_t and add in the offset
	float3 intersection_t = delta_t * ((ray_pos)-floor(ray_pos)) * convert_float3(voxel_step);

	// for negative values, wrap around the delta_t
	intersection_t += delta_t * -convert_float3(isless(intersection_t, 0));

	int3 face_mask = { 0, 0, 0 };
	int length_cutoff = 0;

	// Andrew Woo's raycasting algo
	do {

		// Fancy no branch version of the logic step
		face_mask = intersection_t.xyz <= min(intersection_t.yzx, intersection_t.zxy);
		intersection_t += delta_t * fabs(convert_float3(face_mask.xyz));
		voxel.xyz += voxel_step.xyz * face_mask.xyz;

		if (any(voxel >= *map_dim) ||
			any(voxel < 0)) {
			return false;
		}

		// If we hit a voxel
		int voxel_data = map[voxel.x + (*map_dim).x * (voxel.y + (*map_dim).z * (voxel.z))];

		if (voxel_data != 0)
			return true;

		if (++length_cutoff > 300)
			return false;

	} while (any(isless(intersection_t, (float3)(distance_to_light - 1))));

	return false;
}


// ====================================== Raycaster entry point =====================================
// ==================================================================================================

constant float4 fog_color = { 0.73f, 0.81f, 0.89f, 0.8f };
constant float4 overshoot_color = { 0.00f, 0.00f, 0.00f, 0.00f };
constant float4 overshoot_color_2 = { 0.00f, 0.00f, 0.00f, 0.00f };

__kernel void raycaster(
	global char* map,
	global int3* map_dim,
	global int2* resolution,
	global float3* projection_matrix,
	global float2* cam_dir,
	global float3* cam_pos,
	global float* lights,
	global int* light_count,
	__write_only image2d_t image,
	global int* seed_memory,
	__read_only image2d_t texture_atlas,
	global int2 *atlas_dim,
	global int2 *tile_dim
){

	//	int global_id = x * y;

	// Get and set the random seed from seed memory
	//int seed = seed_memory[global_id];
	//int random_number = rand(&seed);
	//seed_memory[global_id] = seed;

	// Get the pixel on the viewport, and find the view matrix ray that matches it
	int2 pixel = (int2)(get_global_id(0), get_global_id(1));
    float3 ray_dir = projection_matrix[pixel.x + (*resolution).x * pixel.y];

	// Pitch
	ray_dir = (float3)(
		ray_dir.z * sin((*cam_dir).x) + ray_dir.x * cos((*cam_dir).x),
		ray_dir.y,
		ray_dir.z * cos((*cam_dir).x) - ray_dir.x * sin((*cam_dir).x)
		);

	// Yaw
    ray_dir = (float3)(
        ray_dir.x * cos((*cam_dir).y) - ray_dir.y * sin((*cam_dir).y),
        ray_dir.x * sin((*cam_dir).y) + ray_dir.y * cos((*cam_dir).y),
        ray_dir.z
    );


	// Setup the voxel step based on what direction the ray is pointing
    int3 voxel_step = {1, 1, 1};
	voxel_step *= (ray_dir > 0) - (ray_dir < 0);

    // Setup the voxel coords from the camera origin
	int3 voxel = convert_int3(*cam_pos);

    // Delta T is the units a ray must travel along an axis in order to
    // traverse an integer split
	float3 delta_t = fabs(1.0f / ray_dir);

	// Intersection T is the collection of the next intersection points
	// for all 3 axis XYZ. We take the full positive cardinality when
	// subtracting the floor, so we must transfer the sign over from
	// the voxel step
	float3 intersection_t = delta_t * ((*cam_pos) - ceil(*cam_pos)) * convert_float3(voxel_step);

	// When we transfer the sign over, we get the correct direction of
	// the offset, but we merely transposed over the value instead of mirroring
	// it over the axis like we want. So here, isless returns a boolean if intersection_t
	// is less than 0 which dictates whether or not we subtract the delta which in effect
	// mirrors the offset
	intersection_t -= delta_t * convert_float3(isless(intersection_t, 0));

	int dist = 0;
	int3 face_mask = { 0, 0, 0 };
	int voxel_data = 0;
	// Andrew Woo's raycasting algo
    do {

		// Fancy no branch version of the logic step
		face_mask = intersection_t.xyz <= min(intersection_t.yzx, intersection_t.zxy);
		intersection_t += delta_t * fabs(convert_float3(face_mask.xyz));
		voxel.xyz += voxel_step.xyz * face_mask.xyz;

		// Test for out of bounds contions, add fog
		if (any(voxel >= *map_dim)){
			write_imagef(image, pixel, white_light(mix(fog_color, overshoot_color, 1.0 - max(dist / 700.0f, (float)0)), (float3)(lights[7], lights[8], lights[9]), face_mask));
			return;
		}
		if (any(voxel < 0)) {
			write_imagef(image, pixel, white_light(mix(fog_color, overshoot_color_2, 1.0 - max(dist / 700.0f, (float)0)), (float3)(lights[7], lights[8], lights[9]), face_mask));
			return;
		}

        // If we hit a voxel
        voxel_data = map[voxel.x + (*map_dim).x * (voxel.y + (*map_dim).z * (voxel.z))];

		if (voxel_data != 0) {

			float4 voxel_color = (float4)(0.0f, 0.0f, 0.0f, 0.001f);

			// Determine where on the 2d plane the ray intersected
			float3 face_position = (float3)(0);
			float2 tile_face_position = (float2)(0);
			float3 sign = (float3)(1.0f, 1.0f, 1.0f);

			// First determine the percent of the way the ray is towards the next intersection_t
			// in relation to the xyz position on the plane
			if (face_mask.x == -1) {

				sign.x *= -1.0;

				// the next intersection for this plane - the last intersection of the passed plane / delta of this plane
				// basically finds how far in on the other 2 axis we are when the ray traversed the plane
				float z_percent = (intersection_t.z - (intersection_t.x - delta_t.x)) / delta_t.z;
				float y_percent = (intersection_t.y - (intersection_t.x - delta_t.x)) / delta_t.y;

				// Since we intersected face x, we know that we are at the face (1.0)
				// I think the 1.001f rendering bug is the ray thinking it's within the voxel
				// even though it's sitting on the very edge
				face_position = (float3)(1.0001f, y_percent, z_percent);
				tile_face_position = (float2)(y_percent, z_percent);
			}
			else if (face_mask.y == -1) {

				sign.y *= -1.0;
				float x_percent = (intersection_t.x - (intersection_t.y - delta_t.y)) / delta_t.x;
				float z_percent = (intersection_t.z - (intersection_t.y - delta_t.y)) / delta_t.z;

				face_position = (float3)(x_percent, 1.0001f, z_percent);
				tile_face_position = (float2)(x_percent, z_percent);
			}

			else if (face_mask.z == -1) {

				sign.z *= -1.0;
				float x_percent = (intersection_t.x - (intersection_t.z - delta_t.z)) / delta_t.x;
				float y_percent = (intersection_t.y - (intersection_t.z - delta_t.z)) / delta_t.y;

				face_position = (float3)(x_percent, y_percent, 1.0001f);
				tile_face_position = (float2)(x_percent, y_percent);

			}

			// Because the raycasting process is agnostic to the quadrant
			// it's working in, we need to transpose the sign over to the face positions.
			// If we don't it will think that it is always working in the (1, 1, 1) quadrant
			// and will just "copy" the quadrant. This includes shadows as they use the face_position
			// in order to cast the intersection ray!!


			face_position.x = select((float)(face_position.x), (float)(-face_position.x + 1.0f), (int)(ray_dir.x > 0));
			tile_face_position.x = select((float)(tile_face_position.x), (float)(-tile_face_position.x + 1.0f), (int)(ray_dir.x < 0));

			if (ray_dir.y > 0){
				face_position.y =  - face_position.y + 1;
			} else {
				tile_face_position.x = 1.0 - tile_face_position.x;

				// We run into the Hairy ball problem, so we need to define
				// a special case for the zmask
				if (face_mask.z == -1) {
					tile_face_position.x = 1.0 - tile_face_position.x;
					tile_face_position.y = 1.0 - tile_face_position.y;
				}
			}

			face_position.z = select((float)(face_position.z), (float)(-face_position.z + 1.0f), (int)(ray_dir.z > 0));
			tile_face_position.y = select((float)(tile_face_position.y), (float)(-tile_face_position.y + 1.0f), (int)(ray_dir.z < 0));

			// Now either use the face position to retrieve a texture sample, or
			// just a plain color for the voxel color. Notice the JANK -1 after the
			// conditionals in the select statement. That's because select works on negs
			// and pos's. So a false equality will still eval as true as it is technically
			// a positive result (0)
			voxel_color = select(
				(float4)(0.25f, 0.64f, 0.87f, 0.0f),
				(float4)voxel_color,
			 	(int4)((voxel_data == 5) - 1)
			);

			voxel_color = select(
				(float4)(0.0f, 0.239f, 0.419f, 0.0f),
				(float4)read_imagef(
					 texture_atlas,
					 convert_int2(tile_face_position * convert_float2(*atlas_dim / *tile_dim)) +
					 convert_int2((float2)(3, 0) * convert_float2(*atlas_dim / *tile_dim))
				 ),
				 (int4)((voxel_data == 6) - 1)
			);

		 	voxel_color.w = 0.0f;

			if (cast_light_intersection_ray(
				map,
				map_dim,
				normalize((float3)(lights[4], lights[5], lights[6]) - (convert_float3(voxel) + face_position)),
				(convert_float3(voxel) + face_position),
				lights,
				light_count
			)) {

				// If the light ray intersected an object on the way to the light point
				write_imagef(image, pixel, white_light(voxel_color, (float3)(1.0f, 1.0f, 1.0f), face_mask));
				return;
			}

			//  0  1  2  3  4  5  6  7   8   9
			// {r, g, b, i, x, y, z, x', y', z'}

			write_imagef(
				image,
				pixel,
				view_light(
					voxel_color,
					(convert_float3(voxel) + face_position) - (float3)(lights[4], lights[5], lights[6]),
					(float4)(lights[0], lights[1], lights[2], lights[3]),
					(convert_float3(voxel) + face_position) - (*cam_pos),
					face_mask * voxel_step
					)
				);

			return;
		}

    } while (++dist < 700.0f);

	//write_imagef(image, pixel, white_light(mix(fog_color, (float4)(0.40, 0.00, 0.40, 0.2), 1.0 - max(dist / 700.0f, (float)0)), (float3)(lights[7], lights[8], lights[9]), face_mask));
    return;
}