rpgpt/main.c

#define SOKOL_IMPL
#if defined(WIN32) || defined(_WIN32)
#define SOKOL_D3D11
#endif

#if defined(__EMSCRIPTEN__)
#define SOKOL_GLES2
#endif

#include "sokol_app.h"
#include "sokol_gfx.h"
#include "sokol_time.h"
#include "sokol_glue.h"
#define STB_IMAGE_IMPLEMENTATION
#include "stb_image.h"
#define STB_TRUETYPE_IMPLEMENTATION
#include "stb_truetype.h"
#include "HandmadeMath.h"

#pragma warning(disable : 4996) // fopen is safe. I don't care about fopen_s

#include <math.h>

#define ARRLEN(x) ((sizeof(x)/sizeof(0[x])) / ((size_t)(!(sizeof(x) % sizeof(0[x])))))
#define ENTITIES_ITER(ents) for(Entity *it = ents; it < ents + ARRLEN(ents); it++) if(it->exists)

// so can be grep'd and removed
#define dbgprint(...) { printf("Debug | %s:%d | ", __FILE__, __LINE__); printf(__VA_ARGS__); }
Vec2 RotateV2(Vec2 v, float theta)
{
  return V2( 
      v.X * cosf(theta) - v.Y * sinf(theta),
      v.X * sinf(theta) + v.Y * cosf(theta)
    );
}

typedef struct AABB
{
 Vec2 upper_left;
 Vec2 lower_right;
} AABB;

typedef struct Quad
{
 union
 {
  struct
  {
   Vec2 ul; // upper left
   Vec2 ur; // upper right
   Vec2 lr; // lower right
   Vec2 ll; // lower left
  };
  Vec2 points[4];
 };
} Quad;

typedef struct TileInstance
{
 uint16_t kind;
} TileInstance;

typedef struct AnimatedTile
{
 uint16_t id_from;
 int num_frames;
 uint16_t frames[32];
} AnimatedTile;

typedef struct TileSet
{
 sg_image *img;
 AnimatedTile animated[128];
} TileSet;

typedef struct AnimatedSprite
{
 sg_image *img;
 double time_per_frame;
 int num_frames;
 Vec2 start;
 float horizontal_diff_btwn_frames;
 Vec2 region_size;
 bool no_wrap; // does not wrap when playing
} AnimatedSprite;

typedef enum CharacterState
{
 CHARACTER_WALKING,
 CHARACTER_IDLE,
 CHARACTER_ATTACK,
} CharacterState;

typedef enum EntityKind
{
 ENTITY_INVALID, // zero initialized is invalid entity

 ENTITY_PLAYER,
 ENTITY_OLD_MAN,
 ENTITY_BULLET,
} EntityKind;

#define MAX_SENTENCE_LENGTH 400
typedef struct { char text[MAX_SENTENCE_LENGTH]; } Sentence;

typedef struct Dialog
{
 Sentence sentences[8];
} Dialog;

typedef struct Entity
{
 bool exists;
 EntityKind kind;

 // fields for all entities
 Vec2 pos;
 Vec2 vel; // only used sometimes, like in old man and bullet
 float damage; // at 1.0, he's dead
 bool facing_left;

 // old man
 bool aggressive;
 double shotgun_timer;

 // character
 CharacterState state;
 bool is_rolling; // can only roll in idle or walk states
 float speed; // for lerping to the speed, so that roll gives speed boost which fades
 double time_not_rolling; // for cooldown for roll, so you can't just hold it and be invincible
 double roll_progress;
 double swing_progress;
} Entity;

typedef struct Overlap
{
 bool is_tile; // in which case e will be null, naturally
 TileInstance t;
 Entity *e;
} Overlap;

#define MAX_COLLISIONS_RESULTS 16
typedef struct Overlapping
{
 Overlap results[MAX_COLLISIONS_RESULTS];
 int num_results;
} Overlapping;


#define LEVEL_TILES 60
#define TILE_SIZE 32 // in pixels
#define MAX_ENTITIES 128
#define PLAYER_SPEED 3.5f // in meters per second
#define PLAYER_ROLL_SPEED 7.0f
typedef struct Level
{
 TileInstance tiles[LEVEL_TILES][LEVEL_TILES];
 Entity initial_entities[MAX_ENTITIES]; // shouldn't be directly modified, only used to initialize entities on loading of level
} Level;

typedef struct TileCoord
{
 int x;
 int y;
} TileCoord;

// no alignment etc because lazy
typedef struct Arena
{
 char *data;
 size_t data_size;
 size_t cur;
} Arena;

Arena make_arena(size_t max_size)
{
 return (Arena)
 {
  .data = calloc(max_size, 1),
  .data_size = max_size,
  .cur = 0,
 };
}

void reset(Arena *a)
{
 memset(a->data, 0, a->data_size);
 a->cur = 0;
}

char *get(Arena *a, size_t of_size)
{
 assert(a->data != NULL);
 char *to_return = a->data + a->cur;
 a->cur += of_size;
 assert(a->cur < a->data_size);
 return to_return;
}

Arena scratch = {0};

char *tprint(const char *format, ...)
{
 va_list argptr;
 va_start(argptr, format);

 int size = vsnprintf(NULL, 0, format, argptr) + 1; // for null terminator

 char *to_return = get(&scratch, size);

 vsnprintf(to_return, size, format, argptr);

  va_end(argptr);

  return to_return;
}

Vec2 entity_aabb_size(Entity *e)
{
 if(e->kind == ENTITY_PLAYER)
 {
  return V2(TILE_SIZE, TILE_SIZE);
 }
 else if(e->kind == ENTITY_OLD_MAN)
 {
  return V2(TILE_SIZE*0.5f, TILE_SIZE*0.5f);
 }
 else if(e->kind == ENTITY_BULLET)
 {
  return V2(TILE_SIZE*0.25f, TILE_SIZE*0.25f);
 }
 else
 {
  assert(false);
  return (Vec2){0};
 }
}

bool is_tile_solid(TileInstance t)
{
 uint16_t tile_id = t.kind;
 return tile_id == 53 || tile_id == 0 || tile_id == 367 || tile_id == 317 || tile_id == 313 || tile_id == 366 || tile_id == 368;
}
// tilecoord is integer tile position, not like tile coord
Vec2 tilecoord_to_world(TileCoord t)
{
 return V2( (float)t.x * (float)TILE_SIZE * 1.0f, -(float)t.y * (float)TILE_SIZE * 1.0f );
}

// points from tiled editor have their own strange and alien coordinate system (local to the tilemap Y+ down)
Vec2 tilepoint_to_world(Vec2 tilepoint)
{
 Vec2 tilecoord = MulV2F(tilepoint, 1.0/TILE_SIZE);
 return tilecoord_to_world((TileCoord){(int)tilecoord.X, (int)tilecoord.Y});
}

TileCoord world_to_tilecoord(Vec2 w)
{
 // world = V2(tilecoord.x * tile_size, -tilecoord.y * tile_size)
 // world.x = tilecoord.x * tile_size
 // world.x / tile_size = tilecoord.x
 // world.y = -tilecoord.y * tile_size
 // - world.y / tile_size = tilecoord.y
 return (TileCoord){ (int)floorf(w.X / TILE_SIZE), (int)floorf(-w.Y / TILE_SIZE) };
}


AABB tile_aabb(TileCoord t)
{
 return (AABB)
 {
  .upper_left = tilecoord_to_world(t),
   .lower_right = AddV2(tilecoord_to_world(t), V2(TILE_SIZE, -TILE_SIZE)),
 };
}

Vec2 rotate_counter_clockwise(Vec2 v)
{
 return V2(-v.Y, v.X);
}

Vec2 aabb_center(AABB aabb)
{
 return MulV2F(AddV2(aabb.upper_left, aabb.lower_right), 0.5f);
}

AABB centered_aabb(Vec2 at, Vec2 size)
{
 return (AABB){
  .upper_left  = AddV2(at, V2(-size.X/2.0f, size.Y/2.0f)),
   .lower_right = AddV2(at, V2( size.X/2.0f, -size.Y/2.0f)),
 };
}

AABB entity_aabb(Entity *e)
{
 return centered_aabb(e->pos, entity_aabb_size(e));
}

TileInstance get_tile(Level *l, TileCoord t)
{
 bool out_of_bounds = false;
 out_of_bounds |= t.x < 0;
 out_of_bounds |= t.x >= LEVEL_TILES;
 out_of_bounds |= t.y < 0;
 out_of_bounds |= t.y >= LEVEL_TILES;
 //assert(!out_of_bounds);
 if(out_of_bounds) return (TileInstance){0};
 return l->tiles[t.y][t.x];
}

sg_image load_image(const char *path)
{
 sg_image to_return = {0};

 int png_width, png_height, num_channels;
 const int desired_channels = 4;
 stbi_uc* pixels = stbi_load(
   path,
   &png_width, &png_height,
   &num_channels, 0);
 assert(pixels);
 dbgprint("Pah %s | Loading image with dimensions %d %d\n", path, png_width, png_height);
 to_return = sg_make_image(&(sg_image_desc)
   {
   .width = png_width,
   .height = png_height,
   .pixel_format = SG_PIXELFORMAT_RGBA8,
   .min_filter = SG_FILTER_NEAREST,
   .num_mipmaps = 0,
   .wrap_u = SG_WRAP_CLAMP_TO_EDGE,
   .wrap_v = SG_WRAP_CLAMP_TO_EDGE,
   .mag_filter = SG_FILTER_NEAREST,
   .data.subimage[0][0] =
   {
   .ptr = pixels,
   .size = (size_t)(png_width * png_height * 4),
   }
   });
 stbi_image_free(pixels);
 return to_return;
}

#include "quad-sapp.glsl.h"
#include "assets.gen.c"

AnimatedSprite knight_idle =
{
 .img = &image_knight_idle,
 .time_per_frame = 0.3,
 .num_frames = 10,
 .start = {16.0f, 0.0f},
 .horizontal_diff_btwn_frames = 120.0,
 .region_size = {80.0f, 80.0f},
};

AnimatedSprite knight_running =
{
 .img = &image_knight_run,
 .time_per_frame = 0.06,
 .num_frames = 10,
 .start = {19.0f, 0.0f},
 .horizontal_diff_btwn_frames = 120.0,
 .region_size = {80.0f, 80.0f},
};

AnimatedSprite knight_rolling =
{
 .img = &image_knight_roll,
 .time_per_frame = 0.05,
 .num_frames = 12,
 .start = {19.0f, 0.0f},
 .horizontal_diff_btwn_frames = 120.0,
 .region_size = {80.0f, 80.0f},
 .no_wrap = true,
};


AnimatedSprite knight_attack = 
{
 .img = &image_knight_attack,
 .time_per_frame = 0.06,
 .num_frames = 4,
 .start = {37.0f, 0.0f},
 .horizontal_diff_btwn_frames = 120.0,
 .region_size = {80.0f, 80.0f},
 .no_wrap = true,
};

AnimatedSprite old_man_idle = 
{
 .img = &image_old_man,
 .time_per_frame = 0.4,
 .num_frames = 4,
 .start = {0.0, 0.0},
 .horizontal_diff_btwn_frames = 16.0f,
 .region_size = {16.0f, 16.0f},
};

sg_image image_font = {0};
const float font_size = 32.0;
stbtt_bakedchar cdata[96]; // ASCII 32..126 is 95 glyphs


static struct
{
 sg_pass_action pass_action;
 sg_pipeline pip;
 sg_bindings bind;
} state;

AABB level_aabb = { .upper_left = {0.0f, 0.0f}, .lower_right = {2000.0f, -2000.0f} };
Entity entities[MAX_ENTITIES] = {0};
Entity *player = NULL;

Entity *new_entity()
{
 for(int i = 0; i < ARRLEN(entities); i++)
 {
  if(!entities[i].exists)
  {
   Entity *to_return = &entities[i];
   *to_return = (Entity){0};
   to_return->exists = true;
   return to_return;
  }
 }
 assert(false);
 return NULL;
}

void reset_level()
{
 // load level
 Level *to_load = &level_level0;
 {
  assert(ARRLEN(to_load->initial_entities) == ARRLEN(entities));
  memcpy(entities, to_load->initial_entities, sizeof(Entity) * MAX_ENTITIES);

  player = NULL;
  ENTITIES_ITER(entities)
  {
   if(it->kind == ENTITY_PLAYER)
   {
    assert(player == NULL);
    player = it;
   }
  }
  assert(player != NULL); // level initial config must have player entity
 }
}


void init(void)
{
 sg_setup(&(sg_desc){
  .context = sapp_sgcontext(),
  });
 stm_setup();

 scratch = make_arena(1024 * 10);

 load_assets();
 reset_level();

 // load font
 {
  FILE* fontFile = fopen("assets/orange kid.ttf", "rb");
  fseek(fontFile, 0, SEEK_END);
  size_t size = ftell(fontFile); /* how long is the file ? */
  fseek(fontFile, 0, SEEK_SET); /* reset */

  unsigned char *fontBuffer = malloc(size);

  fread(fontBuffer, size, 1, fontFile);
  fclose(fontFile);

  unsigned char *font_bitmap = calloc(1, 512*512);
  stbtt_BakeFontBitmap(fontBuffer, 0, font_size, font_bitmap, 512, 512, 32, 96, cdata);

  unsigned char *font_bitmap_rgba = malloc(4 * 512 * 512); // stack would be too big if allocated on stack (stack overflow)
  for(int i = 0; i < 512 * 512; i++)
  {
   font_bitmap_rgba[i*4 + 0] = 255;
   font_bitmap_rgba[i*4 + 1] = 255;
   font_bitmap_rgba[i*4 + 2] = 255;
   font_bitmap_rgba[i*4 + 3] = font_bitmap[i];
  }

  image_font = sg_make_image( &(sg_image_desc){
    .width = 512,
    .height = 512,
    .pixel_format = SG_PIXELFORMAT_RGBA8,
    .min_filter = SG_FILTER_NEAREST,
    .mag_filter = SG_FILTER_NEAREST,
    .data.subimage[0][0] =
    {
    .ptr = font_bitmap_rgba,
    .size = (size_t)(512 * 512 * 4),
    }
  } );
  free(font_bitmap_rgba);
 }

 state.bind.vertex_buffers[0] = sg_make_buffer(&(sg_buffer_desc)
   {
    .usage = SG_USAGE_STREAM,
    //.data = SG_RANGE(vertices),
    .size = 1024*500,
    .label = "quad-vertices"
   });

 const sg_shader_desc *desc = quad_program_shader_desc(sg_query_backend());
 assert(desc);
 sg_shader shd = sg_make_shader(desc);

 state.pip = sg_make_pipeline(&(sg_pipeline_desc)
   {
    .shader = shd,
    .layout = {
     .attrs =
     {
      [ATTR_quad_vs_position].format = SG_VERTEXFORMAT_FLOAT2,
      [ATTR_quad_vs_texcoord0].format   = SG_VERTEXFORMAT_FLOAT2,
     }
    },
    .colors[0].blend = (sg_blend_state) { // allow transparency
     .enabled = true,
     .src_factor_rgb = SG_BLENDFACTOR_SRC_ALPHA,
     .dst_factor_rgb = SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA,
     .op_rgb = SG_BLENDOP_ADD,
     .src_factor_alpha = SG_BLENDFACTOR_ONE,
     .dst_factor_alpha = SG_BLENDFACTOR_ONE_MINUS_SRC_ALPHA,
     .op_alpha = SG_BLENDOP_ADD,
    },
    .label = "quad-pipeline",
   });

 state.pass_action = (sg_pass_action)
 {
  //.colors[0] = { .action=SG_ACTION_CLEAR, .value={12.5f/255.0f, 12.5f/255.0f, 12.5f/255.0f, 1.0f } }
  //.colors[0] = { .action=SG_ACTION_CLEAR, .value={255.5f/255.0f, 255.5f/255.0f, 255.5f/255.0f, 1.0f } }
  // 0x898989 is the color in tiled
  .colors[0] =
  { .action=SG_ACTION_CLEAR, .value={137.0f/255.0f, 137.0f/255.0f, 137.0f/255.0f, 1.0f } }
 };
}

typedef Vec4 Color;


#define WHITE (Color){1.0f, 1.0f, 1.0f, 1.0f}
#define BLACK (Color){0.0f, 0.0f, 0.0f, 1.0f}
#define RED   (Color){1.0f, 0.0f, 0.0f, 1.0f}
#define GREEN (Color){0.0f, 1.0f, 0.0f, 1.0f}


Vec2 screen_size()
{
 return V2((float)sapp_width(), (float)sapp_height());
}

typedef struct Camera
{
 Vec2 pos;
 float scale;
} Camera;


// everything is in pixels in world space, 43 pixels is approx 1 meter measured from 
// merchant sprite being 5'6"
const float pixels_per_meter = 43.0f;
Camera cam = {.scale = 2.0f };

Vec2 cam_offset()
{
 return AddV2(cam.pos, MulV2F(screen_size(), 0.5f));
}

// in pixels
Vec2 img_size(sg_image img)
{
 sg_image_info info = sg_query_image_info(img);
 return V2((float)info.width, (float)info.height);
}

// full region in pixels
AABB full_region(sg_image img)
{
 return (AABB)
 {
  .upper_left = V2(0.0f, 0.0f),
   .lower_right = img_size(img),
 };
}

// screen coords are in pixels counting from bottom left as (0,0), Y+ is up
Vec2 world_to_screen(Vec2 world)
{
 Vec2 to_return = world;
 to_return = MulV2F(to_return, cam.scale);
 to_return = AddV2(to_return, cam_offset());
 return to_return;
}

Vec2 screen_to_world(Vec2 screen)
{
 Vec2 to_return = screen;
 to_return = SubV2(to_return, cam_offset());
 to_return = MulV2F(to_return, 1.0f/cam.scale);
 return to_return;
}


Quad quad_at(Vec2 at, Vec2 size)
{
 Quad to_return;

 to_return.points[0] = V2(0.0, 0.0);
 to_return.points[1] = V2(size.X, 0.0);
 to_return.points[2] = V2(size.X, -size.Y);
 to_return.points[3] = V2(0.0, -size.Y);

 for(int i = 0; i < 4; i++)
 {
  to_return.points[i] = AddV2(to_return.points[i], at);
 }
 return to_return;
}

Quad tile_quad(TileCoord coord)
{
 Quad to_return = quad_at(tilecoord_to_world(coord), V2(TILE_SIZE, TILE_SIZE));


 return to_return;
}

// out must be of at least length 4
Quad quad_centered(Vec2 at, Vec2 size)
{
 Quad to_return = quad_at(at, size);
 for(int i = 0; i < 4; i++)
 {
  to_return.points[i] = AddV2(to_return.points[i], V2(-size.X*0.5f, size.Y*0.5f));
 }
 return to_return;
}

Quad quad_aabb(AABB aabb)
{
 Vec2 size_vec = SubV2(aabb.lower_right, aabb.upper_left); // negative in vertical direction
 assert(size_vec.Y <= 0.0f);
 assert(size_vec.X >= 0.0f);
 return (Quad) {
  .ul = aabb.upper_left,
  .ur = AddV2(aabb.upper_left, V2(size_vec.X, 0.0f)),
  .lr = AddV2(aabb.upper_left, size_vec),
  .ll = AddV2(aabb.upper_left, V2(0.0f, size_vec.Y)),
 };
}


// both segment_a and segment_b must be arrays of length 2
bool segments_overlapping(float *a_segment, float *b_segment)
{
 assert(a_segment[1] >= a_segment[0]);
 assert(b_segment[1] >= b_segment[0]);
 float total_length = (a_segment[1] - a_segment[0]) + (b_segment[1] - b_segment[0]);
 float farthest_to_left = fminf(a_segment[0], b_segment[0]);
 float farthest_to_right = fmaxf(a_segment[1], b_segment[1]);
 if (farthest_to_right - farthest_to_left < total_length)
 {
  return true;
 } else
 {
  return false;
 }
}

bool overlapping(AABB a, AABB b)
{
 // x axis

 {
  float a_segment[2] =
  { a.upper_left.X, a.lower_right.X };
  float b_segment[2] =
  { b.upper_left.X, b.lower_right.X };
  if(segments_overlapping(a_segment, b_segment))
  {
  } else
  {
   return false;
  }
 }

 // y axis

 {
  float a_segment[2] =
  { a.lower_right.Y, a.upper_left.Y };
  float b_segment[2] =
  { b.lower_right.Y, b.upper_left.Y };
  if(segments_overlapping(a_segment, b_segment))
  {
  } else
  {
   return false;
  }
 }

 return true; // both segments overlapping
}

bool has_point(AABB aabb, Vec2 point)
{
 return
  (aabb.upper_left.X < point.X && point.X < aabb.lower_right.X) &&
  (aabb.upper_left.Y > point.Y && point.Y > aabb.lower_right.Y);
}

int num_draw_calls = 0;

float cur_batch_data[1024*10] = {0};
int cur_batch_data_index = 0;
// @TODO check last tint as well, do this when factor into drawing parameters
sg_image cur_batch_image = {0};
quad_fs_params_t cur_batch_params = {0};
void flush_quad_batch()
{
 if(cur_batch_image.id == 0 || cur_batch_data_index == 0) return; // flush called when image changes, image starts out null!
 state.bind.vertex_buffer_offsets[0] = sg_append_buffer(state.bind.vertex_buffers[0], &(sg_range){cur_batch_data, cur_batch_data_index*sizeof(*cur_batch_data)});
 state.bind.fs_images[SLOT_quad_tex] = cur_batch_image;
 sg_apply_bindings(&state.bind);
 sg_apply_uniforms(SG_SHADERSTAGE_FS, SLOT_quad_fs_params, &SG_RANGE(cur_batch_params));
 assert(cur_batch_data_index % 4 == 0);
 sg_draw(0, cur_batch_data_index/4, 1);
 num_draw_calls += 1;
 memset(cur_batch_data, 0, cur_batch_data_index);
 cur_batch_data_index = 0;
}

// The image region is in pixel space of the image
void draw_quad(bool world_space, Quad quad, sg_image image, AABB image_region, Color tint)
{
 quad_fs_params_t params = {0};
 params.tint[0] = tint.R;
 params.tint[1] = tint.G;
 params.tint[2] = tint.B;
 params.tint[3] = tint.A;

 if(image.id != cur_batch_image.id)
 {
  flush_quad_batch();
  cur_batch_image = image;
  cur_batch_params = params;
 }

 Vec2 *points = quad.points;

 if(world_space)
 {
  for(int i = 0; i < 4; i++)
  {
   points[i] = world_to_screen(points[i]);
  }
 }
 AABB cam_aabb =
 { .upper_left = V2(0.0, screen_size().Y), .lower_right = V2(screen_size().X, 0.0) };
 AABB points_bounding_box =
 { .upper_left = V2(INFINITY, -INFINITY), .lower_right = V2(-INFINITY, INFINITY) };

 for(int i = 0; i < 4; i++)
 {
  points_bounding_box.upper_left.X = fminf(points_bounding_box.upper_left.X, points[i].X);
  points_bounding_box.upper_left.Y = fmaxf(points_bounding_box.upper_left.Y, points[i].Y);

  points_bounding_box.lower_right.X = fmaxf(points_bounding_box.lower_right.X, points[i].X);
  points_bounding_box.lower_right.Y = fminf(points_bounding_box.lower_right.Y, points[i].Y);
 }
 if(!overlapping(cam_aabb, points_bounding_box))
 {
  //dbgprint("Out of screen, cam aabb %f %f %f %f\n", cam_aabb.upper_left.X, cam_aabb.upper_left.Y, cam_aabb.lower_right.X, cam_aabb.lower_right.Y);
  //dbgprint("Points boundig box %f %f %f %f\n", points_bounding_box.upper_left.X, points_bounding_box.upper_left.Y, points_bounding_box.lower_right.X, points_bounding_box.lower_right.Y);
  return; // cull out of screen quads
 }

 float new_vertices[ (2 + 2)*4 ];
 Vec2 region_size = SubV2(image_region.lower_right, image_region.upper_left);
 assert(region_size.X > 0.0);
 assert(region_size.Y > 0.0);
 Vec2 tex_coords[4] =
 {
  AddV2(image_region.upper_left, V2(0.0,                    0.0)),
  AddV2(image_region.upper_left, V2(region_size.X,           0.0)),
  AddV2(image_region.upper_left, V2(region_size.X, region_size.Y)),
  AddV2(image_region.upper_left, V2(0.0,           region_size.Y)),
 };

 // convert to uv space
 sg_image_info info = sg_query_image_info(image);
 for(int i = 0; i < 4; i++)
 {
  tex_coords[i] = DivV2(tex_coords[i], V2((float)info.width, (float)info.height));
 }
 for(int i = 0; i < 4; i++)
 {
  Vec2 zero_to_one = DivV2(points[i], screen_size());
  Vec2 in_clip_space = SubV2(MulV2F(zero_to_one, 2.0), V2(1.0, 1.0));
  new_vertices[i*4] = in_clip_space.X;
  new_vertices[i*4 + 1] = in_clip_space.Y;
  new_vertices[i*4 + 2] = tex_coords[i].X;
  new_vertices[i*4 + 3] = tex_coords[i].Y;
 }

 size_t total_size = ARRLEN(new_vertices)*sizeof(new_vertices);

 // batched a little too close to the sun
 if(cur_batch_data_index + total_size >= ARRLEN(cur_batch_data))
 {
  flush_quad_batch();
  cur_batch_image = image;
  cur_batch_params = params;
 }

#define PUSH_VERTEX(vert) { memcpy(&cur_batch_data[cur_batch_data_index], &vert, 4*sizeof(float)); cur_batch_data_index += 4; }
 PUSH_VERTEX(new_vertices[0*4]);
 PUSH_VERTEX(new_vertices[1*4]);
 PUSH_VERTEX(new_vertices[2*4]);
 PUSH_VERTEX(new_vertices[0*4]);
 PUSH_VERTEX(new_vertices[2*4]);
 PUSH_VERTEX(new_vertices[3*4]);
#undef PUSH_VERTEX

}

void swap(Vec2 *p1, Vec2 *p2)
{
 Vec2 tmp = *p1;
 *p1 = *p2;
 *p2 = tmp;
}

double anim_sprite_duration(AnimatedSprite *s)
{
 return s->num_frames * s->time_per_frame;
}

void draw_animated_sprite(AnimatedSprite *s, double elapsed_time, bool flipped, Vec2 pos, Color tint)
{
 sg_image spritesheet_img = *s->img;
 int index = (int)floor(elapsed_time/s->time_per_frame) % s->num_frames;
 if(s->no_wrap)
 {
  index = (int)floor(elapsed_time/s->time_per_frame);
  if(index >= s->num_frames) index = s->num_frames - 1;
 }

 Quad q = quad_centered(pos, s->region_size);

 if(flipped)
 {
  swap(&q.points[0], &q.points[1]);
  swap(&q.points[3], &q.points[2]);
 }

 AABB region;
 region.upper_left = AddV2(s->start, V2(index * s->horizontal_diff_btwn_frames, 0.0f));
 region.lower_right = V2(region.upper_left.X + (float)s->region_size.X, (float)s->region_size.Y);

 draw_quad(true, q, spritesheet_img, region, tint);
}



Vec2 tile_id_to_coord(sg_image tileset_image, Vec2 tile_size, uint16_t tile_id)
{
 int tiles_per_row = (int)(img_size(tileset_image).X / tile_size.X);
 int tile_index = tile_id - 1;
 int tile_image_row = tile_index / tiles_per_row;
 int tile_image_col = tile_index - tile_image_row*tiles_per_row;
 Vec2 tile_image_coord = V2((float)tile_image_col * tile_size.X, (float)tile_image_row*tile_size.Y);
 return tile_image_coord;
}

void colorquad(bool world_space, Quad q, Color col)
{
 draw_quad(world_space, q, image_white_square, full_region(image_white_square), col);
}

void dbgsquare(Vec2 at)
{
 colorquad(true, quad_centered(at, V2(10.0, 10.0)), RED);
}

// in world coordinates
void line(Vec2 from, Vec2 to, float line_width, Color color)
{
 Vec2 normal = rotate_counter_clockwise(NormV2(SubV2(to, from)));
 Quad line_quad = {
  .points = {
   AddV2(from, MulV2F(normal, line_width)),  // upper left
   AddV2(to, MulV2F(normal, line_width)),    // upper right
   AddV2(to, MulV2F(normal, -line_width)),   // lower right
   AddV2(from, MulV2F(normal, -line_width)), // lower left
  }
 };
 colorquad(true, line_quad, color);
}

void dbgline(Vec2 from, Vec2 to)
{
#ifdef DEVTOOLS
 line(from, to, 2.0f, RED);
#else
 (void)from;
 (void)to;
#endif
}

// in world space
void dbgrect(AABB rect)
{
#ifdef DEVTOOLS
 const float line_width = 0.5;
 const Color col = RED;
 Quad q = quad_aabb(rect);
 line(q.ul, q.ur, line_width, col);
 line(q.ur, q.lr, line_width, col);
 line(q.lr, q.ll, line_width, col);
 line(q.ll, q.ul, line_width, col);
#else
 (void)rect;
#endif
}


// returns bounds. To measure text you can set dry run to true and get the bounds
AABB draw_text(bool world_space, bool dry_run, const char *text, Vec2 pos, Color color, float scale)
{
 size_t text_len = strlen(text);
 AABB bounds = {0};
 float y = 0.0;
 float x = 0.0;
 for(int i = 0; i < text_len; i++)
 {
  stbtt_aligned_quad q;
  float old_y = y;
  stbtt_GetBakedQuad(cdata, 512, 512, text[i]-32, &x, &y, &q, 1);
  float difference = y - old_y;
  y = old_y + difference;

  Vec2 size = V2(q.x1 - q.x0, q.y1 - q.y0);
  if(text[i] == '\n')
  {
#ifdef DEVTOOLS
   y += font_size*0.75f; // arbitrary, only debug text has newlines
   x = 0.0;
#else
   assert(false);
#endif
  }
  if(size.Y > 0.0 && size.X > 0.0)
  { // spaces (and maybe other characters) produce quads of size 0
   Quad to_draw = {
   .points = {
     AddV2(V2(q.x0, -q.y0), V2(0.0f, 0.0f)),
     AddV2(V2(q.x0, -q.y0), V2(size.X, 0.0f)),
     AddV2(V2(q.x0, -q.y0), V2(size.X, -size.Y)),
     AddV2(V2(q.x0, -q.y0), V2(0.0f, -size.Y)),
    },
   };

   for(int i = 0; i < 4; i++)
   {
    to_draw.points[i] = MulV2F(to_draw.points[i], scale);
   }

   AABB font_atlas_region = (AABB)
   {
    .upper_left  = V2(q.s0, q.t0),
     .lower_right = V2(q.s1, q.t1),
   };
   font_atlas_region.upper_left.X *= img_size(image_font).X;
   font_atlas_region.lower_right.X *= img_size(image_font).X;
   font_atlas_region.upper_left.Y *= img_size(image_font).Y;
   font_atlas_region.lower_right.Y *= img_size(image_font).Y;

   for(int i = 0; i < 4; i++)
   {
    bounds.upper_left.X = fminf(bounds.upper_left.X, to_draw.points[i].X);
    bounds.upper_left.Y = fmaxf(bounds.upper_left.Y, to_draw.points[i].Y);
    bounds.lower_right.X = fmaxf(bounds.lower_right.X, to_draw.points[i].X);
    bounds.lower_right.Y = fminf(bounds.lower_right.Y, to_draw.points[i].Y);
   }

   for(int i = 0; i < 4; i++)
   {
    to_draw.points[i] = AddV2(to_draw.points[i], pos);
   }

   if(!dry_run)
   {
    draw_quad(world_space, to_draw, image_font, font_atlas_region, color);
   }
  }
 }

 bounds.upper_left = AddV2(bounds.upper_left, pos);
 bounds.lower_right = AddV2(bounds.lower_right, pos);
 return bounds;
}

// gets aabbs overlapping the input aabb, including entities and tiles
Overlapping get_overlapping(Level *l, AABB aabb)
{
 Overlapping to_return = {0};
 
 Quad q = quad_aabb(aabb);
 // the corners, jessie
 for(int i = 0; i < 4; i++)
 {
  TileInstance t = get_tile(l, world_to_tilecoord(q.points[i]));
  if(is_tile_solid(t))
  {
   to_return.results[to_return.num_results++] = (Overlap)
    {
     .is_tile = true,
     .t = t
    };
   assert(to_return.num_results < ARRLEN(to_return.results));
  }
 }

 // the entities jessie
 ENTITIES_ITER(entities)
 {
  if(!(it->kind == ENTITY_PLAYER && it->is_rolling) && overlapping(aabb, entity_aabb(it)))
  {
   to_return.results[to_return.num_results++] = (Overlap)
   {
    .e = it,
   };
   assert(to_return.num_results < ARRLEN(to_return.results));
  }
 }

 return to_return;
}

// returns new pos after moving and sliding against collidable things
Vec2 move_and_slide(Entity *from, Vec2 position, Vec2 movement_this_frame)
{
 Vec2 collision_aabb_size = entity_aabb_size(from);
 Vec2 new_pos = AddV2(position, movement_this_frame);
 AABB at_new = centered_aabb(new_pos, collision_aabb_size);
 dbgrect(at_new);
 AABB to_check[256] = {0};
 int to_check_index = 0;

 // add tilemap boxes
 {
  Vec2 at_new_size_vector = SubV2(at_new.lower_right, at_new.upper_left);
  Vec2 points_to_check[] = {
   AddV2(at_new.upper_left, V2(0.0, 0.0)),
   AddV2(at_new.upper_left, V2(at_new_size_vector.X, 0.0)),
   AddV2(at_new.upper_left, V2(at_new_size_vector.X, at_new_size_vector.Y)),
   AddV2(at_new.upper_left, V2(0.0, at_new_size_vector.Y)),
  };
  for(int i = 0; i < ARRLEN(points_to_check); i++)
  {
   Vec2 *it = &points_to_check[i];
   TileCoord tilecoord_to_check = world_to_tilecoord(*it);

   if(is_tile_solid(get_tile(&level_level0, tilecoord_to_check)))
   {
    to_check[to_check_index++] = tile_aabb(tilecoord_to_check);
    assert(to_check_index < ARRLEN(to_check));
   }
  }
 }

 // add entity boxes
 if(!(from->kind == ENTITY_PLAYER && from->is_rolling))
 {
  ENTITIES_ITER(entities)
  {
   if(!(it->kind == ENTITY_PLAYER && it->is_rolling) && it != from)
   {
    to_check[to_check_index++] = centered_aabb(it->pos, entity_aabb_size(it));
    assert(to_check_index < ARRLEN(to_check));
   }
  }
 }
 for(int i = 0; i < to_check_index; i++)
 {
  AABB to_depenetrate_from = to_check[i];
  dbgrect(to_depenetrate_from);
  int iters_tried_to_push_apart = 0;
  while(overlapping(to_depenetrate_from, at_new) && iters_tried_to_push_apart < 500)
  { 
   //dbgsquare(to_depenetrate_from.upper_left);
   //dbgsquare(to_depenetrate_from.lower_right);
   const float move_dist = 0.05f;

   Vec2 to_player = NormV2(SubV2(aabb_center(at_new), aabb_center(to_depenetrate_from)));
   Vec2 compass_dirs[4] = {
    V2( 1.0, 0.0),
    V2(-1.0, 0.0),
    V2(0.0,  1.0),
    V2(0.0, -1.0),
   };
   int closest_index = -1;
   float closest_dot = -99999999.0f;
   for(int i = 0; i < 4; i++)
   {
    float dot = DotV2(compass_dirs[i], to_player);
    if(dot > closest_dot)
    {
     closest_index = i;
     closest_dot = dot;
    }
   }
   assert(closest_index != -1);
   Vec2 move_dir = compass_dirs[closest_index];
   Vec2 move = MulV2F(move_dir, move_dist);
   at_new.upper_left = AddV2(at_new.upper_left,move);
   at_new.lower_right = AddV2(at_new.lower_right,move);
   iters_tried_to_push_apart++;
  }
 }

 return aabb_center(at_new);
}

// returns next vertical cursor position
float draw_wrapped_text(Vec2 at_point, float max_width, char *text, float text_scale, Color color)
{
 char *sentence_to_draw = text;
 size_t sentence_len = strlen(sentence_to_draw);

 Vec2 cursor = at_point;
 while(sentence_len > 0)
 {
  char line_to_draw[MAX_SENTENCE_LENGTH] = {0};
  size_t chars_from_sentence = 0;
  AABB line_bounds = {0};
  while(chars_from_sentence <= sentence_len)
  {
   memset(line_to_draw, 0, MAX_SENTENCE_LENGTH);
   memcpy(line_to_draw, sentence_to_draw, chars_from_sentence);

   line_bounds = draw_text(true, true, line_to_draw, cursor, color, text_scale);
   if(line_bounds.lower_right.X > at_point.X + max_width)
   {
    // too big
    assert(chars_from_sentence > 0);
    chars_from_sentence -= 1;
    break;
   }

   chars_from_sentence += 1;
  }
  if(chars_from_sentence > sentence_len) chars_from_sentence--;
  memset(line_to_draw, 0, MAX_SENTENCE_LENGTH);
  memcpy(line_to_draw, sentence_to_draw, chars_from_sentence);
  float line_height = line_bounds.upper_left.Y - line_bounds.lower_right.Y;
  AABB drawn_bounds = draw_text(true, false, line_to_draw, AddV2(cursor, V2(0.0f, -line_height)), color, text_scale);
  dbgrect(drawn_bounds);

  sentence_len -= chars_from_sentence;
  sentence_to_draw += chars_from_sentence;
  cursor = V2(drawn_bounds.upper_left.X, drawn_bounds.lower_right.Y);
 }

 return cursor.Y;
}

double elapsed_time = 0.0;
double last_frame_processing_time = 0.0;
uint64_t last_frame_time;
Vec2 mouse_pos = {0}; // in screen space
bool keydown[SAPP_KEYCODE_MENU] = {0};
#ifdef DEVTOOLS
bool mouse_frozen = false;
#endif
void frame(void)
{
#if 0
 {
  sg_begin_default_pass(&state.pass_action, sapp_width(), sapp_height());
  sg_apply_pipeline(state.pip);

  //colorquad(false, quad_at(V2(0.0, 100.0), V2(100.0f, 100.0f)), RED);
  sg_image img = image_wonky_mystery_tile;
  AABB region = full_region(img);
  //region.lower_right.X *= 0.5f;
  draw_quad(false,quad_at(V2(0.0, 100.0), V2(100.0f, 100.0f)), img, region, WHITE);

  sg_end_pass();
  sg_commit();
  reset(&scratch);
 }
 return;
#endif

 uint64_t time_start_frame = stm_now();
 // elapsed_time
 double dt_double = 0.0;
 {
  dt_double = stm_sec(stm_diff(stm_now(), last_frame_time));
  dt_double = fmin(dt_double, 5.0 / 60.0); // clamp dt at maximum 5 frames, avoid super huge dt
  elapsed_time += dt_double;
  last_frame_time = stm_now();
 }
 float dt = (float)dt_double;

 Vec2 movement = V2(
  (float)keydown[SAPP_KEYCODE_D] - (float)keydown[SAPP_KEYCODE_A],
  (float)keydown[SAPP_KEYCODE_W] - (float)keydown[SAPP_KEYCODE_S]
 );
 bool attack = keydown[SAPP_KEYCODE_J];
 bool roll = keydown[SAPP_KEYCODE_K];
 if(LenV2(movement) > 1.0)
 {
  movement = NormV2(movement);
 }
 sg_begin_default_pass(&state.pass_action, sapp_width(), sapp_height());
 sg_apply_pipeline(state.pip);


 // tilemap
#if 1
 Level * cur_level = &level_level0;

 for(int row = 0; row < LEVEL_TILES; row++)
 {
  for(int col = 0; col < LEVEL_TILES; col++)

  {
   TileCoord cur_coord = { col, row };
   TileInstance cur = get_tile(cur_level, cur_coord);
   TileSet tileset = tileset_ruins_animated;
   if(cur.kind != 0)
   {
    Vec2 tile_size = V2(TILE_SIZE, TILE_SIZE);

    sg_image tileset_image = *tileset.img;

    Vec2 tile_image_coord = tile_id_to_coord(tileset_image, tile_size, cur.kind);

    AnimatedTile *anim = NULL;
    for(int i = 0; i < sizeof(tileset.animated)/sizeof(*tileset.animated); i++)
    {
     if(tileset.animated[i].id_from == cur.kind-1)
     {
      anim = &tileset.animated[i];
     }
    }
    if(anim)
    {
     double time_per_frame = 0.1;
     int frame_index = (int)(elapsed_time/time_per_frame) % anim->num_frames;
     tile_image_coord = tile_id_to_coord(tileset_image, tile_size, anim->frames[frame_index]+1);
    }

    AABB region;
    region.upper_left = tile_image_coord;
    region.lower_right = AddV2(region.upper_left, tile_size);

    draw_quad(true, tile_quad(cur_coord), tileset_image, region, WHITE);
   }
  }
 }
#endif

 assert(player != NULL);

#ifdef DEVTOOLS
  dbgsquare(screen_to_world(mouse_pos));
  
  // tile coord
  {
   TileCoord hovering = world_to_tilecoord(screen_to_world(mouse_pos));
   Vec2 points[4] ={0};
   AABB q = tile_aabb(hovering);
   dbgrect(q);
   draw_text(false, false, tprint("%d", get_tile(&level_level0, hovering).kind), world_to_screen(tilecoord_to_world(hovering)), BLACK, 1.0f);
  }

  // debug draw font image
  {
   draw_quad(true, quad_centered(V2(0.0, 0.0), V2(250.0, 250.0)), image_font,full_region(image_font), WHITE);
  }

  // statistics
  {
   Vec2 pos = V2(0.0, screen_size().Y);
   int num_entities = 0;
   ENTITIES_ITER(entities) num_entities++;
   char *stats = tprint("Frametime: %.1f ms\nProcessing: %.1f ms\nEntities: %d\nDraw calls: %d\n", dt*1000.0, last_frame_processing_time*1000.0, num_entities, num_draw_calls);
   AABB bounds = draw_text(false, true, stats, pos, BLACK, 1.0f);
   pos.Y -= bounds.upper_left.Y - screen_size().Y;
   bounds = draw_text(false, true, stats, pos, BLACK, 1.0f);
   // background panel
   colorquad(false, quad_aabb(bounds), (Color){1.0, 1.0, 1.0, 0.3f});
   draw_text(false, false, stats, pos, BLACK, 1.0f);
   num_draw_calls = 0;
  }
#endif // devtools

  // entities
  ENTITIES_ITER(entities)
  {
   if(it->kind == ENTITY_OLD_MAN)
   {
    if(it->aggressive)
    {
     Entity *targeting = player;
     it->shotgun_timer += dt;
     Vec2 to_player = NormV2(SubV2(targeting->pos, it->pos));
     if(it->shotgun_timer >= 1.0f)
     {
      it->shotgun_timer = 0.0f;
      const float spread = (float)PI/4.0f;
      // shoot shotgun
      for(int i = 0; i < 3; i++)
      {
       Vec2 dir = to_player;
       float theta = Lerp(-spread/2.0f, ((float)i / 2.0f), spread/2.0f);
       dir = RotateV2(dir, theta);
       Entity *new_bullet = new_entity();
       new_bullet->kind = ENTITY_BULLET;
       new_bullet->pos = AddV2(it->pos, MulV2F(dir, 20.0f));
       new_bullet->vel = MulV2F(dir, 10.0f);
       it->vel = AddV2(it->vel, MulV2F(dir, -3.0f));
      }
     }

     Vec2 target_vel = NormV2(AddV2(rotate_counter_clockwise(to_player), MulV2F(to_player, 0.5f)));
     target_vel = MulV2F(target_vel, 3.0f);
     it->vel = LerpV2(it->vel, 15.0f * dt, target_vel);
     it->pos = move_and_slide(it, it->pos, MulV2F(it->vel, pixels_per_meter * dt));
    }
    draw_animated_sprite(&old_man_idle, elapsed_time, false, it->pos, WHITE);
   }
   else if (it->kind == ENTITY_BULLET)
   {
    it->pos = AddV2(it->pos, MulV2F(it->vel, pixels_per_meter * dt));
    draw_quad(true, quad_aabb(entity_aabb(it)), image_white_square, full_region(image_white_square), WHITE);
    Overlapping over = get_overlapping(cur_level, entity_aabb(it));
    for(int i = 0; i < over.num_results; i++) if(over.results[i].e != it)
    {
     if(!over.results[i].is_tile)
     {
      // knockback and damage
      Entity *hit = over.results[i].e;
      if(hit->kind == ENTITY_OLD_MAN) hit->aggressive = true;
      hit->vel = MulV2F(NormV2(SubV2(hit->pos, it->pos)), 5.0f);
      hit->damage += 0.2f;
      *it = (Entity){0};
     }
    }
    if(!has_point(level_aabb, it->pos)) *it = (Entity){0};
   }
   else if(it->kind == ENTITY_PLAYER)
   {
   }
   else
   {
    assert(false);
   }
  }

  // process player character
  {
   Vec2 character_sprite_pos = AddV2(player->pos, V2(0.0, 20.0f));

   if(attack && (player->state == CHARACTER_IDLE || player->state == CHARACTER_WALKING))
   {
    player->state = CHARACTER_ATTACK;
    player->swing_progress = 0.0;
   }

   // rolling
   if(roll && !player->is_rolling && player->time_not_rolling > 0.3f && (player->state == CHARACTER_IDLE || player->state == CHARACTER_WALKING))
   {
    player->is_rolling = true;
    player->roll_progress = 0.0;
    player->speed = PLAYER_ROLL_SPEED;
   }
   if(player->state != CHARACTER_IDLE && player->state != CHARACTER_WALKING)
   {
    player->roll_progress = 0.0;
    player->is_rolling = false;
   }
   if(player->is_rolling)
   {
    player->time_not_rolling = 0.0f;
    player->roll_progress += dt;
    if(player->roll_progress > anim_sprite_duration(&knight_rolling))
    {
     player->is_rolling = false;
    }
   }
   if(!player->is_rolling) player->time_not_rolling += dt;

   cam.pos = LerpV2(cam.pos, dt*8.0f, MulV2F(player->pos, -1.0f * cam.scale));
   if(player->state == CHARACTER_WALKING)
   {
    if(player->speed <= 0.01f) player->speed = PLAYER_SPEED;
    player->speed = Lerp(player->speed, dt * 3.0f, PLAYER_SPEED);
    player->pos = move_and_slide(player, player->pos, MulV2F(movement, dt * pixels_per_meter * player->speed));
    if(player->is_rolling)
    {
     draw_animated_sprite(&knight_rolling, player->roll_progress, player->facing_left, character_sprite_pos, WHITE);
    }
    else
    {
     draw_animated_sprite(&knight_running, elapsed_time, player->facing_left, character_sprite_pos, WHITE);
    }

    if(LenV2(movement) == 0.0)
    {
     player->state = CHARACTER_IDLE;
    }
    else
    {
     player->facing_left = movement.X < 0.0f;
    }
   }
   else if(player->state == CHARACTER_IDLE)
   {
    if(player->is_rolling)
    {
     draw_animated_sprite(&knight_rolling, player->roll_progress, player->facing_left, character_sprite_pos, WHITE);
    }
    else
    {
     draw_animated_sprite(&knight_idle, elapsed_time, player->facing_left, character_sprite_pos, WHITE);
    }
    if(LenV2(movement) > 0.01) player->state = CHARACTER_WALKING;
   }
   else if(player->state == CHARACTER_ATTACK)
   {
    AABB weapon_aabb = {0};
    if(player->facing_left)
    {
     weapon_aabb = (AABB){
      .upper_left = AddV2(player->pos, V2(-40.0, 25.0)),
      .lower_right = AddV2(player->pos, V2(0.0, -25.0)),
     };
    }
    else
    {
     weapon_aabb = (AABB){
      .upper_left = AddV2(player->pos, V2(0.0, 25.0)),
      .lower_right = AddV2(player->pos, V2(40.0, -25.0)),
     };
    }
    dbgrect(weapon_aabb);
    Overlapping overlapping_weapon = get_overlapping(cur_level, weapon_aabb);
    for(int i = 0; i < overlapping_weapon.num_results; i++)
    {
     if(!overlapping_weapon.results[i].is_tile)
     {
      Entity *e = overlapping_weapon.results[i].e;
      if(e->kind == ENTITY_OLD_MAN)
      {
       e->aggressive = true;
      }
     }
    }

    player->swing_progress += dt;
    draw_animated_sprite(&knight_attack, player->swing_progress, player->facing_left, character_sprite_pos, WHITE);
    if(player->swing_progress > anim_sprite_duration(&knight_attack))
    {
     player->state = CHARACTER_IDLE;
    }
   }

   // health
   if(player->damage >= 1.0)
   {
    reset_level();
   }
   else
   {
    draw_quad(false, (Quad){.ul=V2(0.0f, screen_size().Y), .ur = screen_size(), .lr = V2(screen_size().X, 0.0f)}, image_hurt_vignette, full_region(image_hurt_vignette), (Color){1.0f, 1.0f, 1.0f, player->damage});
   }
  }

  // do dialog
  AABB dialog_rect = centered_aabb(player->pos, V2(TILE_SIZE*2.0f, TILE_SIZE*2.0f));
  dbgrect(dialog_rect);
  Overlapping possible_dialogs = get_overlapping(cur_level, dialog_rect);
  Entity *closest_talkto = NULL;
  float closest_talkto_dist = INFINITY;
  for(int i = 0; i < possible_dialogs.num_results; i++)
  {
   Overlap *it = &possible_dialogs.results[i];
   if(!it->is_tile && it->e->kind == ENTITY_OLD_MAN && !it->e->aggressive)
   {
    float dist = LenV2(SubV2(it->e->pos, player->pos));
    if(dist < closest_talkto_dist)
    {
     closest_talkto_dist = dist;
     closest_talkto = it->e;
    }
   }
  }
  if(closest_talkto != NULL)
  {
   draw_quad(true, quad_centered(closest_talkto->pos, V2(TILE_SIZE, TILE_SIZE)), image_dialog_circle, full_region(image_dialog_circle), WHITE);

   Dialog dialog = {
    .sentences[0].text = "I'm an old man. fjdslfdasljfla dsfjdsalkf adskjfdlskfkladsjfkljdskljsadlkfjdsaklfjldsajf",
    .sentences[1].text = "I'm the player. I have lots of things to say. Bla bla bla. All I do is say things. How cringe and terrible",
   };
   float panel_width = 250.0f;
   float panel_height = 100.0f;
   float panel_vert_offset = 30.0f;
   AABB dialog_panel = (AABB){
    .upper_left = AddV2(closest_talkto->pos, V2(-panel_width/2.0f, panel_vert_offset+panel_height)),
    .lower_right = AddV2(closest_talkto->pos, V2(panel_width/2.0f, panel_vert_offset)),
   };
   colorquad(true, quad_aabb(dialog_panel), (Color){1.0f, 1.0f, 1.0f, 0.2f});

   float new_line_height = draw_wrapped_text(dialog_panel.upper_left, dialog_panel.lower_right.X - dialog_panel.upper_left.X, dialog.sentences[0].text, 0.5f, WHITE);
   new_line_height = draw_wrapped_text(V2(dialog_panel.upper_left.X, new_line_height), dialog_panel.lower_right.X - dialog_panel.upper_left.X, dialog.sentences[1].text, 0.5f, GREEN);

   dbgrect(dialog_panel);
  }

  flush_quad_batch();
  sg_end_pass();
  sg_commit();

  last_frame_processing_time = stm_sec(stm_diff(stm_now(),time_start_frame));

  reset(&scratch);
}
void cleanup(void)
{
 sg_shutdown();
}

void event(const sapp_event *e)
{
 if(e->type == SAPP_EVENTTYPE_KEY_DOWN)
 {
  assert(e->key_code < sizeof(keydown)/sizeof(*keydown));
  keydown[e->key_code] = true;
  if(e->key_code == SAPP_KEYCODE_ESCAPE)
  {
   sapp_quit();
  }
#ifdef DEVTOOLS
  if(e->key_code == SAPP_KEYCODE_T)
  {
   mouse_frozen = !mouse_frozen;
  }
#endif
 }
 if(e->type == SAPP_EVENTTYPE_KEY_UP)
 {
  keydown[e->key_code] = false;
 }
 if(e->type == SAPP_EVENTTYPE_MOUSE_MOVE)
 {
  bool ignore_movement = false;
#ifdef DEVTOOLS
  if(mouse_frozen) ignore_movement = true;
#endif
  if(!ignore_movement) mouse_pos = V2(e->mouse_x, (float)sapp_height() - e->mouse_y);
 }
}

sapp_desc sokol_main(int argc, char* argv[])
{
 (void)argc; (void)argv;
 return (sapp_desc){
  .init_cb = init,
   .frame_cb = frame,
   .cleanup_cb = cleanup,
   .event_cb = event,
   .width = 800,
   .height = 600,
   //.gl_force_gles2 = true, not sure why this was here in example, look into
   .window_title = "RPGPT",
   .win32_console_attach = true,
   .icon.sokol_default = true,
 };
}