software_rasterizer/sf_main.cpp

#include "assets_obj_dump.cpp"
#include "sf_vec.cpp"
#include "sf_work_queue.cpp"
#define PROFILE_SCOPE(x)
#define MULTITHREADING 1

struct Vertex {
  Vec3 pos;
  Vec2 tex;
  Vec3 norm;
};

struct Render_Command{
  Bitmap *src;
  Vec4 p0, p1, p2;
  Vec2 tex0, tex1, tex2;
};

struct Render {
  Mat4 camera;
  Mat4 projection;
  Mat4 transform;

  Vec3 camera_pos;
  Vec3 camera_direction;
  Vec3 camera_forward_velocity;
  Vec2 camera_yaw;
  Vec3 camera_target;
  Bitmap img;
  B32 plot_ready;
  Bitmap plot;
  Bitmap screen320;
  F32 *depth320;

  WorkQueue work_queue;
  Array_List<Render_Command> commands;
};

struct Render_Tile_Job_Data{
  Render *r;
  Rect2 region;
};

enum Scene {
  Scene_F22,
  Scene_Sponza,
  Scene_Count,
};

global F32 light_rotation = 0;
global F32 zfar_value = 100000.f;

function
Vec4 srgb_to_almost_linear(Vec4 a) {
  Vec4 result = {a.r*a.r, a.g*a.g, a.b*a.b, a.a};
  return result; // @Note: Linear would be to power of 2.2
}

function
Vec4 almost_linear_to_srgb(Vec4 a) {
  Vec4 result = { sqrtf(a.r), sqrtf(a.g), sqrtf(a.b), a.a };
  return result;
}

function
Vec4 premultiplied_alpha(Vec4 dst, Vec4 src) {
  Vec4 result;
  result.r = src.r + ((1-src.a) * dst.r);
  result.g = src.g + ((1-src.a) * dst.g);
  result.b = src.b + ((1-src.a) * dst.b);
  result.a = src.a + dst.a - src.a*dst.a;
  return result;
}

function
void draw_rect(Bitmap* dst, F32 X, F32 Y, F32 w, F32 h, Vec4 color) {
  int max_x = (int)(min(X + w, (F32)dst->x) + 0.5f);
  int max_y = (int)(min(Y + h, (F32)dst->y) + 0.5f);
  int min_x = (int)(max(0.f, X) + 0.5f);
  int min_y = (int)(max(0.f, Y) + 0.5f);

  color.rgb *= color.a;
  color = srgb_to_almost_linear(color);
  for (int y = min_y; y < max_y; y++) {
    for (int x = min_x; x < max_x; x++) {
      U32 *dst_pixel = dst->pixels + (x + y * dst->x);
      Vec4 dstc = srgb_to_almost_linear(vec4abgr(*dst_pixel));
      dstc = premultiplied_alpha(dstc, color);
      U32 color32 = vec4_to_u32abgr(almost_linear_to_srgb(dstc));
      *dst_pixel = color32;
    }
  }
}

function void
draw_bitmap(Bitmap *dst, Bitmap *src, Vec2 pos){
  S64 minx = (S64)(pos.x + 0.5);
  S64 miny = (S64)(pos.y + 0.5);
  S64 maxx = minx + src->x;
  S64 maxy = miny + src->y;
  S64 offsetx = 0;
  S64 offsety = 0;

  if (maxx > dst->x) {
    maxx = dst->x;
  }
  if (maxy > dst->y) {
    maxy = dst->y;
  }
  if (minx < 0) {
    offsetx = -minx;
    minx = 0;
  }
  if (miny < 0) {
    offsety = -miny;
    miny = 0;
  }
  for (S64 y = miny; y < maxy; y++) {
    for (S64 x = minx; x < maxx; x++) {
      S64 tx = x - minx + offsetx;
      S64 ty = y - miny + offsety;
      U32 *dst_pixel = dst->pixels + (x + y * dst->x);
      U32 *pixel     = src->pixels + (tx + ty * src->x);
      Vec4 result_color = srgb_to_almost_linear(vec4abgr(*pixel));
      Vec4 dst_color = srgb_to_almost_linear(vec4abgr(*dst_pixel));
      result_color = premultiplied_alpha(dst_color, result_color);
      result_color = almost_linear_to_srgb(result_color);
      U32 color32 = vec4_to_u32abgr(result_color);
      *dst_pixel = color32;
    }
  }
}

function
void draw_bitmap(Bitmap* dst, Bitmap* src, Vec2 pos, Vec2 size) {
  S64 minx = (S64)(pos.x + 0.5);
  S64 miny = (S64)(pos.y + 0.5);
  S64 maxx = minx + (S64)(size.x + 0.5f);
  S64 maxy = miny + (S64)(size.y + 0.5f);
  S64 offsetx = 0;
  S64 offsety = 0;
  maxx = clamp_top(maxx, (S64)dst->x);
  maxy = clamp_top(maxy, (S64)dst->y);
  if (minx < 0) {
    offsetx = -minx;
    minx = 0;
  }
  if (miny < 0) {
    offsety = -miny;
    miny = 0;
  }

  F32 distx = (F32)(maxx - minx);
  F32 disty = (F32)(maxy - miny);
  for (S64 y = miny; y < maxy; y++) {
    for (S64 x = minx; x < maxx; x++) {
      F32 u = (F32)(x - minx) / distx;
      F32 v = (F32)(y - miny) / disty;
      S64 tx = (S64)(u * src->x + 0.5f);
      S64 ty = (S64)(v * src->y + 0.5f);
      U32 *dst_pixel = dst->pixels + (x + y * dst->x);
      U32 *pixel     = src->pixels + (tx + ty * src->x);
      Vec4 result_color = srgb_to_almost_linear(vec4abgr(*pixel));
      Vec4 dst_color = srgb_to_almost_linear(vec4abgr(*dst_pixel));
      result_color = premultiplied_alpha(dst_color, result_color);
      result_color = almost_linear_to_srgb(result_color);
      U32 color32 = vec4_to_u32abgr(result_color);
      *dst_pixel = color32;
    }
  }
}

function
Vec4 base_string(Bitmap *dst, Font *font, String word, Vec2 pos, B32 draw) {
  Vec2 og_position = pos;
  F32 max_x = pos.x;
  for (U64 i = 0; i < word.len; i++) {
    if (word.str[i] == ' ') {
      FontGlyph* g = &font->glyphs['_' - '!'];
      pos.x += g->xadvance;
      if (pos.x > max_x) max_x = pos.x;
    }
    else if (word.str[i] == '\n') {
      pos.y -= font->line_advance;
      pos.x = og_position.x;
    }
    else if((word.str[i] >= '!' && word.str[i] <= 127)){
      FontGlyph* g = &font->glyphs[word.str[i] - '!'];
      if(draw) draw_bitmap(dst, &g->bitmap, pos - g->bitmap.align);
      pos.x += g->xadvance;
      if (pos.x > max_x) max_x = pos.x;
    }
  }
  Vec4 rect = vec4(og_position.x, pos.y, max_x - og_position.x, og_position.y - pos.y + font->line_advance);
  return rect;
}

function
Vec4 draw_string(Bitmap *dst, Font *font, String word, Vec2 pos) {
  return base_string(dst, font, word, pos, true);
}

function
Vec4 get_string_rect(Font *font, String word, Vec2 pos) {
  return base_string(0, font, word, pos, false);
}

function
F32 edge_function(Vec4 vecp0, Vec4 vecp1, Vec4 p) {
  F32 result = (vecp1.y - vecp0.y) * (p.x - vecp0.x) - (vecp1.x - vecp0.x) * (p.y - vecp0.y);
  return result;
}

#define F32x8 __m256
#define S32x8 __m256i

S32 render_triangle_test_case_number = 5;
S32 render_triangle_test_case_angle = -1;
U64 filled_pixel_count;
U64 filled_pixel_cycles;
U64 triangle_count;
#include "sf_optimization_log.cpp"


function
void draw_triangle_nearest(Bitmap* dst, F32 *depth_buffer, Bitmap *src,
                           Vec4 p0,   Vec4 p1,   Vec4 p2,
                           Vec2 tex0, Vec2 tex1, Vec2 tex2, Rect2 rect) {
  if(src->pixels == 0) return;

  // U64 fill_pixels_begin = __rdtsc();

  F32 min_x1 = (F32)(min(p0.x, min(p1.x, p2.x)));
  F32 min_y1 = (F32)(min(p0.y, min(p1.y, p2.y)));
  F32 max_x1 = (F32)(max(p0.x, max(p1.x, p2.x)));
  F32 max_y1 = (F32)(max(p0.y, max(p1.y, p2.y)));

  S64 min_x = (S64)max(rect.min_x, floor(min_x1));
  S64 min_y = (S64)max(rect.min_y, floor(min_y1));
  S64 max_x = (S64)min(rect.max_x, ceil(max_x1));
  S64 max_y = (S64)min(rect.max_y, ceil(max_y1));

  if (min_y >= max_y) return;
  if (min_x >= max_x) return;

  F32 dy10 = (p1.y - p0.y);
  F32 dy21 = (p2.y - p1.y);
  F32 dy02 = (p0.y - p2.y);

  F32 dx10 = (p1.x - p0.x);
  F32 dx21 = (p2.x - p1.x);
  F32 dx02 = (p0.x - p2.x);

  F32x8 var255 = _mm256_set1_ps(255);
  F32x8 var0 = _mm256_set1_ps(0);
  F32x8 var1 = _mm256_set1_ps(1);
  F32x8 var_max_x = _mm256_set1_ps(max_x);
  F32x8 var07 = _mm256_set_ps(7,6,5,4,3,2,1,0);
  F32x8 inv255 = _mm256_div_ps(var1, var255);

  F32x8 var_src_x_minus_one = _mm256_set1_ps(src->x-1);
  F32x8 var_src_y_minus_one = _mm256_set1_ps(src->y-1);
  S32x8 var_src_y_minus_one_int = _mm256_set1_epi32(src->y-1);
  S32x8 var_src_x_int = _mm256_set1_epi32(src->x);

  S32x8 var_0xff000000 = _mm256_set1_epi32(0xff000000);
  S32x8 var_0x00ff0000 = _mm256_set1_epi32(0x00ff0000);
  S32x8 var_0x0000ff00 = _mm256_set1_epi32(0x0000ff00);
  S32x8 var_0x000000ff = _mm256_set1_epi32(0x000000ff);

  F32x8 var_tex0x = _mm256_set1_ps(tex0.x);
  F32x8 var_tex1x = _mm256_set1_ps(tex1.x);
  F32x8 var_tex2x = _mm256_set1_ps(tex2.x);
  F32x8 var_tex0y = _mm256_set1_ps(tex0.y);
  F32x8 var_tex1y = _mm256_set1_ps(tex1.y);
  F32x8 var_tex2y = _mm256_set1_ps(tex2.y);

  F32x8 inv_p0w = _mm256_div_ps(var1, _mm256_set1_ps(p0.w));
  F32x8 inv_p1w = _mm256_div_ps(var1, _mm256_set1_ps(p1.w));
  F32x8 inv_p2w = _mm256_div_ps(var1, _mm256_set1_ps(p2.w));
  F32x8 one_over_p0w = _mm256_set1_ps(1.f / p0.w);
  F32x8 one_over_p1w = _mm256_set1_ps(1.f / p1.w);
  F32x8 one_over_p2w = _mm256_set1_ps(1.f / p2.w);

  U32 *destination = dst->pixels + dst->x*min_y;
  F32 area = (p1.y - p0.y) * (p2.x - p0.x) - (p1.x - p0.x) * (p2.y - p0.y);
  F32x8 inv_area8 = _mm256_div_ps(var1, _mm256_set1_ps(area));

  F32x8 _dy10 = _mm256_set1_ps(dy10);
  F32x8 _dx10 = _mm256_set1_ps(dx10);
  F32x8 _dy21 = _mm256_set1_ps(dy21);
  F32x8 _dx21 = _mm256_set1_ps(dx21);
  F32x8 _dy02 = _mm256_set1_ps(dy02);
  F32x8 _dx02 = _mm256_set1_ps(dx02);
  F32x8 p0_x = _mm256_set1_ps(p0.x);
  F32x8 p0_y = _mm256_set1_ps(p0.y);
  F32x8 p1_x = _mm256_set1_ps(p1.x);
  F32x8 p1_y = _mm256_set1_ps(p1.y);
  F32x8 p2_x = _mm256_set1_ps(p2.x);
  F32x8 p2_y = _mm256_set1_ps(p2.y);

  for (S64 y = min_y; y < max_y; y++) {
    F32x8 Y = _mm256_set1_ps(y);
    for (S64 x8 = min_x; x8 < max_x; x8+=8) {
      F32x8 X = _mm256_add_ps(_mm256_set1_ps(x8), var07);

      // Compute the edges
      // F32x8 edge0 = (p1.y - p0.y) * (p.x - p0.x) - (p1.x - p0.x) * (p.y - p0.y);
      F32x8 px_minus_0x = _mm256_sub_ps(X, p0_x);
      F32x8 py_minus_0y = _mm256_sub_ps(Y, p0_y);
      F32x8 right0 = _mm256_mul_ps(_dx10, py_minus_0y);
      F32x8 edge0 = _mm256_fmsub_ps(_dy10, px_minus_0x, right0);

      // F32 result = (p2.y - p1.y) * (p.x - p1.x) - (p2.x - p1.x) * (p.y - p1.y);
      F32x8 px_minus_1x = _mm256_sub_ps(X, p1_x);
      F32x8 py_minus_1y = _mm256_sub_ps(Y, p1_y);
      F32x8 right1 = _mm256_mul_ps(_dx21, py_minus_1y);
      F32x8 edge1 = _mm256_fmsub_ps(_dy21, px_minus_1x, right1);

      // F32 result = (p0.y - p2.y) * (p.x - p2.x) - (p0.x - p2.x) * (p.y - p2.y);
      F32x8 px_minus_2x = _mm256_sub_ps(X, p2_x);
      F32x8 py_minus_2y = _mm256_sub_ps(Y, p2_y);
      F32x8 right2 = _mm256_mul_ps(_dx02, py_minus_2y);
      F32x8 edge2 = _mm256_fmsub_ps(_dy02, px_minus_2x, right2);

      F32x8 should_fill;
      F32x8 test_if_x_should_be_clipped = _mm256_cmp_ps(X, var_max_x, _CMP_LT_OQ);
      F32x8 test_if_pixel_inside_edge_using_dot_result0  = _mm256_cmp_ps(edge0, var0, _CMP_GE_OQ);
      F32x8 test_if_pixel_inside_edge_using_dot_result1  = _mm256_cmp_ps(edge1, var0, _CMP_GE_OQ);
      F32x8 test_if_pixel_inside_edge_using_dot_result2  = _mm256_cmp_ps(edge2, var0, _CMP_GE_OQ);
      F32x8 dot_result_combination0  = _mm256_and_ps(test_if_pixel_inside_edge_using_dot_result0, test_if_pixel_inside_edge_using_dot_result1);
      F32x8 dot_result_combination1 = _mm256_and_ps(dot_result_combination0, test_if_pixel_inside_edge_using_dot_result2);
      should_fill = _mm256_and_ps(test_if_x_should_be_clipped, dot_result_combination1);

      F32x8 w0 = _mm256_mul_ps(edge1, inv_area8);
      F32x8 w1 = _mm256_mul_ps(edge2, inv_area8);
      F32x8 w2 = _mm256_mul_ps(edge0, inv_area8);

      // @Todo: Turn this into 1 / interpolated_w, turns out in theory it should be
      // more performant but couldn't make it work

      // @Old_Note: We could do: interpolated_w = 1.f / interpolated_w to get proper depth
      // but why waste an instruction, the smaller the depth value the farther the object
      F32x8 interpolated_w = _mm256_mul_ps(one_over_p0w, w0);
      interpolated_w = _mm256_fmadd_ps(one_over_p1w, w1, interpolated_w);
      interpolated_w = _mm256_fmadd_ps(one_over_p2w, w2, interpolated_w);

      F32 *depth_pointer = (depth_buffer + (x8 + y * dst->x));
      F32x8 depth = _mm256_loadu_ps(depth_pointer);

      F32x8 should_fill_term = _mm256_cmp_ps(depth, interpolated_w, _CMP_LT_OQ);
      should_fill = _mm256_and_ps(should_fill, should_fill_term);

      // If all pixels are not going to get drawn then opt out
      F32x8 compare_with_zero = _mm256_cmpeq_epi32(should_fill, var0);
      int mask = _mm256_movemask_epi8(compare_with_zero);
      if(mask == 0xffffffff) {
        continue;
      }

      F32x8 invw0 = _mm256_mul_ps(w0, inv_p0w);
      F32x8 invw1 = _mm256_mul_ps(w1, inv_p1w);
      F32x8 invw2 = _mm256_mul_ps(w2, inv_p2w);

      F32x8 u0 = _mm256_mul_ps(var_tex0x, invw0);
      u0 = _mm256_fmadd_ps(var_tex1x, invw1, u0);
      u0 = _mm256_fmadd_ps(var_tex2x, invw2, u0);

      F32x8 v0 = _mm256_mul_ps(var_tex0y, invw0);
      v0 = _mm256_fmadd_ps(var_tex1y, invw1, v0);
      v0 = _mm256_fmadd_ps(var_tex2y, invw2, v0);

      F32x8 u1 = _mm256_div_ps(u0, interpolated_w);
      F32x8 v1 = _mm256_div_ps(v0, interpolated_w);

      F32x8 u_floored = _mm256_floor_ps(u1);
      F32x8 v_floored = _mm256_floor_ps(v1);
      F32x8 u2 = _mm256_sub_ps(u1, u_floored);
      F32x8 v2 = _mm256_sub_ps(v1, v_floored);
      F32x8 u3 = _mm256_mul_ps(u2, var_src_x_minus_one);
      F32x8 v3 = _mm256_mul_ps(v2, var_src_y_minus_one);

      F32x8 ui = _mm256_cvtps_epi32(u3);
      F32x8 vi = _mm256_cvtps_epi32(v3);

      // Origin UV (0,0) is in bottom left
      _mm256_maskstore_epi32((int *)depth_pointer, should_fill, interpolated_w);

      //
      // Fetch and calculate texel values
      //
      S32x8 indices_to_fetch0 = _mm256_sub_epi32(var_src_y_minus_one_int, vi);
      S32x8 indices_to_fetch1 = _mm256_mullo_epi32(var_src_x_int, indices_to_fetch0);
      S32x8 indices_to_fetch2  = _mm256_add_epi32(indices_to_fetch1, ui);
      S32x8 indices_to_fetch3 = _mm256_and_si256(indices_to_fetch2, should_fill);

      S32x8 pixel = _mm256_set_epi32(
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 7)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 6)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 5)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 4)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 3)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 2)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 1)],
        src->pixels[_mm256_extract_epi32(indices_to_fetch3, 0)]
      );

      S32x8 texel_i_a = _mm256_and_si256(pixel, var_0xff000000);
      S32x8 texel_i_b = _mm256_and_si256(pixel, var_0x00ff0000);
      S32x8 texel_i_g = _mm256_and_si256(pixel, var_0x0000ff00);
      S32x8 texel_i_r = _mm256_and_si256(pixel, var_0x000000ff);

      texel_i_a = _mm256_srli_epi32(texel_i_a, 24);
      texel_i_b = _mm256_srli_epi32(texel_i_b, 16);
      texel_i_g = _mm256_srli_epi32(texel_i_g, 8 );

      F32x8 texel_a0 = _mm256_cvtepi32_ps(texel_i_a);
      F32x8 texel_b0 = _mm256_cvtepi32_ps(texel_i_b);
      F32x8 texel_g0 = _mm256_cvtepi32_ps(texel_i_g);
      F32x8 texel_r0 = _mm256_cvtepi32_ps(texel_i_r);

      F32x8 texel_b1 = _mm256_mul_ps(texel_b0, inv255);
      F32x8 texel_g1 = _mm256_mul_ps(texel_g0, inv255);
      F32x8 texel_r1 = _mm256_mul_ps(texel_r0, inv255);
      F32x8 texel_a1 = _mm256_mul_ps(texel_a0, inv255);

      texel_r1 = _mm256_mul_ps(texel_r1, texel_r1);
      texel_g1 = _mm256_mul_ps(texel_g1, texel_g1);
      texel_b1 = _mm256_mul_ps(texel_b1, texel_b1);

      //
      // Fetch and calculate dst pixels
      //
      U32 *dst_memory = destination + x8;
      S32x8 dst_pixel = _mm256_maskload_epi32((const int *)dst_memory, should_fill);

      S32x8 dst_i_a0 = _mm256_and_si256(dst_pixel, var_0xff000000);
      S32x8 dst_i_b0 = _mm256_and_si256(dst_pixel, var_0x00ff0000);
      S32x8 dst_i_g0 = _mm256_and_si256(dst_pixel, var_0x0000ff00);
      S32x8 dst_i_r0 = _mm256_and_si256(dst_pixel, var_0x000000ff);

      S32x8 dst_i_a1 = _mm256_srli_epi32(dst_i_a0, 24);
      S32x8 dst_i_b1 = _mm256_srli_epi32(dst_i_b0, 16);
      S32x8 dst_i_g1 = _mm256_srli_epi32(dst_i_g0, 8);
      S32x8 dst_i_r1 = dst_i_r0;

      F32x8 dst_a = _mm256_cvtepi32_ps(dst_i_a1);
      F32x8 dst_b = _mm256_cvtepi32_ps(dst_i_b1);
      F32x8 dst_g = _mm256_cvtepi32_ps(dst_i_g1);
      F32x8 dst_r = _mm256_cvtepi32_ps(dst_i_r1);

      dst_a = _mm256_mul_ps(dst_a, inv255);
      dst_b = _mm256_mul_ps(dst_b, inv255);
      dst_g = _mm256_mul_ps(dst_g, inv255);
      dst_r = _mm256_mul_ps(dst_r, inv255);

      dst_r = _mm256_mul_ps(dst_r, dst_r);
      dst_g = _mm256_mul_ps(dst_g, dst_g);
      dst_b = _mm256_mul_ps(dst_b, dst_b);

      // Premultiplied alpha
      {
        F32x8 inv_texel_a = _mm256_sub_ps(var1,texel_a1);
        dst_r = _mm256_fmadd_ps(inv_texel_a, dst_r, texel_r1);
        dst_g = _mm256_fmadd_ps(inv_texel_a, dst_g, texel_g1);
        dst_b = _mm256_fmadd_ps(inv_texel_a, dst_b, texel_b1);
        dst_a = _mm256_sub_ps(_mm256_add_ps(texel_a1, dst_a), _mm256_mul_ps(texel_a1,dst_a));
      }

      // Almost linear to srgb
      {
        dst_r = _mm256_sqrt_ps(dst_r);
        dst_g = _mm256_sqrt_ps(dst_g);
        dst_b = _mm256_sqrt_ps(dst_b);
      }

      // Convert to integer format
      dst_r = _mm256_mul_ps(dst_r, var255);
      dst_g = _mm256_mul_ps(dst_g, var255);
      dst_b = _mm256_mul_ps(dst_b, var255);
      dst_a = _mm256_mul_ps(dst_a, var255);

      S32x8 dst_r_int = _mm256_cvtps_epi32(dst_r);
      S32x8 dst_g_int = _mm256_cvtps_epi32(dst_g);
      S32x8 dst_b_int = _mm256_cvtps_epi32(dst_b);
      S32x8 dst_a_int = _mm256_cvtps_epi32(dst_a);

      S32x8 dst_int_a_shifted = _mm256_slli_epi32(dst_a_int, 24);
      S32x8 dst_int_b_shifted = _mm256_slli_epi32(dst_b_int, 16);
      S32x8 dst_int_g_shifted = _mm256_slli_epi32(dst_g_int, 8);
      S32x8 dst_int_r_shifted = dst_r_int;

      S32x8 packed_abgr0 = _mm256_or_si256(dst_int_a_shifted, dst_int_b_shifted);
      S32x8 packed_abgr1 = _mm256_or_si256(dst_int_r_shifted, dst_int_g_shifted);
      S32x8 packed_abgr2 = _mm256_or_si256(packed_abgr1, packed_abgr0);

      _mm256_maskstore_epi32((int *)dst_memory, should_fill, packed_abgr2);
    }
    destination += dst->x;
  }

  // filled_pixel_cycles += __rdtsc() - fill_pixels_begin;
  // filled_pixel_count  += (max_x - min_x)*(max_y - min_y);
}

WORK_QUEUE_CALLBACK(draw_tile){
  auto d = (Render_Tile_Job_Data *)data;
  Render *r = d->r;
  For_It(r->commands){
    draw_triangle_nearest(&r->screen320, r->depth320, it.item->src, it.item->p0, it.item->p1, it.item->p2, it.item->tex0, it.item->tex1, it.item->tex2, d->region);
  }
}

function
void draw_mesh(Render *r, String scene_name, Obj_Material *materials, Obj_Mesh *mesh, Vec3 *vertices, Vec2 *tex_coords, Vec3 *normals) {

  for (int i = 0; i < mesh->indices.len; i++) {
    Obj_Index *index = mesh->indices.data + i;
    Bitmap *image = &r->img;
    if(index->material_id != -1) {
      Obj_Material *material = materials + index->material_id;
      // @Todo: No size info from OBJ things, this stuff needs a bit of refactor
      //        Need to figure out how to accomodate multiple possible formats of input etc.
      if(material->texture_ambient.pixels) {
        image = &material->texture_ambient;
      }
    }

    Vertex vert[] = {
      {
        vertices[index->vertex[0] - 1],
        tex_coords[index->tex[0] - 1],
        normals[index->normal[0] - 1],
      },
      {
        vertices[index->vertex[1] - 1],
        tex_coords[index->tex[1] - 1],
        normals[index->normal[1] - 1],
      },
      {
        vertices[index->vertex[2] - 1],
        tex_coords[index->tex[2] - 1],
        normals[index->normal[2] - 1],
      },
    };

    //@Note: Transform
    for (int j = 0; j < 3; j++) {
      vert[j].pos = r->transform * vert[j].pos;
    }


    Vec3 p0_to_camera = r->camera_pos - vert[0].pos;
    Vec3 p0_to_p1 = vert[1].pos - vert[0].pos;
    Vec3 p0_to_p2 = vert[2].pos - vert[0].pos;
    Vec3 normal = normalize(cross(p0_to_p1, p0_to_p2));
    Vec3 light_direction =  mat4_rotation_x(light_rotation) * vec3(0, 0, 1);

    if (dot(normal, p0_to_camera) > 0) { //@Note: Backface culling
      /// ## Clipping
      ///
      /// There are 3 clipping stages, 2 clipping stages in 3D space against zfar and znear and 1 clipping
      /// stage in 2D against left, bottom, right, top(2D image bounds).
      ///
      /// First the triangles get clipped against the zfar plane,
      /// if a triangle has even one vertex outside the clipping region, the entire triangle gets cut.
      /// So far I didn't have problems with that. It simplifies the computations and splitting triangles
      /// on zfar seems like a waste of power.
      ///
      /// The second clipping stage is znear plane. Triangles get fully and nicely clipped against znear.
      /// Every time a triangle gets partially outside the clipping region it gets cut to the znear and
      /// either one or two new triangles get derived from the old one.
      ///
      /// Last clipping stage is performed in the 2D image space. Every triangle has a corresponding AABB
      /// box. In this box every pixel gets tested to see if it's in the triangle. In this clipping stage
      /// the box is clipped to the image metrics - 0, 0, width, height.
      ///
      ///
      // @Note: Zfar
      B32 vertex_is_outside = false;
      Vec3 zfar_normal = vec3(0, 0, -1);
      Vec3 zfar_pos = vec3(0, 0, zfar_value);
      for (S32 j = 0; j < 3; j++) {
        // @Note: Camera
        vert[j].pos = r->camera * vert[j].pos;
        // @Note: Skip triangle if even one vertex gets outside the clipping plane
        if ((dot(zfar_normal, vert[j].pos - zfar_pos) < 0)) {
          vertex_is_outside = true;
          break;
        }
      }

      if (vertex_is_outside) {
        continue;
      }

      // @Note: Znear, clip triangles to the near clipping plane
      Vec3 znear_normal = vec3(0, 0, 1);
      Vec3 znear_pos = vec3(0, 0, 1.f);

      struct _Vertex {
        Vec4 pos;
        Vec2 tex;
        Vec3 norm;
      } in[4];
      S32 in_count = 0;

      Vertex *prev = vert + 2;
      Vertex *curr = vert;
      F32       prev_dot = dot(znear_normal, prev->pos - znear_pos);
      F32       curr_dot = 0;
      for (int j = 0; j < 3; j++) {
        curr_dot = dot(znear_normal, curr->pos - znear_pos);
        if (curr_dot * prev_dot < 0) {
          F32 t = prev_dot / (prev_dot - curr_dot);
          in[in_count].pos = vec4(lerp(prev->pos, curr->pos, t), 1);
          in[in_count].tex = lerp(prev->tex, curr->tex, t);
          in[in_count].norm = lerp(prev->norm, curr->norm, t);
          in_count += 1;
        }

        if (curr_dot > 0) {
          in[in_count].pos = vec4(vert[j].pos, 1);
          in[in_count].tex = vert[j].tex;
          in[in_count++].norm = vert[j].norm;
        }

        prev = curr++;
        prev_dot = curr_dot;
      }

      if (in_count == 0) {
        continue;
      }

      for(S64 j = 0; j < in_count; j++) {
        //@Note: Perspective
        in[j].pos = r->projection * in[j].pos;
        in[j].pos.x = in[j].pos.x / in[j].pos.w;
        in[j].pos.y = in[j].pos.y / in[j].pos.w;
        // in[j].pos.z = in[j].pos.z / in[j].pos.w;

        //@Note: To pixel space
        in[j].pos.x *= r->screen320.x / 2;
        in[j].pos.y *= r->screen320.y / 2;
        in[j].pos.x += r->screen320.x / 2;
        in[j].pos.y += r->screen320.y / 2;
      }

      triangle_count++;
      if (in_count > 3) triangle_count++;

#if MULTITHREADING
      Render_Command *command = array_alloc(os.perm_arena, &r->commands);
      command->src = image;
      command->p0 = in[0].pos;
      command->p1 = in[1].pos;
      command->p2 = in[2].pos;
      command->tex0 = in[0].tex;
      command->tex1 = in[1].tex;
      command->tex2 = in[2].tex;
      if(in_count > 3){
        Render_Command *command = array_alloc(os.perm_arena, &r->commands);
        command->src = image;
        command->p0 = in[0].pos;
        command->p1 = in[2].pos;
        command->p2 = in[3].pos;
        command->tex0 = in[0].tex;
        command->tex1 = in[2].tex;
        command->tex2 = in[3].tex;
      }

#else
      switch(render_triangle_test_case_number){
        case 1:
          draw_triangle_nearest_a(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[1].pos, in[2].pos, in[0].tex, in[1].tex, in[2].tex, in[0].norm, in[1].norm, in[2].norm);
          if (in_count > 3) draw_triangle_nearest_a(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[2].pos, in[3].pos, in[0].tex, in[2].tex, in[3].tex, in[0].norm, in[2].norm, in[3].norm);
        break;
        case 2:
          draw_triangle_nearest_b(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[1].pos, in[2].pos, in[0].tex, in[1].tex, in[2].tex, in[0].norm, in[1].norm, in[2].norm);
          if (in_count > 3) draw_triangle_nearest_b(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[2].pos, in[3].pos, in[0].tex, in[2].tex, in[3].tex, in[0].norm, in[2].norm, in[3].norm);
        break;
        case 3:
          draw_triangle_nearest_simd_with_overloads(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[1].pos, in[2].pos, in[0].tex, in[1].tex, in[2].tex, in[0].norm, in[1].norm, in[2].norm);
          if (in_count > 3) draw_triangle_nearest_simd_with_overloads(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[2].pos, in[3].pos, in[0].tex, in[2].tex, in[3].tex, in[0].norm, in[2].norm, in[3].norm);
        break;
        case 4:
          draw_triangle_nearest_simd_without_overloads(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[1].pos, in[2].pos, in[0].tex, in[1].tex, in[2].tex, in[0].norm, in[1].norm, in[2].norm);
          if (in_count > 3) draw_triangle_nearest_simd_without_overloads(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[2].pos, in[3].pos, in[0].tex, in[2].tex, in[3].tex, in[0].norm, in[2].norm, in[3].norm);
        break;
        case 5:
          draw_triangle_nearest_final(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[1].pos, in[2].pos, in[0].tex, in[1].tex, in[2].tex, in[0].norm, in[1].norm, in[2].norm);
          if (in_count > 3) draw_triangle_nearest_final(&r->screen320, r->depth320, image, light_direction, in[0].pos, in[2].pos, in[3].pos, in[0].tex, in[2].tex, in[3].tex, in[0].norm, in[2].norm, in[3].norm);
        break;
      }
#endif
    }
  }
}

#include "sf_ui.cpp"
global F32 speed = 100.f;
global F32 rotation = 0;
global Obj *f22;
global Obj *sponza;
global Obj *obj;
global Render r = {};
global Scene scene = Scene_Sponza;

function
UI_SIGNAL_CALLBACK(scene_callback) {
  switch(scene) {
    case Scene_F22: {
      speed = 1;
      r.camera_pos = vec3(0,0,-2);
      obj = f22;
    } break;
    case Scene_Sponza: {
      speed = 100;
      r.camera_pos = vec3(-1020, 687, -85); r.camera_yaw = vec2(-1.3, -0.44);
      obj = sponza;
    } break;
    case Scene_Count:
    invalid_default_case;
  }
  scene = (Scene)(((int)scene + 1) % Scene_Count);
}

FILE *global_file;
function void
windows_log(Log_Kind kind, String string, char *file, int line){
  fprintf(global_file, "%s", string.str);
  // OutputDebugStringA((const char *)string.str);
}

function void
next_test_case(B32 first_time){
  render_triangle_test_case_number += 1;
  if(first_time || render_triangle_test_case_number == 6){
    render_triangle_test_case_angle += 1;
    render_triangle_test_case_number = 1;
    try_again: switch(render_triangle_test_case_angle){
      case 0: r.camera_pos = vec3(-1020, 687, -85); r.camera_yaw = vec2(-1.3, -0.44); break;
      case 1: r.camera_pos = vec3(-356,89.5,168); r.camera_yaw = vec2(0.2, 0); break;
      case 2: render_triangle_test_case_angle = 0; goto try_again; break;
    }
  }
}

int
main(int argc, char **argv) {
  global_file = fopen("perfclocks.txt", "a");
  thread_ctx.log_proc = windows_log;

  os.window_size.x = 1920;
  os.window_size.y = 1080;
  os.window_resizable = 1;
  assert(os_init());
  Font font = os_load_font(os.perm_arena, 12*os.dpi_scale, "Arial", 0);
  // test_array_list();

  // f22 = load_obj_dump(os.perm_arena, "plane.bin"_s);
  // sponza = load_obj_dump(os.perm_arena, "sponza.bin"_s);
   Obj sponza_obj = load_obj(&os_process_heap, "assets/sponza/sponza.obj"_s);
  sponza = &sponza_obj;
  scene_callback();
  next_test_case(true);

  int screen_x = os.window_size.x;
  int screen_y = os.window_size.y;

  r.screen320 = {(U32 *)arena_push_size(os.perm_arena, screen_x*screen_y*sizeof(U32)), screen_x, screen_y};
  r.depth320 = (F32 *)arena_push_size(os.perm_arena, sizeof(F32) * screen_x * screen_y);
  r.commands.block_size = 1024*1024;
  ThreadStartupInfo thread_infos[16] = {};
  init_work_queue(&r.work_queue, buff_cap(thread_infos), thread_infos);

  String frame_data = {};
  String raster_details = {};
  UISetup setup[] = {
    UI_SIGNAL("Change scene"_s, scene_callback),
    UI_LABEL(&frame_data),
    UI_LABEL(&raster_details),
    UI_LABEL(&os.text),
  };
  UI ui = ui_make(setup, buff_cap(setup));
  B32 ui_mouse_lock = true;

  while (os_game_loop()) {
    PROFILE_SCOPE(main_loop);
    if (ui_mouse_lock == false) {
      r.camera_yaw.x += os.delta_mouse_pos.x * 0.01f;
      r.camera_yaw.y -= os.delta_mouse_pos.y * 0.01f;
    }
    if (os.key[Key_Escape].pressed) os_quit();
    if (os.key[Key_O].down) light_rotation += 0.05f;
    if (os.key[Key_P].down) light_rotation -= 0.05f;
    if (os.key[Key_F2].pressed) {
      ui_mouse_lock = !ui_mouse_lock;
      os_show_cursor(!os.cursor_visible);
    }
    if (os.key[Key_A].down) r.camera_pos.x -= speed * (F32)os.delta_time;
    if (os.key[Key_D].down) r.camera_pos.x += speed * (F32)os.delta_time;
    if (os.key[Key_W].down) {
      r.camera_forward_velocity = r.camera_direction * speed * (F32)os.delta_time;
      r.camera_pos = r.camera_pos + r.camera_forward_velocity;
    }
    if (os.key[Key_S].down) {
      r.camera_forward_velocity = r.camera_direction * speed * (F32)os.delta_time;
      r.camera_pos = r.camera_pos - r.camera_forward_velocity;
    }
    if (os.key[Key_R].down) r.camera_pos.y += speed * (F32)os.delta_time;
    if (os.key[Key_F].down) r.camera_pos.y -= speed * (F32)os.delta_time;

    // Clear screen and depth buffer
    U32* p = r.screen320.pixels;
    for (int y = 0; y < r.screen320.y; y++) {
      for (int x = 0; x < r.screen320.x; x++) {
        *p++ = 0x33333333;
      }
    }

    F32* dp = r.depth320;
    for (int y = 0; y < r.screen320.y; y++) {
      for (int x = 0; x < r.screen320.x; x++) {
        *dp++ = -F32MAX;
      }
    }

    Mat4 camera_rotation = mat4_rotation_y(r.camera_yaw.x) * mat4_rotation_x(r.camera_yaw.y);
    r.camera_direction = (camera_rotation * vec4(0,0,1,1)).xyz;
    Vec3 target = r.camera_pos + r.camera_direction;
    r.camera = mat4_look_at(r.camera_pos, target, vec3(0, 1, 0));
    r.projection = mat4_perspective(60.f, (F32)os.screen->x, (F32)os.screen->y, 1.f, zfar_value);
    r.transform = mat4_rotation_z(rotation);
    r.transform = r.transform * mat4_rotation_y(rotation);
    for (int i = 0; i < obj->mesh.len; i++) {
      PROFILE_SCOPE(draw_all_meshes);
      Vec2* tex_coords = (Vec2*)obj->texture_coordinates.data;
      Vec3 *normals = (Vec3 *)obj->normals.data;
      Obj_Mesh *mesh = obj->mesh.data;
      Vec3* vertices = (Vec3 *)obj->vertices.data;
      draw_mesh(&r, obj->name, obj->materials.data, mesh+i, vertices, tex_coords, normals);
    }

#if MULTITHREADING
    Render_Tile_Job_Data tile_job_data[32];
    S32 x_tiles = 1;
    S32 y_tiles = 16;
    F32 block_size_x = r.screen320.x / x_tiles;
    F32 block_size_y = r.screen320.y / y_tiles;
    S32 i = 0;
    for(S32 x = 0; x < x_tiles; x++){
      for(S32 y = 0; y < y_tiles; y++){
        Rect2 bounding_rect;
        bounding_rect.min_x = block_size_x * x;
        bounding_rect.min_y = block_size_y * y;
        bounding_rect.max_x = bounding_rect.min_x + block_size_x;
        bounding_rect.max_y = bounding_rect.min_y + block_size_y;
        tile_job_data[i].region = bounding_rect;
        tile_job_data[i].r = &r;

        push_work(&r.work_queue, (void *)(tile_job_data + i), draw_tile);
        i += 1;
      }
    }

    wait_until_completion(&r.work_queue);
    array_free_all_nodes(&r.commands);
#endif

    // @Note: Draw 320screen to OS screen
    U32* ptr = os.screen->pixels;
    for (int y = 0; y < os.screen->y; y++) {
      for (int x = 0; x < os.screen->x; x++) {
        F32 u = (F32)x / (F32)os.screen->x;
        F32 v = (F32)y / (F32)os.screen->y;
        int tx = (int)(u * r.screen320.x );
        int ty = (int)(v * r.screen320.y );
        *ptr++ = r.screen320.pixels[tx + ty * (r.screen320.x)];
      }
    }

    ui_end_frame(os.screen, &ui, &font);
    frame_data = string_fmt(os.frame_arena, "FPS:%f dt:%f frame:%u camera_pos: %f %f %f camera_yaw: %f %f",
      os.fps, os.delta_time*1000, os.frame, r.camera_pos.x, r.camera_pos.y, r.camera_pos.z, r.camera_yaw.x, r.camera_yaw.y);
#if MULTITHREADING
    if(os.frame == 1) log_info("Angle;Frame_Time\n");
    log_info("%d;%f\n", render_triangle_test_case_angle, os.delta_time*1000);
#else
    if(os.frame == 1) log_info("Angle;Algorithm;Frame_Time;Cycles_Per_Pixel;Cycles_To_Process_Triangles;Pixels_Processed;Triangles\n");
    log_info("%d;%d;%f;%llu;%llu;%llu;%llu\n", render_triangle_test_case_angle, render_triangle_test_case_number,
      os.delta_time*1000, filled_pixel_cycles/filled_pixel_count, filled_pixel_cycles, filled_pixel_count, triangle_count);
#endif

    filled_pixel_count = 0;
    filled_pixel_cycles = 0;
    triangle_count = 0;

    // @Todo I think there is bug with test_case_number, after doing full round it
    // skips a phase
    if(os.frame % 15 == 0){
      next_test_case(false);
    }

  }
}

/////////////////////////////////////////////////////////////////////////////////////
/// ### Resources that helped me build the rasterizer (Might be helpful to you too):
///
/// * Algorithm I used for triangle rasterization by Juan Pineda is described in paper called "A Parallel Algorithm for Polygon Rasterization"
/// * Casey Muratori's series on making a game from scratch(including a 2D software rasterizer(episode ~82) and 3d gpu renderer): https://hero.handmade.network/episode/code#
/// * Fabian Giessen's "Optimizing Software Occlusion Culling": https://fgiesen.wordpress.com/2013/02/17/optimizing-sw-occlusion-culling-index/
/// * Fabian Giessen's optimized software renderer: https://github.com/rygorous/intel_occlusion_cull/tree/blog/SoftwareOcclusionCulling
/// * Fabian Giessen's javascript triangle rasterizer: https://gist.github.com/rygorous/2486101
/// * Fabian Giessen's C++ triangle rasterizer: https://github.com/rygorous/trirast/blob/master/main.cpp
/// * Joy's Kenneth lectures about computer graphics: https://www.youtube.com/playlist?list=PL_w_qWAQZtAZhtzPI5pkAtcUVgmzdAP8g
/// * Joy's Kenneth article on clipping: https://import.cdn.thinkific.com/167815/JoyKennethClipping-200905-175314.pdf
/// * A bunch of helpful notes and links to resources: https://nlguillemot.wordpress.com/2016/07/10/rasterizer-notes/
/// * Very nice paid course on making a software rasterizer using a scanline method: https://pikuma.com/courses/learn-3d-computer-graphics-programming
/// * Reference for obj loader: https://github.com/tinyobjloader/tinyobjloader/blob/master/tiny_obj_loader.h
///
/// ### To read
///
/// * http://ce-publications.et.tudelft.nl/publications/1362_hardware_algorithms_for_tilebased_realtime_rendering.pdf