GPU: Rewrite CRTC display modeling and overscan handling

6 years ago · 148279e2f2
parent fe824d6c89
commit 148279e2f2
9 changed files with 282 additions and 171 deletions
--- a/src/core/gpu.cpp
+++ b/src/core/gpu.cpp
@ -36,6 +36,9 @@ bool GPU::Initialize(HostDisplay* host_display, System* system, DMA* dma, Interr
 void GPU::UpdateSettings()
 {
  m_force_progressive_scan = m_system->GetSettings().display_force_progressive_scan;
  // Crop mode calls this, so recalculate the display area
  UpdateCRTCDisplayParameters();
 }
 void GPU::Reset()
@ -107,12 +110,14 @@ bool GPU::DoState(StateWrapper& sw)
  sw.Do(&m_crtc_state.regs.horizontal_display_range);
  sw.Do(&m_crtc_state.regs.vertical_display_range);
  sw.Do(&m_crtc_state.dot_clock_divider);
-  sw.Do(&m_crtc_state.visible_display_width);
+  sw.Do(&m_crtc_state.display_width);
-  sw.Do(&m_crtc_state.visible_display_height);
+  sw.Do(&m_crtc_state.display_height);
-  sw.Do(&m_crtc_state.active_display_left);
+  sw.Do(&m_crtc_state.display_origin_left);
-  sw.Do(&m_crtc_state.active_display_top);
+  sw.Do(&m_crtc_state.display_origin_top);
-  sw.Do(&m_crtc_state.active_display_width);
+  sw.Do(&m_crtc_state.display_vram_left);
-  sw.Do(&m_crtc_state.active_display_height);
+  sw.Do(&m_crtc_state.display_vram_top);
  sw.Do(&m_crtc_state.display_vram_width);
  sw.Do(&m_crtc_state.display_vram_height);
  sw.Do(&m_crtc_state.horizontal_total);
  sw.Do(&m_crtc_state.horizontal_display_start);
  sw.Do(&m_crtc_state.horizontal_display_end);
@ -319,7 +324,6 @@ void GPU::UpdateCRTCConfig()
 {
  static constexpr std::array<u16, 8> dot_clock_dividers = {{10, 8, 5, 4, 7, 7, 7, 7}};
  CRTCState& cs = m_crtc_state;
  const DisplayCropMode crop_mode = m_system->GetSettings().display_crop_mode;
  if (m_GPUSTAT.pal_mode)
  {
@ -343,99 +347,154 @@ void GPU::UpdateCRTCConfig()
  const u8 horizontal_resolution_index = m_GPUSTAT.horizontal_resolution_1 | (m_GPUSTAT.horizontal_resolution_2 << 2);
  cs.dot_clock_divider = dot_clock_dividers[horizontal_resolution_index];
-  cs.horizontal_display_start = static_cast<TickCount>(std::min<u32>(cs.regs.X1, cs.horizontal_total));
+  cs.horizontal_display_start = std::min<u16>(cs.regs.X1, cs.horizontal_total);
-  cs.horizontal_display_end = static_cast<TickCount>(std::min<u32>(cs.regs.X2, cs.horizontal_total));
+  cs.horizontal_display_end = std::min<u16>(cs.regs.X2, cs.horizontal_total);
-  cs.vertical_display_start = static_cast<TickCount>(std::min<u32>(cs.regs.Y1, cs.vertical_total));
+  cs.vertical_display_start = std::min<u16>(cs.regs.Y1, cs.vertical_total);
-  cs.vertical_display_end = static_cast<TickCount>(std::min<u32>(cs.regs.Y2, cs.vertical_total));
+  cs.vertical_display_end = std::min<u16>(cs.regs.Y2, cs.vertical_total);
  // determine the active display size
  cs.active_display_width = std::clamp<u16>((cs.regs.X2 - cs.regs.X1) / cs.dot_clock_divider, 1, VRAM_WIDTH);
  cs.active_display_height =
    std::clamp<u16>((cs.regs.Y2 - cs.regs.Y1), 1, VRAM_HEIGHT >> BoolToUInt8(m_GPUSTAT.In480iMode()));
  // Construct screen borders from configured active area and the standard visible range.
  // TODO: Ensure it doesn't overflow
  const u16 horizontal_start_display_tick = (crop_mode == DisplayCropMode::None ? 488 : 608);
  const u16 horizontal_end_display_tick = (crop_mode == DisplayCropMode::None ? 2800 : 2560);
  cs.visible_display_width = horizontal_end_display_tick / cs.dot_clock_divider;
  cs.active_display_left =
    (std::max<u16>(m_crtc_state.regs.X1, horizontal_start_display_tick) - horizontal_start_display_tick) /
    cs.dot_clock_divider;
  const u16 vertical_start_display_line = (crop_mode == DisplayCropMode::None ? 8 : (m_GPUSTAT.pal_mode ? 20 : 16));
  const u16 vertical_end_display_line =
    (crop_mode == DisplayCropMode::None ? static_cast<u16>(cs.vertical_total) :
                                          static_cast<u16>(m_GPUSTAT.pal_mode ? 308 : 256));
  const u16 bottom_padding = vertical_end_display_line - std::min<u16>(m_crtc_state.regs.Y2, vertical_end_display_line);
  cs.active_display_top =
    std::max<u16>(m_crtc_state.regs.Y1, vertical_start_display_line) - vertical_start_display_line;
  cs.visible_display_height = cs.active_display_top + cs.active_display_height + bottom_padding;
-  // Aspect ratio is always 4:3.
+  UpdateCRTCDisplayParameters();
-  cs.display_aspect_ratio = 4.0f / 3.0f;
+  UpdateSliceTicks();
 }
 void GPU::UpdateCRTCDisplayParameters()
 {
  CRTCState& cs = m_crtc_state;
  const DisplayCropMode crop_mode = m_system->GetSettings().display_crop_mode;
-  if (crop_mode == DisplayCropMode::Borders)
+  u16 horizontal_display_start_tick, horizontal_display_end_tick;
-  {
+  u16 vertical_display_start_line, vertical_display_end_line;
    // Compute the aspect ratio necessary to display borders in the inactive region of the picture.
    // Convert total dots/lines to time.
    const float dot_clock =
      (static_cast<float>(MASTER_CLOCK) * (11.0f / 7.0f / static_cast<float>(cs.dot_clock_divider)));
    const float dot_clock_period = 1.0f / dot_clock;
    const float dots_per_scanline = static_cast<float>(cs.horizontal_total) / static_cast<float>(cs.dot_clock_divider);
    const float horizontal_period = dots_per_scanline * dot_clock_period;
    const float vertical_period = horizontal_period * static_cast<float>(cs.vertical_total);
    // Convert active dots/lines to time.
    const float visible_dots_per_scanline = static_cast<float>(cs.active_display_width);
    const float horizontal_active_time = horizontal_period * visible_dots_per_scanline;
    const float vertical_active_time = horizontal_active_time * static_cast<float>(cs.regs.Y2 - cs.regs.Y1);
    // Use the reference active time/lines for the signal to work out the border area, and thus aspect ratio
    // transformation for the active area in our framebuffer. For the purposes of these calculations, we're assuming
    // progressive scan.
    float display_ratio;
  if (m_GPUSTAT.pal_mode)
  {
-      // Wikipedia says PAL is active 51.95us of 64.00us, and 576/625 lines.
+    // TODO: Verify PAL numbers.
-      const float signal_horizontal_active_time = 51.95f;
+    switch (crop_mode)
-      const float signal_horizontal_total_time = 64.0f;
+    {
-      const float signal_vertical_active_lines = 576.0f;
+      case DisplayCropMode::None:
-      const float signal_vertical_total_lines = 625.0f;
+        horizontal_display_start_tick = 487;
-      const float h_ratio =
+        horizontal_display_end_tick = 3282;
-        (horizontal_active_time / horizontal_period) * (signal_horizontal_total_time / signal_horizontal_active_time);
+        vertical_display_start_line = 12;
-      const float v_ratio =
+        vertical_display_end_line = 312;
-        (vertical_active_time / vertical_period) * (signal_vertical_total_lines / signal_vertical_active_lines);
+        break;
-      display_ratio = h_ratio / v_ratio;
+
      case DisplayCropMode::Overscan:
        horizontal_display_start_tick = 628;
        horizontal_display_end_tick = 3188;
        vertical_display_start_line = 19;
        vertical_display_end_line = 307;
        break;
      case DisplayCropMode::Borders:
      default:
        horizontal_display_start_tick = m_crtc_state.horizontal_display_start;
        horizontal_display_end_tick = m_crtc_state.horizontal_display_end;
        vertical_display_start_line = m_crtc_state.vertical_display_start;
        vertical_display_end_line = m_crtc_state.vertical_display_end;
        break;
    }
  }
  else
  {
-      const float signal_horizontal_active_time = 52.66f;
+    switch (crop_mode)
-      const float signal_horizontal_total_time = 63.56f;
+    {
-      const float signal_vertical_active_lines = 486.0f;
+      case DisplayCropMode::None:
-      const float signal_vertical_total_lines = 525.0f;
+        horizontal_display_start_tick = 488;
-      const float h_ratio =
+        horizontal_display_end_tick = 3288;
-        (horizontal_active_time / horizontal_period) * (signal_horizontal_total_time / signal_horizontal_active_time);
+        vertical_display_start_line = 8;
-      const float v_ratio =
+        vertical_display_end_line = 260;
-        (vertical_active_time / vertical_period) * (signal_vertical_total_lines / signal_vertical_active_lines);
+        break;
-      display_ratio = h_ratio / v_ratio;
+
      case DisplayCropMode::Overscan:
        horizontal_display_start_tick = 608;
        horizontal_display_end_tick = 3168;
        vertical_display_start_line = 16;
        vertical_display_end_line = 256;
        break;
      case DisplayCropMode::Borders:
      default:
        horizontal_display_start_tick = m_crtc_state.horizontal_display_start;
        horizontal_display_end_tick = m_crtc_state.horizontal_display_end;
        vertical_display_start_line = m_crtc_state.vertical_display_start;
        vertical_display_end_line = m_crtc_state.vertical_display_end;
        break;
    }
  }
-    // Ensure the numbers are sane, and not due to a misconfigured active display range.
+  const u8 height_shift = BoolToUInt8(m_GPUSTAT.In480iMode());
-    cs.display_aspect_ratio = (std::isnormal(display_ratio) && display_ratio != 0.0f) ? display_ratio : (4.0f / 3.0f);
+
-    cs.visible_display_width = cs.active_display_width;
+  // Determine screen size.
-    cs.visible_display_height = cs.active_display_height;
+  cs.display_width = std::max<u16>(
-    cs.active_display_left = 0;
+    ((horizontal_display_end_tick - horizontal_display_start_tick) + (cs.dot_clock_divider - 1)) / cs.dot_clock_divider,
-    cs.active_display_top = 0;
+    1u);
  cs.display_height = std::max<u16>((vertical_display_end_line - vertical_display_start_line) << height_shift, 1u);
  // Determine if we need to adjust the VRAM rectangle (because the display is starting outside the visible area) or add
  // padding.
  if (cs.horizontal_display_start >= horizontal_display_start_tick)
  {
    cs.display_origin_left = (cs.horizontal_display_start - horizontal_display_start_tick) / cs.dot_clock_divider;
    cs.display_vram_left = m_crtc_state.regs.X;
  }
  else
  {
    cs.display_origin_left = 0;
    cs.display_vram_left = std::min<u16>(
      m_crtc_state.regs.X + ((horizontal_display_start_tick - cs.horizontal_display_start) / cs.dot_clock_divider),
      VRAM_WIDTH - 1);
-  Log_DevPrintf("Screen resolution: %ux%u", cs.visible_display_width, cs.visible_display_height);
+    // for 24-bit scanout we must stay aligned
-  Log_DevPrintf("Active display: %ux%u @ %u,%u (VRAM %u,%u)", cs.active_display_width, cs.active_display_height,
+    if (m_GPUSTAT.display_area_color_depth_24 && ((cs.display_vram_left - cs.regs.X) & 1u))
-                cs.active_display_left, cs.active_display_top, cs.regs.X.GetValue(), cs.regs.Y.GetValue());
+      cs.display_vram_left--;
-  Log_DevPrintf("Padding: Left=%u, Top=%u, Right=%u, Bottom=%u", cs.active_display_left, cs.active_display_top,
+  }
                cs.visible_display_width - cs.active_display_width - cs.active_display_left,
                cs.visible_display_height - cs.active_display_height - cs.active_display_top);
-  UpdateSliceTicks();
+  if (cs.horizontal_display_end <= horizontal_display_end_tick)
  {
    cs.display_vram_width = std::min<u16>(
      std::max<u16>(
        (((cs.horizontal_display_end - std::max(cs.horizontal_display_start, horizontal_display_start_tick)) +
          (cs.dot_clock_divider - 1)) /
         cs.dot_clock_divider),
        1u),
      VRAM_WIDTH - cs.display_vram_left);
  }
  else
  {
    cs.display_vram_width = std::min<u16>(
      std::max<u16>(
        (((horizontal_display_end_tick - std::max(cs.horizontal_display_start, horizontal_display_start_tick)) +
          (cs.dot_clock_divider - 1)) /
         cs.dot_clock_divider),
        1u),
      VRAM_WIDTH - cs.display_vram_left);
  }
  if (cs.vertical_display_start >= vertical_display_start_line)
  {
    cs.display_origin_top = (cs.vertical_display_start - vertical_display_start_line) << height_shift;
    cs.display_vram_top = m_crtc_state.regs.Y;
  }
  else
  {
    cs.display_origin_top = 0;
    cs.display_vram_top =
      std::min<u16>(m_crtc_state.regs.Y + ((cs.vertical_display_start - vertical_display_start_line) << height_shift),
                    VRAM_HEIGHT - 1);
  }
  if (cs.vertical_display_end <= vertical_display_end_line)
  {
    cs.display_vram_height = std::min<u16>(
      (cs.vertical_display_end - std::max(cs.vertical_display_start, vertical_display_start_line)) << height_shift,
      VRAM_HEIGHT - cs.display_vram_top);
  }
  else
  {
    cs.display_vram_height = std::min<u16>(
      (vertical_display_end_line - std::max(cs.vertical_display_start, vertical_display_start_line)) << height_shift,
      VRAM_HEIGHT - cs.display_vram_top);
  }
  // Aspect ratio is always 4:3.
  cs.display_aspect_ratio = 4.0f / 3.0f;
 }
 TickCount GPU::GetPendingGPUTicks() const
@ -679,6 +738,7 @@ void GPU::WriteGP1(u32 value)
      m_crtc_state.regs.display_address_start = param & CRTCState::Regs::DISPLAY_ADDRESS_START_MASK;
      Log_DebugPrintf("Display address start <- 0x%08X", m_crtc_state.regs.display_address_start);
      m_system->IncrementInternalFrameNumber();
      UpdateCRTCDisplayParameters();
    }
    break;
@ -1065,7 +1125,6 @@ void GPU::DrawDebugStateWindow()
                m_GPUSTAT.interlaced_field ? "odd" : "even");
    ImGui::Text("Display Disable: %s", m_GPUSTAT.display_disable ? "Yes" : "No");
    ImGui::Text("Drawing Even Line: %s", m_GPUSTAT.drawing_even_line ? "Yes" : "No");
    ImGui::Text("Display Resolution: %ux%u", cs.active_display_width, cs.active_display_height);
    ImGui::Text("Color Depth: %u-bit", m_GPUSTAT.display_area_color_depth_24 ? 24 : 15);
    ImGui::Text("Start Offset: (%u, %u)", cs.regs.X.GetValue(), cs.regs.Y.GetValue());
    ImGui::Text("Display Total: %u (%u) horizontal, %u vertical", cs.horizontal_total,
@ -1074,6 +1133,13 @@ void GPU::DrawDebugStateWindow()
                cs.regs.X1.GetValue() / cs.dot_clock_divider, cs.regs.X2.GetValue() / cs.dot_clock_divider,
                cs.regs.Y1.GetValue(), cs.regs.Y2.GetValue());
    ImGui::Text("Current Scanline: %u (tick %u)", cs.current_scanline, cs.current_tick_in_scanline);
    ImGui::Text("Display resolution: %ux%u", cs.display_width, cs.display_height);
    ImGui::Text("Display origin: %u, %u", cs.display_origin_left, cs.display_origin_top);
    ImGui::Text("Active display: %ux%u @ (%u, %u)", cs.display_vram_width, cs.display_vram_height, cs.display_vram_left,
                cs.display_vram_top);
    ImGui::Text("Padding: Left=%u, Top=%u, Right=%u, Bottom=%u", cs.display_origin_left, cs.display_origin_top,
                cs.display_width - cs.display_vram_width - cs.display_origin_left,
                cs.display_height - cs.display_vram_height - cs.display_origin_top);
  }
  if (ImGui::CollapsingHeader("GPU", ImGuiTreeNodeFlags_DefaultOpen))
--- a/src/core/gpu.h
+++ b/src/core/gpu.h
@ -313,6 +313,7 @@ protected:
  // Sets dots per scanline
  void UpdateCRTCConfig();
  void UpdateCRTCDisplayParameters();
  // Update ticks for this execution slice
  void UpdateSliceTicks();
@ -547,19 +548,26 @@ protected:
    u16 dot_clock_divider;
-    u16 visible_display_width;
+    // Size of the simulated screen in pixels. Depending on crop mode, this may include overscan area.
-    u16 visible_display_height;
+    u16 display_width;
-    u16 active_display_left;
+    u16 display_height;
    u16 active_display_top;
    u16 active_display_width;
    u16 active_display_height;
-    TickCount horizontal_total;
+    // Top-left corner where the VRAM is displayed. Depending on the CRTC config, this may indicate padding.
-    TickCount horizontal_display_start;
+    u16 display_origin_left;
-    TickCount horizontal_display_end;
+    u16 display_origin_top;
-    u32 vertical_total;
+
-    u32 vertical_display_start;
+    // Rectangle describing the displayed area of VRAM, in coordinates.
-    u32 vertical_display_end;
+    u16 display_vram_left;
    u16 display_vram_top;
    u16 display_vram_width;
    u16 display_vram_height;
    u16 horizontal_total;
    u16 horizontal_display_start;
    u16 horizontal_display_end;
    u16 vertical_total;
    u16 vertical_display_start;
    u16 vertical_display_end;
    TickCount fractional_ticks;
    TickCount current_tick_in_scanline;
@ -568,15 +576,6 @@ protected:
    float display_aspect_ratio;
    bool in_hblank;
    bool in_vblank;
    /// Returns a rectangle representing the active display region within the visible area of the screen, i.e. where the
    /// VRAM texture should be "scanned out" to. Areas outside this region (the border) should be displayed as black.
    Common::Rectangle<s32> GetActiveDisplayRectangle() const
    {
      return Common::Rectangle<s32>::FromExtents(
        static_cast<s32>(ZeroExtend32(active_display_left)), static_cast<s32>(ZeroExtend32(active_display_top)),
        static_cast<s32>(ZeroExtend32(active_display_width)), static_cast<s32>(ZeroExtend32(active_display_height)));
    }
  } m_crtc_state = {};
  State m_state = State::Idle;
--- a/src/core/gpu_hw.cpp
+++ b/src/core/gpu_hw.cpp
@ -490,7 +490,7 @@ void GPU_HW::DispatchRenderCommand(RenderCommand rc, u32 num_vertices, const u32
          (m_draw_mode.GetTexturePageRectangle().Intersects(m_vram_dirty_rect) ||
           (m_draw_mode.IsUsingPalette() && m_draw_mode.GetTexturePaletteRectangle().Intersects(m_vram_dirty_rect))))
      {
-        Log_DevPrintf("Invalidating VRAM read cache due to drawing area overlap");
+        //Log_DevPrintf("Invalidating VRAM read cache due to drawing area overlap");
        if (!IsFlushed())
          FlushRender();
--- a/src/core/gpu_hw_d3d11.cpp
+++ b/src/core/gpu_hw_d3d11.cpp
@ -525,18 +525,17 @@ void GPU_HW_D3D11::UpdateDisplay()
  {
    m_host_display->SetDisplayTexture(m_vram_texture.GetD3DSRV(), m_vram_texture.GetWidth(), m_vram_texture.GetHeight(),
                                      0, 0, m_vram_texture.GetWidth(), m_vram_texture.GetHeight());
-    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, Common::Rectangle<s32>(0, 0, VRAM_WIDTH, VRAM_HEIGHT),
+    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, 0, 0, VRAM_WIDTH, VRAM_HEIGHT,
                                         static_cast<float>(VRAM_WIDTH) / static_cast<float>(VRAM_HEIGHT));
  }
  else
  {
-    const u32 vram_offset_x = m_crtc_state.regs.X;
+    const u32 vram_offset_x = m_crtc_state.display_vram_left;
-    const u32 vram_offset_y = m_crtc_state.regs.Y;
+    const u32 vram_offset_y = m_crtc_state.display_vram_top;
    const u32 scaled_vram_offset_x = vram_offset_x * m_resolution_scale;
    const u32 scaled_vram_offset_y = vram_offset_y * m_resolution_scale;
-    const u32 display_width = std::min<u32>(m_crtc_state.active_display_width, VRAM_WIDTH - vram_offset_x);
+    const u32 display_width = m_crtc_state.display_vram_width;
-    const u32 display_height = std::min<u32>(m_crtc_state.active_display_height << BoolToUInt8(m_GPUSTAT.In480iMode()),
+    const u32 display_height = m_crtc_state.display_vram_height;
                                             VRAM_HEIGHT - vram_offset_y);
    const u32 scaled_display_width = display_width * m_resolution_scale;
    const u32 scaled_display_height = display_height * m_resolution_scale;
    const bool interlaced = IsDisplayInterlaced();
@ -594,8 +593,10 @@ void GPU_HW_D3D11::UpdateDisplay()
      RestoreGraphicsAPIState();
    }
-    m_host_display->SetDisplayParameters(m_crtc_state.visible_display_width, m_crtc_state.visible_display_height,
+    m_host_display->SetDisplayParameters(m_crtc_state.display_width, m_crtc_state.display_height,
-                                         m_crtc_state.GetActiveDisplayRectangle(), m_crtc_state.display_aspect_ratio);
+                                         m_crtc_state.display_origin_left, m_crtc_state.display_origin_top,
                                         m_crtc_state.display_vram_width, m_crtc_state.display_vram_height,
                                         m_crtc_state.display_aspect_ratio);
  }
 }
--- a/src/core/gpu_hw_opengl.cpp
+++ b/src/core/gpu_hw_opengl.cpp
@ -479,18 +479,17 @@ void GPU_HW_OpenGL::UpdateDisplay()
                                      m_vram_texture.GetWidth(), static_cast<s32>(m_vram_texture.GetHeight()), 0,
                                      m_vram_texture.GetHeight(), m_vram_texture.GetWidth(),
                                      -static_cast<s32>(m_vram_texture.GetHeight()));
-    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, Common::Rectangle<s32>(0, 0, VRAM_WIDTH, VRAM_HEIGHT),
+    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, 0, 0, VRAM_WIDTH, VRAM_HEIGHT,
                                         static_cast<float>(VRAM_WIDTH) / static_cast<float>(VRAM_HEIGHT));
  }
  else
  {
-    const u32 vram_offset_x = m_crtc_state.regs.X;
+    const u32 vram_offset_x = m_crtc_state.display_vram_left;
-    const u32 vram_offset_y = m_crtc_state.regs.Y;
+    const u32 vram_offset_y = m_crtc_state.display_vram_top;
    const u32 scaled_vram_offset_x = vram_offset_x * m_resolution_scale;
    const u32 scaled_vram_offset_y = vram_offset_y * m_resolution_scale;
-    const u32 display_width = std::min<u32>(m_crtc_state.active_display_width, VRAM_WIDTH - vram_offset_x);
+    const u32 display_width = m_crtc_state.display_vram_width;
-    const u32 display_height = std::min<u32>(m_crtc_state.active_display_height << BoolToUInt8(m_GPUSTAT.In480iMode()),
+    const u32 display_height = m_crtc_state.display_vram_height;
                                             VRAM_HEIGHT - vram_offset_y);
    const u32 scaled_display_width = display_width * m_resolution_scale;
    const u32 scaled_display_height = display_height * m_resolution_scale;
    const bool interlaced = IsDisplayInterlaced();
@ -572,8 +571,10 @@ void GPU_HW_OpenGL::UpdateDisplay()
      glEnable(GL_SCISSOR_TEST);
    }
-    m_host_display->SetDisplayParameters(m_crtc_state.visible_display_width, m_crtc_state.visible_display_height,
+    m_host_display->SetDisplayParameters(m_crtc_state.display_width, m_crtc_state.display_height,
-                                         m_crtc_state.GetActiveDisplayRectangle(), m_crtc_state.display_aspect_ratio);
+                                         m_crtc_state.display_origin_left, m_crtc_state.display_origin_top,
                                         m_crtc_state.display_vram_width, m_crtc_state.display_vram_height,
                                         m_crtc_state.display_aspect_ratio);
  }
 }
--- a/src/core/gpu_hw_opengl_es.cpp
+++ b/src/core/gpu_hw_opengl_es.cpp
@ -343,18 +343,17 @@ void GPU_HW_OpenGL_ES::UpdateDisplay()
                                      m_vram_texture.GetWidth(), static_cast<s32>(m_vram_texture.GetHeight()), 0,
                                      m_vram_texture.GetHeight(), m_vram_texture.GetWidth(),
                                      -static_cast<s32>(m_vram_texture.GetHeight()));
-    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, Common::Rectangle<s32>(0, 0, VRAM_WIDTH, VRAM_HEIGHT),
+    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, 0, 0, VRAM_WIDTH, VRAM_HEIGHT,
                                         static_cast<float>(VRAM_WIDTH) / static_cast<float>(VRAM_HEIGHT));
  }
  else
  {
-    const u32 vram_offset_x = m_crtc_state.regs.X;
+    const u32 vram_offset_x = m_crtc_state.display_vram_left;
-    const u32 vram_offset_y = m_crtc_state.regs.Y;
+    const u32 vram_offset_y = m_crtc_state.display_vram_top;
    const u32 scaled_vram_offset_x = vram_offset_x * m_resolution_scale;
    const u32 scaled_vram_offset_y = vram_offset_y * m_resolution_scale;
-    const u32 display_width = std::min<u32>(m_crtc_state.active_display_width, VRAM_WIDTH - vram_offset_x);
+    const u32 display_width = m_crtc_state.display_vram_width;
-    const u32 display_height = std::min<u32>(m_crtc_state.active_display_height << BoolToUInt8(m_GPUSTAT.In480iMode()),
+    const u32 display_height = m_crtc_state.display_vram_height;
                                             VRAM_HEIGHT - vram_offset_y);
    const u32 scaled_display_width = display_width * m_resolution_scale;
    const u32 scaled_display_height = display_height * m_resolution_scale;
    const bool interlaced = IsDisplayInterlaced();
@ -436,8 +435,10 @@ void GPU_HW_OpenGL_ES::UpdateDisplay()
      glEnable(GL_SCISSOR_TEST);
    }
-    m_host_display->SetDisplayParameters(m_crtc_state.visible_display_width, m_crtc_state.visible_display_height,
+    m_host_display->SetDisplayParameters(m_crtc_state.display_width, m_crtc_state.display_height,
-                                         m_crtc_state.GetActiveDisplayRectangle(), m_crtc_state.display_aspect_ratio);
+                                         m_crtc_state.display_origin_left, m_crtc_state.display_origin_top,
                                         m_crtc_state.display_vram_width, m_crtc_state.display_vram_height,
                                         m_crtc_state.display_aspect_ratio);
  }
 }
--- a/src/core/gpu_sw.cpp
+++ b/src/core/gpu_sw.cpp
@ -84,11 +84,10 @@ void GPU_SW::UpdateDisplay()
  if (!m_system->GetSettings().debugging.show_vram)
  {
    // TODO: Handle interlacing
-    const u32 vram_offset_x = m_crtc_state.regs.X;
+    const u32 vram_offset_x = m_crtc_state.display_vram_left;
-    const u32 vram_offset_y = m_crtc_state.regs.Y;
+    const u32 vram_offset_y = m_crtc_state.display_vram_top;
-    const u32 display_width = std::min<u32>(m_crtc_state.active_display_width, VRAM_WIDTH - vram_offset_x);
+    const u32 display_width = m_crtc_state.display_vram_width;
-    const u32 display_height = std::min<u32>(m_crtc_state.active_display_height << BoolToUInt8(m_GPUSTAT.In480iMode()),
+    const u32 display_height = m_crtc_state.display_vram_height;
                                             VRAM_HEIGHT - vram_offset_y);
    if (m_GPUSTAT.display_disable)
    {
@ -110,8 +109,10 @@ void GPU_SW::UpdateDisplay()
                                  m_display_texture_buffer.data(), display_width * sizeof(u32));
    m_host_display->SetDisplayTexture(m_display_texture->GetHandle(), VRAM_WIDTH, VRAM_HEIGHT, 0, 0, display_width,
                                      display_height);
-    m_host_display->SetDisplayParameters(m_crtc_state.visible_display_width, m_crtc_state.visible_display_height,
+    m_host_display->SetDisplayParameters(m_crtc_state.display_width, m_crtc_state.display_height,
-                                         m_crtc_state.GetActiveDisplayRectangle(), m_crtc_state.display_aspect_ratio);
+                                         m_crtc_state.display_origin_left, m_crtc_state.display_origin_top,
                                         m_crtc_state.display_vram_width, m_crtc_state.display_vram_height,
                                         m_crtc_state.display_aspect_ratio);
  }
  else
  {
@ -120,7 +121,7 @@ void GPU_SW::UpdateDisplay()
                                  m_display_texture_buffer.data(), VRAM_WIDTH * sizeof(u32));
    m_host_display->SetDisplayTexture(m_display_texture->GetHandle(), VRAM_WIDTH, VRAM_HEIGHT, 0, 0, VRAM_WIDTH,
                                      VRAM_HEIGHT);
-    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, Common::Rectangle<s32>(0, 0, VRAM_WIDTH, VRAM_HEIGHT),
+    m_host_display->SetDisplayParameters(VRAM_WIDTH, VRAM_HEIGHT, 0, 0, VRAM_WIDTH, VRAM_HEIGHT,
                                         static_cast<float>(VRAM_WIDTH) / static_cast<float>(VRAM_HEIGHT));
  }
 }
--- a/src/core/host_display.cpp
+++ b/src/core/host_display.cpp
@ -20,35 +20,71 @@ void HostDisplay::WindowResized(s32 new_window_width, s32 new_window_height)
 std::tuple<s32, s32, s32, s32> HostDisplay::CalculateDrawRect() const
 {
 #if 0
  // convert display region to correct pixel aspect ratio
  float display_width, display_height, active_left, active_top, active_width, active_height;
  if (m_display_width >= m_display_height)
  {
    display_width = static_cast<float>(m_display_width);
    display_height = static_cast<float>(m_display_width) / m_display_pixel_aspect_ratio;
    const float scale = display_height / static_cast<float>(m_display_height);
    active_left = static_cast<float>(m_display_active_left);
    active_top = static_cast<float>(m_display_active_top) * scale;
    active_width = static_cast<float>(m_display_active_width);
    active_height = static_cast<float>(m_display_active_width) / m_display_pixel_aspect_ratio;
  }
  else
  {
    display_width = static_cast<float>(m_display_height) * m_display_pixel_aspect_ratio;
    display_height = static_cast<float>(m_display_height);
    const float scale = display_width / static_cast<float>(m_display_width);
    active_left = static_cast<float>(m_display_active_left) * scale;
    active_top = static_cast<float>(m_display_active_top);
    active_width = static_cast<float>(m_display_active_height) * m_display_pixel_aspect_ratio;
    active_height = static_cast<float>(m_display_active_height);
  }
 #else
  const float y_scale =
    (static_cast<float>(m_display_width) / static_cast<float>(m_display_height)) / m_display_pixel_aspect_ratio;
  const float display_width = static_cast<float>(m_display_width);
  const float display_height = static_cast<float>(m_display_height) * y_scale;
  const float active_left = static_cast<float>(m_display_active_left);
  const float active_top = static_cast<float>(m_display_active_top) * y_scale;
  const float active_width = static_cast<float>(m_display_active_width);
  const float active_height = static_cast<float>(m_display_active_height) * y_scale;
 #endif
  // now fit it within the window
  const s32 window_width = m_window_width;
  const s32 window_height = m_window_height - m_display_top_margin;
  const float window_ratio = static_cast<float>(window_width) / static_cast<float>(window_height);
  float scale;
-  int left, top, width, height;
+  int top_padding = 0, left_padding = 0;
-  if (window_ratio >= m_display_aspect_ratio)
+
  if ((display_width / display_height) >= window_ratio)
  {
-    width = static_cast<int>(static_cast<float>(window_height) * m_display_aspect_ratio);
+    // align in middle vertically
-    height = static_cast<int>(window_height);
+    scale = static_cast<float>(window_width) / display_width;
-    scale = static_cast<float>(window_height) / static_cast<float>(m_display_height);
+    top_padding = (window_height - static_cast<s32>(display_height * scale)) / 2;
    left = (window_width - width) / 2;
    top = 0;
  }
  else
  {
-    width = static_cast<int>(window_width);
+    // align in middle horizontally
-    height = static_cast<int>(float(window_width) / m_display_aspect_ratio);
+    scale = static_cast<float>(window_height) / display_height;
-    scale = static_cast<float>(window_width) / static_cast<float>(m_display_width);
+    left_padding = (window_width - static_cast<s32>(display_width * scale)) / 2;
    left = 0;
    top = (window_height - height) / 2;
  }
-  // add in padding
+  int left, top, width, height;
-  left += static_cast<s32>(static_cast<float>(m_display_area.left) * scale);
+  width = static_cast<s32>(active_width * scale);
-  top += static_cast<s32>(static_cast<float>(m_display_area.top) * scale);
+  height = static_cast<s32>(active_height * scale);
-  width -= static_cast<s32>(static_cast<float>(m_display_area.left + (m_display_width - m_display_area.right)) * scale);
+  left = static_cast<s32>(active_left * scale);
-  height -=
+  top = static_cast<s32>(active_top * scale);
-    static_cast<s32>(static_cast<float>(m_display_area.top + (m_display_height - m_display_area.bottom)) * scale);
+
  left += std::max(left_padding, 0);
  top += std::max(top_padding, 0);
  // add in margin
  top += m_display_top_margin;
@ -153,15 +189,15 @@ bool HostDisplay::WriteDisplayTextureToFile(const char* filename, bool full_reso
  s32 resize_height = 0;
  if (apply_aspect_ratio && full_resolution)
  {
-    if (m_display_aspect_ratio > 1.0f)
+    if (m_display_pixel_aspect_ratio > 1.0f)
    {
      resize_width = m_display_texture_view_width;
-      resize_height = static_cast<s32>(static_cast<float>(resize_width) / m_display_aspect_ratio);
+      resize_height = static_cast<s32>(static_cast<float>(resize_width) / m_display_pixel_aspect_ratio);
    }
    else
    {
      resize_height = m_display_texture_view_height;
-      resize_width = static_cast<s32>(static_cast<float>(resize_height) * m_display_aspect_ratio);
+      resize_width = static_cast<s32>(static_cast<float>(resize_height) * m_display_pixel_aspect_ratio);
    }
  }
  else if (apply_aspect_ratio)
--- a/src/core/host_display.h
+++ b/src/core/host_display.h
@ -80,13 +80,16 @@ public:
    m_display_changed = true;
  }
-  void SetDisplayParameters(s32 display_width, s32 display_height, const Common::Rectangle<s32>& display_area,
+  void SetDisplayParameters(s32 display_width, s32 display_height, s32 active_left, s32 active_top, s32 active_width,
-                            float pixel_aspect_ratio)
+                            s32 active_height, float pixel_aspect_ratio)
  {
    m_display_width = display_width;
    m_display_height = display_height;
-    m_display_area = display_area;
+    m_display_active_left = active_left;
-    m_display_aspect_ratio = pixel_aspect_ratio;
+    m_display_active_top = active_top;
    m_display_active_width = active_width;
    m_display_active_height = active_height;
    m_display_pixel_aspect_ratio = pixel_aspect_ratio;
    m_display_changed = true;
  }
@ -109,8 +112,11 @@ protected:
  s32 m_display_width = 0;
  s32 m_display_height = 0;
-  Common::Rectangle<s32> m_display_area{};
+  s32 m_display_active_left = 0;
-  float m_display_aspect_ratio = 1.0f;
+  s32 m_display_active_top = 0;
  s32 m_display_active_width = 0;
  s32 m_display_active_height = 0;
  float m_display_pixel_aspect_ratio = 1.0f;
  void* m_display_texture_handle = nullptr;
  s32 m_display_texture_width = 0;