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115 lines
3.6 KiB
C++
115 lines
3.6 KiB
C++
// Copyright 2009 Dolphin Emulator Project
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// Licensed under GPLv2+
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// Refer to the license.txt file included.
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#pragma once
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#include <d3d11.h>
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#include <memory>
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#include "VideoBackends/D3D/D3DTexture.h"
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#include "VideoCommon/FramebufferManagerBase.h"
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namespace DX11
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{
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// On the GameCube, the game sends a request for the graphics processor to
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// transfer its internal EFB (Embedded Framebuffer) to an area in GameCube RAM
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// called the XFB (External Framebuffer). The size and location of the XFB is
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// decided at the time of the copy, and the format is always YUYV. The video
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// interface is given a pointer to the XFB, which will be decoded and
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// displayed on the TV.
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//
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// There are two ways for Dolphin to emulate this:
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//
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// Real XFB mode:
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//
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// Dolphin will behave like the GameCube and encode the EFB to
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// a portion of GameCube RAM. The emulated video interface will decode the data
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// for output to the screen.
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//
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// Advantages: Behaves exactly like the GameCube.
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// Disadvantages: Resolution will be limited.
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//
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// Virtual XFB mode:
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//
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// When a request is made to copy the EFB to an XFB, Dolphin
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// will remember the RAM location and size of the XFB in a Virtual XFB list.
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// The video interface will look up the XFB in the list and use the enhanced
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// data stored there, if available.
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//
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// Advantages: Enables high resolution graphics, better than real hardware.
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// Disadvantages: If the GameCube CPU writes directly to the XFB (which is
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// possible but uncommon), the Virtual XFB will not capture this information.
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// There may be multiple XFBs in GameCube RAM. This is the maximum number to
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// virtualize.
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struct XFBSource : public XFBSourceBase
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{
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XFBSource(D3DTexture2D* _tex, int slices) : tex(_tex), m_slices(slices) {}
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~XFBSource() { tex->Release(); }
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void DecodeToTexture(u32 xfbAddr, u32 fbWidth, u32 fbHeight) override;
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void CopyEFB(float Gamma) override;
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D3DTexture2D* const tex;
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const int m_slices;
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};
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class FramebufferManager : public FramebufferManagerBase
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{
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public:
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FramebufferManager();
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~FramebufferManager();
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static D3DTexture2D*& GetEFBColorTexture();
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static D3DTexture2D*& GetEFBColorReadTexture();
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static ID3D11Texture2D*& GetEFBColorStagingBuffer();
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static D3DTexture2D*& GetEFBDepthTexture();
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static D3DTexture2D*& GetEFBDepthReadTexture();
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static ID3D11Texture2D*& GetEFBDepthStagingBuffer();
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static D3DTexture2D*& GetResolvedEFBColorTexture();
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static D3DTexture2D*& GetResolvedEFBDepthTexture();
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static D3DTexture2D*& GetEFBColorTempTexture() { return m_efb.color_temp_tex; }
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static void SwapReinterpretTexture()
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{
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D3DTexture2D* swaptex = GetEFBColorTempTexture();
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m_efb.color_temp_tex = GetEFBColorTexture();
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m_efb.color_tex = swaptex;
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}
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private:
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std::unique_ptr<XFBSourceBase> CreateXFBSource(unsigned int target_width,
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unsigned int target_height,
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unsigned int layers) override;
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void GetTargetSize(unsigned int* width, unsigned int* height) override;
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void CopyToRealXFB(u32 xfbAddr, u32 fbStride, u32 fbHeight, const EFBRectangle& sourceRc,
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float Gamma) override;
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static struct Efb
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{
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D3DTexture2D* color_tex;
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ID3D11Texture2D* color_staging_buf;
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D3DTexture2D* color_read_texture;
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D3DTexture2D* depth_tex;
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ID3D11Texture2D* depth_staging_buf;
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D3DTexture2D* depth_read_texture;
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D3DTexture2D* color_temp_tex;
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D3DTexture2D* resolved_color_tex;
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D3DTexture2D* resolved_depth_tex;
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int slices;
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} m_efb;
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static unsigned int m_target_width;
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static unsigned int m_target_height;
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};
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} // namespace DX11
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