pcsx2/plugins/GSdx_legacy/GSDevice9.cpp

/*
 *	Copyright (C) 2007-2009 Gabest
 *	http://www.gabest.org
 *
 *  This Program is free software; you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation; either version 2, or (at your option)
 *  any later version.
 *
 *  This Program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with GNU Make; see the file COPYING.  If not, write to
 *  the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA USA.
 *  http://www.gnu.org/copyleft/gpl.html
 *
 */

#include "stdafx.h"
#include "GSdx.h"
#include "GSDevice9.h"
#include "resource.h"
#include <fstream>

GSDevice9::GSDevice9()
	: m_lost(false)
{
	m_rbswapped = true;
	FXAA_Compiled = false;
	ExShader_Compiled = false;


	memset(&m_pp, 0, sizeof(m_pp));
	memset(&m_d3dcaps, 0, sizeof(m_d3dcaps));
	memset(&m_state, 0, sizeof(m_state));

	m_state.bf = 0xffffffff;
}

GSDevice9::~GSDevice9()
{
	for_each(m_om_bs.begin(), m_om_bs.end(), delete_second());
	for_each(m_om_dss.begin(), m_om_dss.end(), delete_second());
	for_each(m_ps_ss.begin(), m_ps_ss.end(), delete_second());
	for_each(m_mskfix.begin(), m_mskfix.end(), delete_second());

	if(m_state.vs_cb) _aligned_free(m_state.vs_cb);
	if(m_state.ps_cb) _aligned_free(m_state.ps_cb);
}

static void FindAdapter(IDirect3D9 *d3d9, UINT &adapter, D3DDEVTYPE &devtype, std::string adapter_id = "")
{
	adapter = D3DADAPTER_DEFAULT;
	devtype = D3DDEVTYPE_HAL;

	if (!adapter_id.length())
		adapter_id = theApp.GetConfig("Adapter", "default");

	if (adapter_id == "default")
		;
	else if (adapter_id == "ref")
	{
		devtype = D3DDEVTYPE_REF;
	}
	else
	{
		int n = d3d9->GetAdapterCount();
		for (int i = 0; i < n; i++)
		{
			D3DADAPTER_IDENTIFIER9 id;
			if (D3D_OK != d3d9->GetAdapterIdentifier(i, 0, &id))
				break;
			if (GSAdapter(id) == adapter_id)
			{
				adapter = i;
				devtype = D3DDEVTYPE_HAL;
				break;
			}
		}
	}
}

// if supported and null != msaa_desc, msaa_desc will contain requested Count and Quality

static bool IsMsaaSupported(IDirect3D9* d3d, UINT adapter, D3DDEVTYPE devtype, D3DFORMAT depth_format, uint32 msaaCount, DXGI_SAMPLE_DESC* msaa_desc = NULL)
{
	if(msaaCount > 16) return false;

	D3DCAPS9 d3dcaps;

	memset(&d3dcaps, 0, sizeof(d3dcaps));

	d3d->GetDeviceCaps(adapter, devtype, &d3dcaps);

	DWORD quality[2] = {0, 0};

	if(SUCCEEDED(d3d->CheckDeviceMultiSampleType(d3dcaps.AdapterOrdinal, d3dcaps.DeviceType, D3DFMT_A8R8G8B8, TRUE, (D3DMULTISAMPLE_TYPE)msaaCount, &quality[0])) && quality[0] > 0
	&& SUCCEEDED(d3d->CheckDeviceMultiSampleType(d3dcaps.AdapterOrdinal, d3dcaps.DeviceType, depth_format, TRUE, (D3DMULTISAMPLE_TYPE)msaaCount, &quality[1])) && quality[1] > 0)
	{
		if(msaa_desc)
		{
			msaa_desc->Count = msaaCount;
			msaa_desc->Quality = std::min<DWORD>(quality[0] - 1, quality[1] - 1);
		}

		return true;
	}

	return false;
}

static bool TestDepthFormat(IDirect3D9* d3d, UINT adapter, D3DDEVTYPE devtype, D3DFORMAT format)
{
	if(FAILED(d3d->CheckDeviceFormat(adapter, devtype, D3DFMT_X8R8G8B8, D3DUSAGE_DEPTHSTENCIL, D3DRTYPE_SURFACE, format)))
	{
		return false;
	}

	if(FAILED(d3d->CheckDepthStencilMatch(adapter, devtype, D3DFMT_X8R8G8B8, D3DFMT_X8R8G8B8, format)))
	{
		return false;
	}

	return true;
}

static D3DFORMAT BestD3dFormat(IDirect3D9* d3d, UINT adapter, D3DDEVTYPE devtype, int msaaCount = 0, DXGI_SAMPLE_DESC* msaa_desc = NULL)
{
	// In descending order of preference

	static D3DFORMAT fmts[] =
	{
		D3DFMT_D32,
		D3DFMT_D32F_LOCKABLE,
		D3DFMT_D24S8
	};

	if(1 == msaaCount) msaaCount = 0;

	for(size_t i = 0; i < countof(fmts); i++)
	{
		if(TestDepthFormat(d3d, adapter, devtype, fmts[i]) && (!msaaCount || IsMsaaSupported(d3d, adapter, devtype, fmts[i], msaaCount, msaa_desc)))
		{
			return fmts[i];
		}
	}

	return D3DFMT_UNKNOWN;
}

// return: 32, 24, or 0 if not supported. if 1==msaa, considered as msaa=0

uint32 GSDevice9::GetMaxDepth(uint32 msaa, std::string adapter_id)
{
	CComPtr<IDirect3D9> d3d;

	d3d.Attach(Direct3DCreate9(D3D_SDK_VERSION));

	UINT adapter;
	D3DDEVTYPE devtype;

	FindAdapter(d3d, adapter, devtype, adapter_id);

	switch(BestD3dFormat(d3d, adapter, devtype, msaa))
	{
		case D3DFMT_D32:
		case D3DFMT_D32F_LOCKABLE:
			return 32;
		case D3DFMT_D24S8:
			return 24;
	}

	return 0;
}

void GSDevice9::ForceValidMsaaConfig()
{
	if(0 == GetMaxDepth(theApp.GetConfig("UserHacks_MSAA", 0)))
	{
		theApp.SetConfig("UserHacks_MSAA", 0); // replace invalid msaa value in ini file with 0.
	}
};

bool GSDevice9::Create(GSWnd* wnd)
{
	if(!__super::Create(wnd))
	{
		return false;
	}

	// d3d

	m_d3d.Attach(Direct3DCreate9(D3D_SDK_VERSION));

	if(!m_d3d) return false;

	UINT adapter;
	D3DDEVTYPE devtype;

	FindAdapter(m_d3d, adapter, devtype);

	D3DADAPTER_IDENTIFIER9 id;

	if(S_OK == m_d3d->GetAdapterIdentifier(adapter, 0, &id))
	{
		printf("%s (%d.%d.%d.%d)\n",
			id.Description,
			id.DriverVersion.HighPart >> 16,
			id.DriverVersion.HighPart & 0xffff,
			id.DriverVersion.LowPart >> 16,
			id.DriverVersion.LowPart & 0xffff);
	}

	ForceValidMsaaConfig();

	// Get best format/depth for msaa. Assumption is that if the resulting depth is 24 instead of possible 32,
	// the user was already warned when she selected it. (Lower res z buffer without warning is unacceptable).

	m_depth_format = BestD3dFormat(m_d3d, adapter, devtype, m_msaa, &m_msaa_desc);

	if(D3DFMT_UNKNOWN == m_depth_format)
	{
		// can't find a format with requested msaa, try without.

		m_depth_format = BestD3dFormat(m_d3d, adapter, devtype, 0);

		if(D3DFMT_UNKNOWN == m_depth_format)
		{
			return false;
		}

		m_msaa = 0;
	}

	memset(&m_d3dcaps, 0, sizeof(m_d3dcaps));

	m_d3d->GetDeviceCaps(D3DADAPTER_DEFAULT, D3DDEVTYPE_HAL, &m_d3dcaps);

	//

	if(m_d3dcaps.VertexShaderVersion < (m_d3dcaps.PixelShaderVersion & ~0x10000))
	{
		if(m_d3dcaps.VertexShaderVersion > D3DVS_VERSION(0, 0))
		{
			ASSERT(0);

			return false;
		}

		// else vertex shader should be emulated in software (gma950)
	}

	m_d3dcaps.VertexShaderVersion = m_d3dcaps.PixelShaderVersion & ~0x10000;

	if(m_d3dcaps.PixelShaderVersion >= D3DPS_VERSION(3, 0))
	{
		SetFeatureLevel(D3D_FEATURE_LEVEL_9_3, false);
	}
	else if(m_d3dcaps.PixelShaderVersion >= D3DPS_VERSION(2, 0))
	{
		SetFeatureLevel(D3D_FEATURE_LEVEL_9_2, false);
	}
	else
	{
		string s = format(
			"Supported pixel shader version is too low!\n\nSupported: %d.%d\nNeeded: 2.0 or higher",
			D3DSHADER_VERSION_MAJOR(m_d3dcaps.PixelShaderVersion), D3DSHADER_VERSION_MINOR(m_d3dcaps.PixelShaderVersion));

		MessageBox(NULL, s.c_str(), "GSdx", MB_OK);

		return false;
	}

	if(!Reset(1, 1))
	{
		return false;
	}

	m_dev->Clear(0, NULL, D3DCLEAR_TARGET, 0, 1.0f, 0);

	// convert

	static const D3DVERTEXELEMENT9 il_convert[] =
	{
		{0, 0,  D3DDECLTYPE_FLOAT4, D3DDECLMETHOD_DEFAULT, D3DDECLUSAGE_POSITION, 0},
		{0, 16, D3DDECLTYPE_FLOAT2, D3DDECLMETHOD_DEFAULT, D3DDECLUSAGE_TEXCOORD, 0},
		D3DDECL_END()
	};

	vector<unsigned char> shader;
	theApp.LoadResource(IDR_CONVERT_FX, shader);
	CompileShader((const char *)shader.data(), shader.size(), "convert.fx", "vs_main", nullptr, &m_convert.vs, il_convert, countof(il_convert), &m_convert.il);

	for(size_t i = 0; i < countof(m_convert.ps); i++)
	{
		CompileShader((const char *)shader.data(), shader.size(), "convert.fx", format("ps_main%d", i), nullptr, &m_convert.ps[i]);
	}

	m_convert.dss.DepthEnable = false;
	m_convert.dss.StencilEnable = false;

	m_convert.bs.BlendEnable = false;
	m_convert.bs.RenderTargetWriteMask = D3DCOLORWRITEENABLE_RGBA;
	D3DTEXTUREFILTERTYPE LinearToAnisotropic = theApp.GetConfig("MaxAnisotropy", 0) && !theApp.GetConfig("paltex", 0) ? D3DTEXF_ANISOTROPIC : D3DTEXF_LINEAR;
	D3DTEXTUREFILTERTYPE PointToAnisotropic = theApp.GetConfig("MaxAnisotropy", 0) && !theApp.GetConfig("paltex", 0) ? D3DTEXF_ANISOTROPIC : D3DTEXF_POINT;

	m_convert.ln.FilterMin[0] = LinearToAnisotropic;
	m_convert.ln.FilterMag[0] = LinearToAnisotropic;
	m_convert.ln.FilterMin[1] = LinearToAnisotropic;
	m_convert.ln.FilterMag[1] = LinearToAnisotropic;
	m_convert.ln.AddressU = D3DTADDRESS_CLAMP;
	m_convert.ln.AddressV = D3DTADDRESS_CLAMP;
	m_convert.ln.MaxAnisotropy = theApp.GetConfig("MaxAnisotropy", 0);

	m_convert.pt.FilterMin[0] = PointToAnisotropic;
	m_convert.pt.FilterMag[0] = PointToAnisotropic;
	m_convert.pt.FilterMin[1] = PointToAnisotropic;
	m_convert.pt.FilterMag[1] = PointToAnisotropic;
	m_convert.pt.AddressU = D3DTADDRESS_CLAMP;
	m_convert.pt.AddressV = D3DTADDRESS_CLAMP;
	m_convert.pt.MaxAnisotropy = theApp.GetConfig("MaxAnisotropy", 0);

	// merge

	theApp.LoadResource(IDR_MERGE_FX, shader);
	for(size_t i = 0; i < countof(m_merge.ps); i++)
	{
		CompileShader((const char *)shader.data(), shader.size(), "merge.fx", format("ps_main%d", i), nullptr, &m_merge.ps[i]);
	}

	m_merge.bs.BlendEnable = true;
	m_merge.bs.BlendOp = D3DBLENDOP_ADD;
	m_merge.bs.SrcBlend = D3DBLEND_SRCALPHA;
	m_merge.bs.DestBlend = D3DBLEND_INVSRCALPHA;
	m_merge.bs.BlendOpAlpha = D3DBLENDOP_ADD;
	m_merge.bs.SrcBlendAlpha = D3DBLEND_ONE;
	m_merge.bs.DestBlendAlpha = D3DBLEND_ZERO;
	m_merge.bs.RenderTargetWriteMask = D3DCOLORWRITEENABLE_RGBA;

	// interlace

	theApp.LoadResource(IDR_INTERLACE_FX, shader);
	for(size_t i = 0; i < countof(m_interlace.ps); i++)
	{
		CompileShader((const char *)shader.data(), shader.size(), "interlace.fx", format("ps_main%d", i), nullptr, &m_interlace.ps[i]);
	}

	// Shade Boost	

	int ShadeBoost_Contrast = theApp.GetConfig("ShadeBoost_Contrast", 50);
	int ShadeBoost_Brightness = theApp.GetConfig("ShadeBoost_Brightness", 50);
	int ShadeBoost_Saturation = theApp.GetConfig("ShadeBoost_Saturation", 50);
		
	string str[3];		
		
	str[0] = format("%d", ShadeBoost_Saturation);
	str[1] = format("%d", ShadeBoost_Brightness);
	str[2] = format("%d", ShadeBoost_Contrast);

	D3D_SHADER_MACRO macro[] =
	{			
		{"SB_SATURATION", str[0].c_str()},
		{"SB_BRIGHTNESS", str[1].c_str()},
		{"SB_CONTRAST", str[2].c_str()},
		{NULL, NULL},
	};

	theApp.LoadResource(IDR_SHADEBOOST_FX, shader);
	CompileShader((const char *)shader.data(), shader.size(), "shadeboost.fx", "ps_main", macro, &m_shadeboost.ps);

	// create shader layout

	VSSelector sel;
	VSConstantBuffer cb;

	SetupVS(sel, &cb);

	//

	memset(&m_date.dss, 0, sizeof(m_date.dss));

	m_date.dss.StencilEnable = true;
	m_date.dss.StencilReadMask = 1;
	m_date.dss.StencilWriteMask = 1;
	m_date.dss.StencilFunc = D3DCMP_ALWAYS;
	m_date.dss.StencilPassOp = D3DSTENCILOP_REPLACE;
	m_date.dss.StencilRef = 1;

	memset(&m_date.bs, 0, sizeof(m_date.bs));

	//

	return true;
}

bool GSDevice9::Reset(int w, int h)
{
	if(!__super::Reset(w, h))
		return false;

	HRESULT hr;

	int mode = (!m_wnd->IsManaged() || theApp.GetConfig("windowed", 1)) ? Windowed : Fullscreen;

	if(mode == DontCare)
	{
		mode = m_pp.Windowed ? Windowed : Fullscreen;
	}

	if(!m_lost)
	{
		if(m_swapchain && mode != Fullscreen && m_pp.Windowed)
		{
			m_swapchain = NULL;

			m_pp.BackBufferWidth = w;
			m_pp.BackBufferHeight = h;
			m_pp.PresentationInterval = m_vsync ? D3DPRESENT_INTERVAL_ONE : D3DPRESENT_INTERVAL_IMMEDIATE;

			hr = m_dev->CreateAdditionalSwapChain(&m_pp, &m_swapchain);

			if(FAILED(hr)) return false;

			CComPtr<IDirect3DSurface9> backbuffer;
			hr = m_swapchain->GetBackBuffer(0, D3DBACKBUFFER_TYPE_MONO, &backbuffer);
			m_backbuffer = new GSTexture9(backbuffer);

			return true;
		}
	}

	m_swapchain = NULL;

	m_vb = NULL;
	m_vb_old = NULL;

	m_vertex.start = 0;
	m_vertex.count = 0;
	m_index.start = 0;
	m_index.count = 0;

	if(m_state.vs_cb) _aligned_free(m_state.vs_cb);
	if(m_state.ps_cb) _aligned_free(m_state.ps_cb);

	memset(&m_state, 0, sizeof(m_state));

	m_state.bf = 0xffffffff;

	memset(&m_pp, 0, sizeof(m_pp));

	m_pp.Windowed = TRUE;
	m_pp.hDeviceWindow = (HWND)m_wnd->GetHandle();
	m_pp.SwapEffect = D3DSWAPEFFECT_FLIP;
	m_pp.BackBufferFormat = D3DFMT_X8R8G8B8;
	m_pp.BackBufferWidth = 1;
	m_pp.BackBufferHeight = 1;
	m_pp.PresentationInterval = m_vsync ? D3DPRESENT_INTERVAL_ONE : D3DPRESENT_INTERVAL_IMMEDIATE;

	// m_pp.Flags |= D3DPRESENTFLAG_VIDEO; // enables tv-out (but I don't think anyone would still use a regular tv...)

	int mw = theApp.GetConfig("ModeWidth", 0);
	int mh = theApp.GetConfig("ModeHeight", 0);
	int mrr = theApp.GetConfig("ModeRefreshRate", 0);

	if(m_wnd->IsManaged() && mode == Fullscreen && mw > 0 && mh > 0 && mrr >= 0)
	{
		m_pp.Windowed = FALSE;
		m_pp.BackBufferWidth = mw;
		m_pp.BackBufferHeight = mh;
		// m_pp.FullScreen_RefreshRateInHz = mrr;

		m_wnd->HideFrame();
	}

	if(!m_dev)
	{
		uint32 flags = m_d3dcaps.VertexProcessingCaps ? D3DCREATE_HARDWARE_VERTEXPROCESSING : D3DCREATE_SOFTWARE_VERTEXPROCESSING;

		if(flags & D3DCREATE_HARDWARE_VERTEXPROCESSING)
		{
			flags |= D3DCREATE_PUREDEVICE;
		}

		hr = m_d3d->CreateDevice(D3DADAPTER_DEFAULT, D3DDEVTYPE_HAL, (HWND)m_wnd->GetHandle(), flags, &m_pp, &m_dev);

		if(FAILED(hr)) return false;
	}
	else
	{
		hr = m_dev->Reset(&m_pp);

		if(FAILED(hr))
		{
			if(D3DERR_DEVICELOST == hr)
			{
				Sleep(1000);

				hr = m_dev->Reset(&m_pp);
			}

			if(FAILED(hr)) return false;
		}
	}

	if(m_pp.Windowed)
	{
		m_pp.BackBufferWidth = 1;
		m_pp.BackBufferHeight = 1;

		hr = m_dev->CreateAdditionalSwapChain(&m_pp, &m_swapchain);

		if(FAILED(hr)) return false;
	}

	CComPtr<IDirect3DSurface9> backbuffer;

	if(m_swapchain)
	{
		hr = m_swapchain->GetBackBuffer(0, D3DBACKBUFFER_TYPE_MONO, &backbuffer);
	}
	else
	{
		hr = m_dev->GetBackBuffer(0, 0, D3DBACKBUFFER_TYPE_MONO, &backbuffer);
	}

	m_backbuffer = new GSTexture9(backbuffer);

	m_dev->SetRenderState(D3DRS_CULLMODE, D3DCULL_NONE);
	m_dev->SetRenderState(D3DRS_LIGHTING, FALSE);
	m_dev->SetRenderState(D3DRS_ALPHATESTENABLE, FALSE);
	m_dev->SetRenderState(D3DRS_SCISSORTESTENABLE, TRUE);

	return true;
}

bool GSDevice9::IsLost(bool update)
{
	if(!m_lost || update)
	{
		HRESULT hr = m_dev->TestCooperativeLevel();

		m_lost = hr == D3DERR_DEVICELOST || hr == D3DERR_DEVICENOTRESET;
	}

	return m_lost;
}

void GSDevice9::Flip()
{
	m_dev->EndScene();

	HRESULT hr;

	if(m_swapchain)
	{
		hr = m_swapchain->Present(NULL, NULL, NULL, NULL, 0);
	}
	else
	{
		hr = m_dev->Present(NULL, NULL, NULL, NULL);
	}

	m_dev->BeginScene();

	if(FAILED(hr))
	{
		m_lost = true;
	}
}

void GSDevice9::SetVSync(bool enable)
{
	if(m_vsync == enable) return;

	__super::SetVSync(enable);

	// Clever trick:  Delete the backbuffer, so that the next Present will fail and
	// cause a DXDevice9::Reset call, which re-creates the backbuffer with current
	// vsync settings. :)

	delete m_backbuffer;

	m_backbuffer = NULL;
}

void GSDevice9::BeginScene()
{
	// m_dev->BeginScene();
}

void GSDevice9::DrawPrimitive()
{
	int prims = 0;

	switch(m_state.topology)
	{
    case D3DPT_POINTLIST:
		prims = m_vertex.count;
		break;
    case D3DPT_LINELIST:
		prims = m_vertex.count / 2;
		break;
    case D3DPT_LINESTRIP:
		prims = m_vertex.count - 1;
		break;
    case D3DPT_TRIANGLELIST:
		prims = m_vertex.count / 3;
		break;
    case D3DPT_TRIANGLESTRIP:
    case D3DPT_TRIANGLEFAN:
		prims = m_vertex.count - 2;
		break;
	default:
		__assume(0);
	}

	m_dev->DrawPrimitive(m_state.topology, m_vertex.start, prims);
}

void GSDevice9::DrawIndexedPrimitive()
{
	int prims = 0;

	switch(m_state.topology)
	{
    case D3DPT_POINTLIST:
		prims = m_index.count;
		break;
    case D3DPT_LINELIST:
    case D3DPT_LINESTRIP:
		prims = m_index.count / 2;
		break;
    case D3DPT_TRIANGLELIST:
    case D3DPT_TRIANGLESTRIP:
    case D3DPT_TRIANGLEFAN:
		prims = m_index.count / 3;
		break;
	default:
		__assume(0);
	}

	m_dev->DrawIndexedPrimitive(m_state.topology, m_vertex.start, 0, m_index.count, m_index.start, prims);
}

void GSDevice9::EndScene()
{
	// m_dev->EndScene();

	__super::EndScene();
}

void GSDevice9::ClearRenderTarget(GSTexture* t, const GSVector4& c)
{
	if (!t) return;
	ClearRenderTarget(t, (c * 255 + 0.5f).zyxw().rgba32());
}

void GSDevice9::ClearRenderTarget(GSTexture* rt, uint32 c)
{
	if (!rt) return;
	CComPtr<IDirect3DSurface9> surface;
	m_dev->GetRenderTarget(0, &surface);
	m_dev->SetRenderTarget(0, *(GSTexture9*)rt);
	m_dev->Clear(0, NULL, D3DCLEAR_TARGET, c, 0, 0);
	m_dev->SetRenderTarget(0, surface);
}

void GSDevice9::ClearDepth(GSTexture* t, float c)
{
	if (!t) return;
	CComPtr<IDirect3DSurface9> dssurface;
	m_dev->GetDepthStencilSurface(&dssurface);
	m_dev->SetDepthStencilSurface(*(GSTexture9*)t);
	m_dev->Clear(0, NULL, D3DCLEAR_ZBUFFER, 0, c, 0);
	m_dev->SetDepthStencilSurface(dssurface);
}

void GSDevice9::ClearStencil(GSTexture* t, uint8 c)
{
	if (!t) return;
	CComPtr<IDirect3DSurface9> dssurface;
	m_dev->GetDepthStencilSurface(&dssurface);
	m_dev->SetDepthStencilSurface(*(GSTexture9*)t);
	m_dev->Clear(0, NULL, D3DCLEAR_STENCIL, 0, 0, c);
	m_dev->SetDepthStencilSurface(dssurface);
}

GSTexture* GSDevice9::CreateSurface(int type, int w, int h, bool msaa, int format)
{
	HRESULT hr;

	CComPtr<IDirect3DTexture9> texture;
	CComPtr<IDirect3DSurface9> surface;

	switch(type)
	{
	case GSTexture::RenderTarget:
		if(msaa) hr = m_dev->CreateRenderTarget(w, h, (D3DFORMAT)format, (D3DMULTISAMPLE_TYPE)m_msaa_desc.Count, m_msaa_desc.Quality, FALSE, &surface, NULL);
		else hr = m_dev->CreateTexture(w, h, 1, D3DUSAGE_RENDERTARGET, (D3DFORMAT)format, D3DPOOL_DEFAULT, &texture, NULL);
		break;
	case GSTexture::DepthStencil:
		if(msaa) hr = m_dev->CreateDepthStencilSurface(w, h, (D3DFORMAT)format, (D3DMULTISAMPLE_TYPE)m_msaa_desc.Count, m_msaa_desc.Quality, FALSE, &surface, NULL);
		else hr = m_dev->CreateDepthStencilSurface(w, h, (D3DFORMAT)format, D3DMULTISAMPLE_NONE, 0, FALSE, &surface, NULL);
		break;
	case GSTexture::Texture:
		hr = m_dev->CreateTexture(w, h, 1, 0, (D3DFORMAT)format, D3DPOOL_MANAGED, &texture, NULL);
		break;
	case GSTexture::Offscreen:
		hr = m_dev->CreateOffscreenPlainSurface(w, h, (D3DFORMAT)format, D3DPOOL_SYSTEMMEM, &surface, NULL);
		break;
	}

	GSTexture9* t = NULL;

	if(surface)
	{
		t = new GSTexture9(surface);
	}

	if(texture)
	{
		t = new GSTexture9(texture);
	}

	if(t)
	{
		switch(type)
		{
		case GSTexture::RenderTarget:
			ClearRenderTarget(t, 0);
			break;
		case GSTexture::DepthStencil:
			ClearDepth(t, 0);
			break;
		}
	}

	return t;
}

GSTexture* GSDevice9::CreateRenderTarget(int w, int h, bool msaa, int format)
{
	return __super::CreateRenderTarget(w, h, msaa, format ? format : D3DFMT_A8R8G8B8);
}

GSTexture* GSDevice9::CreateDepthStencil(int w, int h, bool msaa, int format)
{
	return __super::CreateDepthStencil(w, h, msaa, format ? format : m_depth_format);
}

GSTexture* GSDevice9::CreateTexture(int w, int h, int format)
{
	return __super::CreateTexture(w, h, format ? format : D3DFMT_A8R8G8B8);
}

GSTexture* GSDevice9::CreateOffscreen(int w, int h, int format)
{
	return __super::CreateOffscreen(w, h, format ? format : D3DFMT_A8R8G8B8);
}

GSTexture* GSDevice9::Resolve(GSTexture* t)
{
	ASSERT(t != NULL && t->IsMSAA());

	if(GSTexture* dst = CreateRenderTarget(t->GetWidth(), t->GetHeight(), false, t->GetFormat()))
	{
		dst->SetScale(t->GetScale());

		m_dev->StretchRect(*(GSTexture9*)t, NULL, *(GSTexture9*)dst, NULL, D3DTEXF_POINT);

		return dst;
	}

	return NULL;
}

GSTexture* GSDevice9::CopyOffscreen(GSTexture* src, const GSVector4& sRect, int w, int h, int format, int ps_shader)
{
	GSTexture* dst = NULL;

	if(format == 0)
	{
		format = D3DFMT_A8R8G8B8;
	}

	if(format != D3DFMT_A8R8G8B8)
	{
		ASSERT(0);

		return false;
	}

	if(GSTexture* rt = CreateRenderTarget(w, h, false, format))
	{
		GSVector4 dRect(0, 0, w, h);

		if(GSTexture* src2 = src->IsMSAA() ? Resolve(src) : src)
		{
			StretchRect(src2, sRect, rt, dRect, m_convert.ps[1], NULL, 0);

			if(src2 != src) Recycle(src2);
		}

		dst = CreateOffscreen(w, h, format);

		if(dst)
		{
			m_dev->GetRenderTargetData(*(GSTexture9*)rt, *(GSTexture9*)dst);
		}

		Recycle(rt);
	}

	return dst;
}

void GSDevice9::CopyRect(GSTexture* sTex, GSTexture* dTex, const GSVector4i& r)
{
	if(!sTex || !dTex)
	{
		ASSERT(0);
		return;
	}

	m_dev->StretchRect(*(GSTexture9*)sTex, r, *(GSTexture9*)dTex, r, D3DTEXF_NONE);
}

void GSDevice9::StretchRect(GSTexture* sTex, const GSVector4& sRect, GSTexture* dTex, const GSVector4& dRect, int shader, bool linear)
{
	StretchRect(sTex, sRect, dTex, dRect, m_convert.ps[shader], NULL, 0, linear);
}

void GSDevice9::StretchRect(GSTexture* sTex, const GSVector4& sRect, GSTexture* dTex, const GSVector4& dRect, IDirect3DPixelShader9* ps, const float* ps_cb, int ps_cb_len, bool linear)
{
	StretchRect(sTex, sRect, dTex, dRect, ps, ps_cb, ps_cb_len, &m_convert.bs, linear);
}

void GSDevice9::StretchRect(GSTexture* sTex, const GSVector4& sRect, GSTexture* dTex, const GSVector4& dRect, IDirect3DPixelShader9* ps, const float* ps_cb, int ps_cb_len, Direct3DBlendState9* bs, bool linear)
{
	if(!sTex || !dTex)
	{
		ASSERT(0);
		return;
	}

	BeginScene();

	GSVector2i ds = dTex->GetSize();

	// om

	OMSetDepthStencilState(&m_convert.dss);
	OMSetBlendState(bs, 0);
	OMSetRenderTargets(dTex, NULL);

	// ia

	float left = dRect.x * 2 / ds.x - 1.0f;
	float top = 1.0f - dRect.y * 2 / ds.y;
	float right = dRect.z * 2 / ds.x - 1.0f;
	float bottom = 1.0f - dRect.w * 2 / ds.y;

	GSVertexPT1 vertices[] =
	{
		{GSVector4(left, top, 0.5f, 1.0f), GSVector2(sRect.x, sRect.y)},
		{GSVector4(right, top, 0.5f, 1.0f), GSVector2(sRect.z, sRect.y)},
		{GSVector4(left, bottom, 0.5f, 1.0f), GSVector2(sRect.x, sRect.w)},
		{GSVector4(right, bottom, 0.5f, 1.0f), GSVector2(sRect.z, sRect.w)},
	};

	for(size_t i = 0; i < countof(vertices); i++)
	{
		vertices[i].p.x -= 1.0f / ds.x;
		vertices[i].p.y += 1.0f / ds.y;
	}

	IASetVertexBuffer(vertices, sizeof(vertices[0]), countof(vertices));
	IASetPrimitiveTopology(D3DPT_TRIANGLESTRIP);
	IASetInputLayout(m_convert.il);

	// vs

	VSSetShader(m_convert.vs, NULL, 0);

	// ps

	PSSetSamplerState(linear ? &m_convert.ln : &m_convert.pt);
	PSSetShaderResources(sTex, NULL);
	PSSetShader(ps, ps_cb, ps_cb_len);

	//

	DrawPrimitive();

	//

	EndScene();
}

void GSDevice9::DoMerge(GSTexture* sTex[2], GSVector4* sRect, GSTexture* dTex, GSVector4* dRect, bool slbg, bool mmod, const GSVector4& c)
{
	ClearRenderTarget(dTex, c);

	if(sTex[1] && !slbg)
	{
		StretchRect(sTex[1], sRect[1], dTex, dRect[1], m_merge.ps[0], NULL, true);
	}

	if(sTex[0])
	{
		MergeConstantBuffer cb;

		cb.BGColor = c;

		StretchRect(sTex[0], sRect[0], dTex, dRect[0], m_merge.ps[mmod ? 1 : 0], (const float*)&cb, 1, &m_merge.bs, true);
	}
}

void GSDevice9::DoInterlace(GSTexture* sTex, GSTexture* dTex, int shader, bool linear, float yoffset)
{
	GSVector4 s = GSVector4(dTex->GetSize());

	GSVector4 sRect(0, 0, 1, 1);
	GSVector4 dRect(0.0f, yoffset, s.x, s.y + yoffset);

	InterlaceConstantBuffer cb;

	cb.ZrH = GSVector2(0, 1.0f / s.y);
	cb.hH = (float)s.y / 2;

	StretchRect(sTex, sRect, dTex, dRect, m_interlace.ps[shader], (const float*)&cb, 1, linear);
}

void GSDevice9::InitExternalFX()
{
	if (!ExShader_Compiled)
	{
		try {
			std::string config_name(theApp.GetConfig("shaderfx_conf", "shaders/GSdx_FX_Settings.ini"));
			std::ifstream fconfig(config_name);
			std::stringstream shader;
			if (fconfig.good())
				shader << fconfig.rdbuf() << "\n";
			else
				fprintf(stderr, "GSdx: External shader config '%s' not loaded.\n", config_name.c_str());

			std::string shader_name(theApp.GetConfig("shaderfx_glsl", "shaders/GSdx.fx"));
			std::ifstream fshader(shader_name);
			if (fshader.good())
			{
				shader << fshader.rdbuf();
				CompileShader(shader.str().c_str(), shader.str().length(), shader_name.c_str(), "ps_main", nullptr, &m_shaderfx.ps);
			}
			else
			{
				fprintf(stderr, "GSdx: External shader '%s' not loaded and will be disabled!\n", shader_name.c_str());
			}
		}
		catch (GSDXRecoverableError) {
			printf("GSdx: failed to compile external post-processing shader. \n");
		}
		ExShader_Compiled = true;
	}
}

void GSDevice9::DoExternalFX(GSTexture* sTex, GSTexture* dTex)
{
	GSVector2i s = dTex->GetSize();

	GSVector4 sRect(0, 0, 1, 1);
	GSVector4 dRect(0, 0, s.x, s.y);

	ExternalFXConstantBuffer cb;
	
	InitExternalFX();

	cb.xyFrame = GSVector2(s.x, s.y);
	cb.rcpFrame = GSVector4(1.0f / s.x, 1.0f / s.y, 0.0f, 0.0f);
	cb.rcpFrameOpt = GSVector4::zero();

	StretchRect(sTex, sRect, dTex, dRect, m_shaderfx.ps, (const float*)&cb, 2, true);
}

void GSDevice9::InitFXAA()
{
	if (!FXAA_Compiled)
	{
		try {
			vector<unsigned char> shader;
			theApp.LoadResource(IDR_FXAA_FX, shader);
			CompileShader((const char *)shader.data(), shader.size(), "fxaa.fx", "ps_main", nullptr, &m_fxaa.ps);
		}
		catch (GSDXRecoverableError) {
			printf("GSdx: Failed to compile fxaa shader.\n");
		}
		FXAA_Compiled = true;
	}
}

void GSDevice9::DoFXAA(GSTexture* sTex, GSTexture* dTex)
{
	GSVector2i s = dTex->GetSize();

	GSVector4 sRect(0, 0, 1, 1);
	GSVector4 dRect(0, 0, s.x, s.y);

	FXAAConstantBuffer cb;

	InitFXAA();

	cb.rcpFrame = GSVector4(1.0f / s.x, 1.0f / s.y, 0.0f, 0.0f);
	cb.rcpFrameOpt = GSVector4::zero();

	StretchRect(sTex, sRect, dTex, dRect, m_fxaa.ps, (const float*)&cb, 2, true);
}

void GSDevice9::DoShadeBoost(GSTexture* sTex, GSTexture* dTex)
{
	GSVector2i s = dTex->GetSize();

	GSVector4 sRect(0, 0, 1, 1);
	GSVector4 dRect(0, 0, s.x, s.y);

	ShadeBoostConstantBuffer cb;

	cb.rcpFrame = GSVector4(1.0f / s.x, 1.0f / s.y, 0.0f, 0.0f);
	cb.rcpFrameOpt = GSVector4::zero();

	StretchRect(sTex, sRect, dTex, dRect, m_shadeboost.ps, (const float*)&cb, 1, true);
}

void GSDevice9::SetupDATE(GSTexture* rt, GSTexture* ds, const GSVertexPT1* vertices, bool datm)
{
	const GSVector2i& size = rt->GetSize();

	if(GSTexture* t = CreateRenderTarget(size.x, size.y, rt->IsMSAA()))
	{
		// sfex3 (after the capcom logo), vf4 (first menu fading in), ffxii shadows, rumble roses shadows, persona4 shadows

		BeginScene();

		ClearStencil(ds, 0);

		// om

		OMSetDepthStencilState(&m_date.dss);
		OMSetBlendState(&m_date.bs, 0);
		OMSetRenderTargets(t, ds);

		// ia

		IASetVertexBuffer(vertices, sizeof(vertices[0]), 4);
		IASetPrimitiveTopology(D3DPT_TRIANGLESTRIP);

		// vs

		VSSetShader(m_convert.vs, NULL, 0);
		IASetInputLayout(m_convert.il);

		// ps

		GSTexture* rt2 = rt->IsMSAA() ? Resolve(rt) : rt;

		PSSetShaderResources(rt2, NULL);
		PSSetShader(m_convert.ps[datm ? 2 : 3], NULL, 0);
		PSSetSamplerState(&m_convert.pt);

		//

		DrawPrimitive();

		//

		EndScene();

		Recycle(t);

		if(rt2 != rt) Recycle(rt2);
	}
}

void GSDevice9::IASetVertexBuffer(const void* vertex, size_t stride, size_t count)
{
	void* ptr = NULL;

	if(IAMapVertexBuffer(&ptr, stride, count))
	{
		GSVector4i::storent(ptr, vertex, count * stride);

		IAUnmapVertexBuffer();
	}
}

bool GSDevice9::IAMapVertexBuffer(void** vertex, size_t stride, size_t count)
{
	ASSERT(m_vertex.count == 0);

	if(count * stride > m_vertex.limit * m_vertex.stride)
	{
		m_vb_old = m_vb;
		m_vb = NULL;

		m_vertex.start = 0;
		m_vertex.count = 0;
		m_vertex.limit = std::max<int>(count * 3 / 2, 10000);
	}

	if(m_vb == NULL)
	{
		HRESULT hr;

		hr = m_dev->CreateVertexBuffer(m_vertex.limit * stride, D3DUSAGE_DYNAMIC | D3DUSAGE_WRITEONLY, 0, D3DPOOL_DEFAULT, &m_vb, NULL);

		if(FAILED(hr)) return false;
	}

	uint32 flags = D3DLOCK_NOOVERWRITE;

	if(m_vertex.start + count > m_vertex.limit || stride != m_vertex.stride)
	{
		m_vertex.start = 0;

		flags = D3DLOCK_DISCARD;
	}

	if(FAILED(m_vb->Lock(m_vertex.start * stride, count * stride, vertex, flags)))
	{
		return false;
	}

	m_vertex.count = count;
	m_vertex.stride = stride;

	return true;
}

void GSDevice9::IAUnmapVertexBuffer()
{
	m_vb->Unlock();

	IASetVertexBuffer(m_vb, m_vertex.stride);
}

void GSDevice9::IASetVertexBuffer(IDirect3DVertexBuffer9* vb, size_t stride)
{
	if(m_state.vb != vb || m_state.vb_stride != stride)
	{
		m_state.vb = vb;
		m_state.vb_stride = stride;

		m_dev->SetStreamSource(0, vb, 0, stride);
	}
}

void GSDevice9::IASetIndexBuffer(const void* index, size_t count)
{
	ASSERT(m_index.count == 0);

	if(count > m_index.limit)
	{
		m_ib_old = m_ib;
		m_ib = NULL;

		m_index.count = 0;
		m_index.limit = std::max<int>(count * 3 / 2, 11000);
	}

	if(m_ib == NULL)
	{
		HRESULT hr;

		hr = m_dev->CreateIndexBuffer(m_index.limit * sizeof(uint32), D3DUSAGE_DYNAMIC | D3DUSAGE_WRITEONLY, D3DFMT_INDEX32, D3DPOOL_DEFAULT, &m_ib, NULL);

		if(FAILED(hr)) return;
	}

	uint32 flags = D3DLOCK_NOOVERWRITE;

	if(m_index.start + count > m_index.limit)
	{
		m_index.start = 0;

		flags = D3DLOCK_DISCARD;
	}

	void* ptr = NULL;

	if(SUCCEEDED(m_ib->Lock(m_index.start * sizeof(uint32), count * sizeof(uint32), &ptr, flags)))
	{
		memcpy(ptr, index, count * sizeof(uint32));

		m_ib->Unlock();
	}

	m_index.count = count;

	IASetIndexBuffer(m_ib);
}

void GSDevice9::IASetIndexBuffer(IDirect3DIndexBuffer9* ib)
{
	if(m_state.ib != ib)
	{
		m_state.ib = ib;

		m_dev->SetIndices(ib);
	}
}

void GSDevice9::IASetInputLayout(IDirect3DVertexDeclaration9* layout)
{
	if(m_state.layout != layout)
	{
		m_state.layout = layout;

		m_dev->SetVertexDeclaration(layout);
	}
}

void GSDevice9::IASetPrimitiveTopology(D3DPRIMITIVETYPE topology)
{
	m_state.topology = topology;
}

void GSDevice9::VSSetShader(IDirect3DVertexShader9* vs, const float* vs_cb, int vs_cb_len)
{
	if(m_state.vs != vs)
	{
		m_state.vs = vs;

		m_dev->SetVertexShader(vs);
	}

	if(vs_cb && vs_cb_len > 0)
	{
		int size = vs_cb_len * sizeof(float) * 4;

		if(m_state.vs_cb_len != vs_cb_len || m_state.vs_cb == NULL || memcmp(m_state.vs_cb, vs_cb, size))
		{
			if(m_state.vs_cb == NULL || m_state.vs_cb_len < vs_cb_len)
			{
				if(m_state.vs_cb) _aligned_free(m_state.vs_cb);

				m_state.vs_cb = (float*)_aligned_malloc(size, 32);
			}

			m_state.vs_cb_len = vs_cb_len;

			memcpy(m_state.vs_cb, vs_cb, size);

			m_dev->SetVertexShaderConstantF(0, vs_cb, vs_cb_len);
		}
	}
}

void GSDevice9::PSSetShaderResources(GSTexture* sr0, GSTexture* sr1)
{
	PSSetShaderResource(0, sr0);
	PSSetShaderResource(1, sr1);
	PSSetShaderResource(2, NULL);
}

void GSDevice9::PSSetShaderResource(int i, GSTexture* sr)
{
	IDirect3DTexture9* srv = NULL;

	if(sr) srv = *(GSTexture9*)sr;

	if(m_state.ps_srvs[i] != srv)
	{
		m_state.ps_srvs[i] = srv;

		m_dev->SetTexture(i, srv);
	}
}

void GSDevice9::PSSetShader(IDirect3DPixelShader9* ps, const float* ps_cb, int ps_cb_len)
{
	if(m_state.ps != ps)
	{
		m_state.ps = ps;

		m_dev->SetPixelShader(ps);
	}

	if(ps_cb && ps_cb_len > 0)
	{
		int size = ps_cb_len * sizeof(float) * 4;

		if(m_state.ps_cb_len != ps_cb_len || m_state.ps_cb == NULL || memcmp(m_state.ps_cb, ps_cb, size))
		{
			if(m_state.ps_cb == NULL || m_state.ps_cb_len < ps_cb_len)
			{
				if(m_state.ps_cb) _aligned_free(m_state.ps_cb);

				m_state.ps_cb = (float*)_aligned_malloc(size, 32);
			}

			m_state.ps_cb_len = ps_cb_len;

			memcpy(m_state.ps_cb, ps_cb, size);

			m_dev->SetPixelShaderConstantF(0, ps_cb, ps_cb_len);
		}
	}
}

void GSDevice9::PSSetSamplerState(Direct3DSamplerState9* ss)
{
	if(ss && m_state.ps_ss != ss)
	{
		m_state.ps_ss = ss;

		m_dev->SetSamplerState(0, D3DSAMP_MINFILTER, ss->FilterMin[0]);
		m_dev->SetSamplerState(0, D3DSAMP_MAGFILTER, ss->FilterMag[0]);
		m_dev->SetSamplerState(0, D3DSAMP_MIPFILTER, ss->FilterMip[0]);
		m_dev->SetSamplerState(0, D3DSAMP_ADDRESSU, ss->AddressU);
		m_dev->SetSamplerState(0, D3DSAMP_ADDRESSV, ss->AddressV);
		m_dev->SetSamplerState(0, D3DSAMP_ADDRESSW, ss->AddressW);
		m_dev->SetSamplerState(0, D3DSAMP_MAXANISOTROPY, ss->MaxAnisotropy);
		m_dev->SetSamplerState(0, D3DSAMP_MAXMIPLEVEL, ss->MaxLOD);

		m_dev->SetSamplerState(1, D3DSAMP_MINFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(1, D3DSAMP_MAGFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(1, D3DSAMP_MIPFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(1, D3DSAMP_ADDRESSU, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(1, D3DSAMP_ADDRESSV, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(1, D3DSAMP_ADDRESSW, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(1, D3DSAMP_MAXANISOTROPY, ss->MaxAnisotropy);
		m_dev->SetSamplerState(1, D3DSAMP_MAXMIPLEVEL, ss->MaxLOD);

		m_dev->SetSamplerState(2, D3DSAMP_MINFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(2, D3DSAMP_MAGFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(2, D3DSAMP_MIPFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(2, D3DSAMP_ADDRESSU, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(2, D3DSAMP_ADDRESSV, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(2, D3DSAMP_ADDRESSW, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(2, D3DSAMP_MAXANISOTROPY, ss->MaxAnisotropy);
		m_dev->SetSamplerState(2, D3DSAMP_MAXMIPLEVEL, ss->MaxLOD);

		m_dev->SetSamplerState(3, D3DSAMP_MINFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(3, D3DSAMP_MAGFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(3, D3DSAMP_MIPFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(3, D3DSAMP_ADDRESSU, D3DTADDRESS_WRAP);
		m_dev->SetSamplerState(3, D3DSAMP_ADDRESSV, D3DTADDRESS_WRAP);
		m_dev->SetSamplerState(3, D3DSAMP_ADDRESSW, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(3, D3DSAMP_MAXANISOTROPY, ss->MaxAnisotropy);
		m_dev->SetSamplerState(3, D3DSAMP_MAXMIPLEVEL, ss->MaxLOD);

		m_dev->SetSamplerState(4, D3DSAMP_MINFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(4, D3DSAMP_MAGFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(4, D3DSAMP_MIPFILTER, ss->Anisotropic[1]);
		m_dev->SetSamplerState(4, D3DSAMP_ADDRESSU, D3DTADDRESS_WRAP);
		m_dev->SetSamplerState(4, D3DSAMP_ADDRESSV, D3DTADDRESS_WRAP);
		m_dev->SetSamplerState(4, D3DSAMP_ADDRESSW, D3DTADDRESS_CLAMP);
		m_dev->SetSamplerState(4, D3DSAMP_MAXANISOTROPY, ss->MaxAnisotropy);
		m_dev->SetSamplerState(4, D3DSAMP_MAXMIPLEVEL, ss->MaxLOD);
	}
}

void GSDevice9::OMSetDepthStencilState(Direct3DDepthStencilState9* dss)
{
	if(m_state.dss != dss)
	{
		m_state.dss = dss;

		m_dev->SetRenderState(D3DRS_ZENABLE, dss->DepthEnable);
		m_dev->SetRenderState(D3DRS_ZWRITEENABLE, dss->DepthWriteMask);

		if(dss->DepthEnable)
		{
			m_dev->SetRenderState(D3DRS_ZFUNC, dss->DepthFunc);
		}

		m_dev->SetRenderState(D3DRS_STENCILENABLE, dss->StencilEnable);

		if(dss->StencilEnable)
		{
			m_dev->SetRenderState(D3DRS_STENCILMASK, dss->StencilReadMask);
			m_dev->SetRenderState(D3DRS_STENCILWRITEMASK, dss->StencilWriteMask);
			m_dev->SetRenderState(D3DRS_STENCILFUNC, dss->StencilFunc);
			m_dev->SetRenderState(D3DRS_STENCILPASS, dss->StencilPassOp);
			m_dev->SetRenderState(D3DRS_STENCILFAIL, dss->StencilFailOp);
			m_dev->SetRenderState(D3DRS_STENCILZFAIL, dss->StencilDepthFailOp);
			m_dev->SetRenderState(D3DRS_STENCILREF, dss->StencilRef);
		}
	}
}

void GSDevice9::OMSetBlendState(Direct3DBlendState9* bs, uint32 bf)
{
	if(m_state.bs != bs || m_state.bf != bf)
	{
		m_state.bs = bs;
		m_state.bf = bf;

		m_dev->SetRenderState(D3DRS_ALPHABLENDENABLE, bs->BlendEnable);

		if(bs->BlendEnable)
		{
			m_dev->SetRenderState(D3DRS_BLENDOP, bs->BlendOp);
			m_dev->SetRenderState(D3DRS_SRCBLEND, bs->SrcBlend);
			m_dev->SetRenderState(D3DRS_DESTBLEND, bs->DestBlend);
			m_dev->SetRenderState(D3DRS_SEPARATEALPHABLENDENABLE, TRUE);
			m_dev->SetRenderState(D3DRS_BLENDOPALPHA, bs->BlendOpAlpha);
			m_dev->SetRenderState(D3DRS_SRCBLENDALPHA, bs->SrcBlendAlpha);
			m_dev->SetRenderState(D3DRS_DESTBLENDALPHA, bs->DestBlendAlpha);
			m_dev->SetRenderState(D3DRS_BLENDFACTOR, bf);
		}

		m_dev->SetRenderState(D3DRS_COLORWRITEENABLE, bs->RenderTargetWriteMask);
	}
}

void GSDevice9::OMSetRenderTargets(GSTexture* rt, GSTexture* ds, const GSVector4i* scissor)
{
	IDirect3DSurface9* rtv = NULL;
	IDirect3DSurface9* dsv = NULL;

	if(rt) rtv = *(GSTexture9*)rt;
	if(ds) dsv = *(GSTexture9*)ds;

	if(m_state.rtv != rtv)
	{
		m_state.rtv = rtv;

		m_dev->SetRenderTarget(0, rtv);
	}

	if(m_state.dsv != dsv)
	{
		m_state.dsv = dsv;

		m_dev->SetDepthStencilSurface(dsv);
	}

	GSVector4i r = scissor ? *scissor : GSVector4i(rt->GetSize()).zwxy();

	if(!m_state.scissor.eq(r))
	{
		m_state.scissor = r;

		m_dev->SetScissorRect(r);
	}
}

void GSDevice9::CompileShader(const char *source, size_t size, const char *filename, const string& entry, const D3D_SHADER_MACRO* macro, IDirect3DVertexShader9** vs, const D3DVERTEXELEMENT9* layout, int count, IDirect3DVertexDeclaration9** il)
{
	vector<D3D_SHADER_MACRO> m;

	PrepareShaderMacro(m, macro);

	HRESULT hr;

	CComPtr<ID3DBlob> shader, error;

	hr = s_pD3DCompile(source, size, nullptr, &m[0], nullptr, entry.c_str(), m_shader.vs.c_str(), 0, 0, &shader, &error);

	if(SUCCEEDED(hr))
	{
		hr = m_dev->CreateVertexShader((DWORD*)shader->GetBufferPointer(), vs);
	}
	else if(error)
	{
		printf("%s\n", (const char*)error->GetBufferPointer());
	}

	ASSERT(SUCCEEDED(hr));

	if(FAILED(hr))
	{
		throw GSDXRecoverableError();
	}

	hr = m_dev->CreateVertexDeclaration(layout, il);

	if(FAILED(hr))
	{
		throw GSDXRecoverableError();
	}
}

void GSDevice9::CompileShader(const char *source, size_t size, const char *filename, const string& entry, const D3D_SHADER_MACRO* macro, IDirect3DPixelShader9** ps)
{
	uint32 flags = 0;

	if(m_shader.level >= D3D_FEATURE_LEVEL_9_3)
	{
		flags |= D3DCOMPILE_AVOID_FLOW_CONTROL;
	}
	else
	{
		flags |= D3DCOMPILE_SKIP_VALIDATION;
	}

	vector<D3D_SHADER_MACRO> m;

	PrepareShaderMacro(m, macro);

	HRESULT hr;

	CComPtr<ID3DBlob> shader, error;
	hr = s_pD3DCompile(source, size, filename, &m[0], nullptr, entry.c_str(), m_shader.ps.c_str(), flags, 0, &shader, &error);

	if(SUCCEEDED(hr))
	{
		hr = m_dev->CreatePixelShader((DWORD*)shader->GetBufferPointer(), ps);
	}
	else if(error)
	{
		printf("%s\n", (const char*)error->GetBufferPointer());
	}

	ASSERT(SUCCEEDED(hr));

	if(FAILED(hr))
	{
		throw GSDXRecoverableError();
	}
}