Index: ps/trunk/source/renderer/Renderer.cpp
===================================================================
--- ps/trunk/source/renderer/Renderer.cpp	(revision 24755)
+++ ps/trunk/source/renderer/Renderer.cpp	(revision 24756)
@@ -1,1949 +1,1961 @@
 /* Copyright (C) 2021 Wildfire Games.
  * This file is part of 0 A.D.
  *
  * 0 A.D. 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 of the License, or
  * (at your option) any later version.
  *
  * 0 A.D. 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 0 A.D.  If not, see <http://www.gnu.org/licenses/>.
  */
 
 /*
  * higher level interface on top of OpenGL to render basic objects:
  * terrain, models, sprites, particles etc.
  */
 
 #include "precompiled.h"
 
 #include <map>
 #include <set>
 #include <algorithm>
 
 #include <boost/algorithm/string.hpp>
 
 #include "Renderer.h"
 
 #include "lib/bits.h"	// is_pow2
 #include "lib/res/graphics/ogl_tex.h"
 #include "lib/allocators/shared_ptr.h"
 #include "maths/Matrix3D.h"
 #include "maths/MathUtil.h"
 #include "ps/CLogger.h"
 #include "ps/ConfigDB.h"
 #include "ps/Game.h"
 #include "ps/Profile.h"
 #include "ps/Filesystem.h"
 #include "ps/World.h"
 #include "ps/Loader.h"
 #include "ps/ProfileViewer.h"
 #include "graphics/Camera.h"
 #include "graphics/Decal.h"
 #include "graphics/FontManager.h"
 #include "graphics/GameView.h"
 #include "graphics/LightEnv.h"
 #include "graphics/LOSTexture.h"
 #include "graphics/MaterialManager.h"
 #include "graphics/Model.h"
 #include "graphics/ModelDef.h"
 #include "graphics/ParticleManager.h"
 #include "graphics/Patch.h"
 #include "graphics/ShaderManager.h"
 #include "graphics/Terrain.h"
 #include "graphics/Texture.h"
 #include "graphics/TextureManager.h"
 #include "renderer/HWLightingModelRenderer.h"
 #include "renderer/InstancingModelRenderer.h"
 #include "renderer/ModelRenderer.h"
 #include "renderer/OverlayRenderer.h"
 #include "renderer/ParticleRenderer.h"
 #include "renderer/PostprocManager.h"
 #include "renderer/RenderingOptions.h"
 #include "renderer/RenderModifiers.h"
 #include "renderer/ShadowMap.h"
 #include "renderer/SilhouetteRenderer.h"
 #include "renderer/SkyManager.h"
 #include "renderer/TerrainOverlay.h"
 #include "renderer/TerrainRenderer.h"
 #include "renderer/TimeManager.h"
 #include "renderer/VertexBufferManager.h"
 #include "renderer/WaterManager.h"
 #include "scriptinterface/ScriptInterface.h"
 
 struct SScreenRect
 {
 	GLint x1, y1, x2, y2;
 };
 
 ///////////////////////////////////////////////////////////////////////////////////
 // CRendererStatsTable - Profile display of rendering stats
 
 /**
  * Class CRendererStatsTable: Implementation of AbstractProfileTable to
  * display the renderer stats in-game.
  *
  * Accesses CRenderer::m_Stats by keeping the reference passed to the
  * constructor.
  */
 class CRendererStatsTable : public AbstractProfileTable
 {
 	NONCOPYABLE(CRendererStatsTable);
 public:
 	CRendererStatsTable(const CRenderer::Stats& st);
 
 	// Implementation of AbstractProfileTable interface
 	CStr GetName();
 	CStr GetTitle();
 	size_t GetNumberRows();
 	const std::vector<ProfileColumn>& GetColumns();
 	CStr GetCellText(size_t row, size_t col);
 	AbstractProfileTable* GetChild(size_t row);
 
 private:
 	/// Reference to the renderer singleton's stats
 	const CRenderer::Stats& Stats;
 
 	/// Column descriptions
 	std::vector<ProfileColumn> columnDescriptions;
 
 	enum {
 		Row_DrawCalls = 0,
 		Row_TerrainTris,
 		Row_WaterTris,
 		Row_ModelTris,
 		Row_OverlayTris,
 		Row_BlendSplats,
 		Row_Particles,
 		Row_VBReserved,
 		Row_VBAllocated,
 		Row_TextureMemory,
 		Row_ShadersLoaded,
 
 		// Must be last to count number of rows
 		NumberRows
 	};
 };
 
 // Construction
 CRendererStatsTable::CRendererStatsTable(const CRenderer::Stats& st)
 	: Stats(st)
 {
 	columnDescriptions.push_back(ProfileColumn("Name", 230));
 	columnDescriptions.push_back(ProfileColumn("Value", 100));
 }
 
 // Implementation of AbstractProfileTable interface
 CStr CRendererStatsTable::GetName()
 {
 	return "renderer";
 }
 
 CStr CRendererStatsTable::GetTitle()
 {
 	return "Renderer statistics";
 }
 
 size_t CRendererStatsTable::GetNumberRows()
 {
 	return NumberRows;
 }
 
 const std::vector<ProfileColumn>& CRendererStatsTable::GetColumns()
 {
 	return columnDescriptions;
 }
 
 CStr CRendererStatsTable::GetCellText(size_t row, size_t col)
 {
 	char buf[256];
 
 	switch(row)
 	{
 	case Row_DrawCalls:
 		if (col == 0)
 			return "# draw calls";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_DrawCalls);
 		return buf;
 
 	case Row_TerrainTris:
 		if (col == 0)
 			return "# terrain tris";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_TerrainTris);
 		return buf;
 
 	case Row_WaterTris:
 		if (col == 0)
 			return "# water tris";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_WaterTris);
 		return buf;
 
 	case Row_ModelTris:
 		if (col == 0)
 			return "# model tris";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_ModelTris);
 		return buf;
 
 	case Row_OverlayTris:
 		if (col == 0)
 			return "# overlay tris";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_OverlayTris);
 		return buf;
 
 	case Row_BlendSplats:
 		if (col == 0)
 			return "# blend splats";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_BlendSplats);
 		return buf;
 
 	case Row_Particles:
 		if (col == 0)
 			return "# particles";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)Stats.m_Particles);
 		return buf;
 
 	case Row_VBReserved:
 		if (col == 0)
 			return "VB reserved";
 		sprintf_s(buf, sizeof(buf), "%lu kB", (unsigned long)g_VBMan.GetBytesReserved() / 1024);
 		return buf;
 
 	case Row_VBAllocated:
 		if (col == 0)
 			return "VB allocated";
 		sprintf_s(buf, sizeof(buf), "%lu kB", (unsigned long)g_VBMan.GetBytesAllocated() / 1024);
 		return buf;
 
 	case Row_TextureMemory:
 		if (col == 0)
 			return "textures uploaded";
 		sprintf_s(buf, sizeof(buf), "%lu kB", (unsigned long)g_Renderer.GetTextureManager().GetBytesUploaded() / 1024);
 		return buf;
 
 	case Row_ShadersLoaded:
 		if (col == 0)
 			return "shader effects loaded";
 		sprintf_s(buf, sizeof(buf), "%lu", (unsigned long)g_Renderer.GetShaderManager().GetNumEffectsLoaded());
 		return buf;
 
 	default:
 		return "???";
 	}
 }
 
 AbstractProfileTable* CRendererStatsTable::GetChild(size_t UNUSED(row))
 {
 	return 0;
 }
 
 
 ///////////////////////////////////////////////////////////////////////////////////
 // CRenderer implementation
 
 /**
  * Struct CRendererInternals: Truly hide data that is supposed to be hidden
  * in this structure so it won't even appear in header files.
  */
 struct CRendererInternals
 {
 	NONCOPYABLE(CRendererInternals);
 public:
 	/// true if CRenderer::Open has been called
 	bool IsOpen;
 
 	/// true if shaders need to be reloaded
 	bool ShadersDirty;
 
 	/// Table to display renderer stats in-game via profile system
 	CRendererStatsTable profileTable;
 
 	/// Shader manager
 	CShaderManager shaderManager;
 
 	/// Water manager
 	WaterManager waterManager;
 
 	/// Sky manager
 	SkyManager skyManager;
 
 	/// Texture manager
 	CTextureManager textureManager;
 
 	/// Terrain renderer
 	TerrainRenderer terrainRenderer;
 
 	/// Overlay renderer
 	OverlayRenderer overlayRenderer;
 
 	/// Particle manager
 	CParticleManager particleManager;
 
 	/// Particle renderer
 	ParticleRenderer particleRenderer;
 
 	/// Material manager
 	CMaterialManager materialManager;
 
 	/// Time manager
 	CTimeManager timeManager;
 
 	/// Shadow map
 	ShadowMap shadow;
 
 	/// Postprocessing effect manager
 	CPostprocManager postprocManager;
 
 	CFontManager fontManager;
 
 	SilhouetteRenderer silhouetteRenderer;
 
 	/// Various model renderers
 	struct Models
 	{
 		// NOTE: The current renderer design (with ModelRenderer, ModelVertexRenderer,
 		// RenderModifier, etc) is mostly a relic of an older design that implemented
 		// the different materials and rendering modes through extensive subclassing
 		// and hooking objects together in various combinations.
 		// The new design uses the CShaderManager API to abstract away the details
 		// of rendering, and uses a data-driven approach to materials, so there are
 		// now a small number of generic subclasses instead of many specialised subclasses,
 		// but most of the old infrastructure hasn't been refactored out yet and leads to
 		// some unwanted complexity.
 
 		// Submitted models are split on two axes:
 		//  - Normal vs Transp[arent] - alpha-blended models are stored in a separate
 		//    list so we can draw them above/below the alpha-blended water plane correctly
 		//  - Skinned vs Unskinned - with hardware lighting we don't need to
 		//    duplicate mesh data per model instance (except for skinned models),
 		//    so non-skinned models get different ModelVertexRenderers
 
 		ModelRendererPtr NormalSkinned;
 		ModelRendererPtr NormalUnskinned; // == NormalSkinned if unskinned shader instancing not supported
 		ModelRendererPtr TranspSkinned;
 		ModelRendererPtr TranspUnskinned; // == TranspSkinned if unskinned shader instancing not supported
 
 		ModelVertexRendererPtr VertexRendererShader;
 		ModelVertexRendererPtr VertexInstancingShader;
 		ModelVertexRendererPtr VertexGPUSkinningShader;
 
 		LitRenderModifierPtr ModShader;
 	} Model;
 
 	CShaderDefines globalContext;
 
 	CRendererInternals() :
 		IsOpen(false), ShadersDirty(true), profileTable(g_Renderer.m_Stats), textureManager(g_VFS, false, false)
 	{
 	}
 
 	/**
 	 * Load the OpenGL projection and modelview matrices and the viewport according
 	 * to the given camera.
 	 */
 	void SetOpenGLCamera(const CCamera& camera)
 	{
 		CMatrix3D view;
 		camera.GetOrientation().GetInverse(view);
 		const CMatrix3D& proj = camera.GetProjection();
 
 #if CONFIG2_GLES
 #warning TODO: fix CRenderer camera handling for GLES (do not use global matrixes)
 #else
 		glMatrixMode(GL_PROJECTION);
 		glLoadMatrixf(&proj._11);
 
 		glMatrixMode(GL_MODELVIEW);
 		glLoadMatrixf(&view._11);
 #endif
 
 		g_Renderer.SetViewport(camera.GetViewPort());
 	}
 
 	/**
 	 * Renders all non-alpha-blended models with the given context.
 	 */
 	void CallModelRenderers(const CShaderDefines& context, int cullGroup, int flags)
 	{
 		CShaderDefines contextSkinned = context;
 		if (g_RenderingOptions.GetGPUSkinning())
 		{
 			contextSkinned.Add(str_USE_INSTANCING, str_1);
 			contextSkinned.Add(str_USE_GPU_SKINNING, str_1);
 		}
 		Model.NormalSkinned->Render(Model.ModShader, contextSkinned, cullGroup, flags);
 
 		if (Model.NormalUnskinned != Model.NormalSkinned)
 		{
 			CShaderDefines contextUnskinned = context;
 			contextUnskinned.Add(str_USE_INSTANCING, str_1);
 			Model.NormalUnskinned->Render(Model.ModShader, contextUnskinned, cullGroup, flags);
 		}
 	}
 
 	/**
 	 * Renders all alpha-blended models with the given context.
 	 */
 	void CallTranspModelRenderers(const CShaderDefines& context, int cullGroup, int flags)
 	{
 		CShaderDefines contextSkinned = context;
 		if (g_RenderingOptions.GetGPUSkinning())
 		{
 			contextSkinned.Add(str_USE_INSTANCING, str_1);
 			contextSkinned.Add(str_USE_GPU_SKINNING, str_1);
 		}
 		Model.TranspSkinned->Render(Model.ModShader, contextSkinned, cullGroup, flags);
 
 		if (Model.TranspUnskinned != Model.TranspSkinned)
 		{
 			CShaderDefines contextUnskinned = context;
 			contextUnskinned.Add(str_USE_INSTANCING, str_1);
 			Model.TranspUnskinned->Render(Model.ModShader, contextUnskinned, cullGroup, flags);
 		}
 	}
 };
 
 ///////////////////////////////////////////////////////////////////////////////////
 // CRenderer constructor
 CRenderer::CRenderer()
 {
 	m = new CRendererInternals;
 	m_WaterManager = &m->waterManager;
 	m_SkyManager = &m->skyManager;
 
 	g_ProfileViewer.AddRootTable(&m->profileTable);
 
 	m_Width = 0;
 	m_Height = 0;
 	m_TerrainRenderMode = SOLID;
 	m_WaterRenderMode = SOLID;
 	m_ModelRenderMode = SOLID;
 	m_OverlayRenderMode = SOLID;
 	m_ClearColor[0] = m_ClearColor[1] = m_ClearColor[2] = m_ClearColor[3] = 0;
 
 	m_DisplayTerrainPriorities = false;
 	m_SkipSubmit = false;
 
 	CStr skystring = "0 0 0";
 	CColor skycolor;
 	CFG_GET_VAL("skycolor", skystring);
 	if (skycolor.ParseString(skystring, 255.f))
 		SetClearColor(skycolor.AsSColor4ub());
 
 	m_ShadowZBias = 0.02f;
 	m_ShadowMapSize = 0;
 
 	m_LightEnv = NULL;
 
 	m_CurrentScene = NULL;
 
 	m_hCompositeAlphaMap = 0;
 
 	m_Stats.Reset();
 
 	RegisterFileReloadFunc(ReloadChangedFileCB, this);
 }
 
 ///////////////////////////////////////////////////////////////////////////////////
 // CRenderer destructor
 CRenderer::~CRenderer()
 {
 	UnregisterFileReloadFunc(ReloadChangedFileCB, this);
 
 	// we no longer UnloadAlphaMaps / UnloadWaterTextures here -
 	// that is the responsibility of the module that asked for
 	// them to be loaded (i.e. CGameView).
 	delete m;
 }
 
 
 ///////////////////////////////////////////////////////////////////////////////////
 // EnumCaps: build card cap bits
 void CRenderer::EnumCaps()
 {
 	// assume support for nothing
 	m_Caps.m_VBO = false;
 	m_Caps.m_ARBProgram = false;
 	m_Caps.m_ARBProgramShadow = false;
 	m_Caps.m_VertexShader = false;
 	m_Caps.m_FragmentShader = false;
 	m_Caps.m_Shadows = false;
 	m_Caps.m_PrettyWater = false;
 
 	// now start querying extensions
 	if (!g_RenderingOptions.GetNoVBO() && ogl_HaveExtension("GL_ARB_vertex_buffer_object"))
 		m_Caps.m_VBO = true;
 
 	if (0 == ogl_HaveExtensions(0, "GL_ARB_vertex_program", "GL_ARB_fragment_program", NULL))
 	{
 		m_Caps.m_ARBProgram = true;
 		if (ogl_HaveExtension("GL_ARB_fragment_program_shadow"))
 			m_Caps.m_ARBProgramShadow = true;
 	}
 
 	if (0 == ogl_HaveExtensions(0, "GL_ARB_shader_objects", "GL_ARB_shading_language_100", NULL))
 	{
 		if (ogl_HaveExtension("GL_ARB_vertex_shader"))
 			m_Caps.m_VertexShader = true;
 		if (ogl_HaveExtension("GL_ARB_fragment_shader"))
 			m_Caps.m_FragmentShader = true;
 	}
 
 #if CONFIG2_GLES
 	m_Caps.m_Shadows = true;
 #else
 	if (0 == ogl_HaveExtensions(0, "GL_ARB_shadow", "GL_ARB_depth_texture", "GL_EXT_framebuffer_object", NULL))
 	{
 		if (ogl_max_tex_units >= 4)
 			m_Caps.m_Shadows = true;
 	}
 #endif
 
 #if CONFIG2_GLES
 	m_Caps.m_PrettyWater = true;
 #else
 	if (0 == ogl_HaveExtensions(0, "GL_ARB_vertex_shader", "GL_ARB_fragment_shader", "GL_EXT_framebuffer_object", NULL))
 		m_Caps.m_PrettyWater = true;
 #endif
 }
 
 void CRenderer::RecomputeSystemShaderDefines()
 {
 	CShaderDefines defines;
 
 	if (m_Caps.m_ARBProgram)
 		defines.Add(str_SYS_HAS_ARB, str_1);
 
 	if (m_Caps.m_VertexShader && m_Caps.m_FragmentShader)
 		defines.Add(str_SYS_HAS_GLSL, str_1);
 
 	if (g_RenderingOptions.GetPreferGLSL())
 		defines.Add(str_SYS_PREFER_GLSL, str_1);
 
 	m_SystemShaderDefines = defines;
 }
 
 void CRenderer::ReloadShaders()
 {
 	ENSURE(m->IsOpen);
 
 	m->globalContext = m_SystemShaderDefines;
 
 	if (m_Caps.m_Shadows && g_RenderingOptions.GetShadows())
 	{
 		m->globalContext.Add(str_USE_SHADOW, str_1);
 		if (m_Caps.m_ARBProgramShadow && g_RenderingOptions.GetARBProgramShadow())
 			m->globalContext.Add(str_USE_FP_SHADOW, str_1);
 		if (g_RenderingOptions.GetShadowPCF())
 			m->globalContext.Add(str_USE_SHADOW_PCF, str_1);
 #if !CONFIG2_GLES
 		m->globalContext.Add(str_USE_SHADOW_SAMPLER, str_1);
 #endif
 	}
 
 	if (g_RenderingOptions.GetPreferGLSL() && g_RenderingOptions.GetFog())
 		m->globalContext.Add(str_USE_FOG, str_1);
 
 	m->Model.ModShader = LitRenderModifierPtr(new ShaderRenderModifier());
 
 	ENSURE(g_RenderingOptions.GetRenderPath() != RenderPath::FIXED);
 	m->Model.VertexRendererShader = ModelVertexRendererPtr(new ShaderModelVertexRenderer());
 	m->Model.VertexInstancingShader = ModelVertexRendererPtr(new InstancingModelRenderer(false, g_RenderingOptions.GetPreferGLSL()));
 
 	if (g_RenderingOptions.GetGPUSkinning()) // TODO: should check caps and GLSL etc too
 	{
 		m->Model.VertexGPUSkinningShader = ModelVertexRendererPtr(new InstancingModelRenderer(true, g_RenderingOptions.GetPreferGLSL()));
 		m->Model.NormalSkinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexGPUSkinningShader));
 		m->Model.TranspSkinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexGPUSkinningShader));
 	}
 	else
 	{
 		m->Model.VertexGPUSkinningShader.reset();
 		m->Model.NormalSkinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexRendererShader));
 		m->Model.TranspSkinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexRendererShader));
 	}
 
 	m->Model.NormalUnskinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexInstancingShader));
 	m->Model.TranspUnskinned = ModelRendererPtr(new ShaderModelRenderer(m->Model.VertexInstancingShader));
 
 	m->ShadersDirty = false;
 }
 
 bool CRenderer::Open(int width, int height)
 {
 	m->IsOpen = true;
 
 	// Must query card capabilities before creating renderers that depend
 	// on card capabilities.
 	EnumCaps();
 
 	// Dimensions
 	m_Width = width;
 	m_Height = height;
 
 	// set packing parameters
 	glPixelStorei(GL_PACK_ALIGNMENT,1);
 	glPixelStorei(GL_UNPACK_ALIGNMENT,1);
 
 	// setup default state
 	glDepthFunc(GL_LEQUAL);
 	glEnable(GL_DEPTH_TEST);
 	glCullFace(GL_BACK);
 	glFrontFace(GL_CCW);
 	glEnable(GL_CULL_FACE);
 
 	GLint bits;
 	glGetIntegerv(GL_DEPTH_BITS,&bits);
 	LOGMESSAGE("CRenderer::Open: depth bits %d",bits);
 	glGetIntegerv(GL_STENCIL_BITS,&bits);
 	LOGMESSAGE("CRenderer::Open: stencil bits %d",bits);
 	glGetIntegerv(GL_ALPHA_BITS,&bits);
 	LOGMESSAGE("CRenderer::Open: alpha bits %d",bits);
 
 	// Validate the currently selected render path
 	SetRenderPath(g_RenderingOptions.GetRenderPath());
 
 	RecomputeSystemShaderDefines();
 
 	// Let component renderers perform one-time initialization after graphics capabilities and
 	// the shader path have been determined.
 	m->overlayRenderer.Initialize();
 
 	if (g_RenderingOptions.GetPostProc())
 		m->postprocManager.Initialize();
 
 	return true;
 }
 
 // resize renderer view
 void CRenderer::Resize(int width, int height)
 {
 	// need to recreate the shadow map object to resize the shadow texture
 	m->shadow.RecreateTexture();
 
 	m_Width = width;
 	m_Height = height;
 
 	m->postprocManager.Resize();
 
 	m_WaterManager->Resize();
 }
 
 //////////////////////////////////////////////////////////////////////////////////////////
 // SetRenderPath: Select the preferred render path.
 // This may only be called before Open(), because the layout of vertex arrays and other
 // data may depend on the chosen render path.
 void CRenderer::SetRenderPath(RenderPath rp)
 {
 	if (!m->IsOpen)
 	{
 		// Delay until Open() is called.
 		return;
 	}
 
 	// Renderer has been opened, so validate the selected renderpath
 	if (rp == RenderPath::DEFAULT)
 	{
 		if (m_Caps.m_ARBProgram || (m_Caps.m_VertexShader && m_Caps.m_FragmentShader && g_RenderingOptions.GetPreferGLSL()))
 			rp = RenderPath::SHADER;
 		else
 			rp = RenderPath::FIXED;
 	}
 
 	if (rp == RenderPath::SHADER)
 	{
 		if (!(m_Caps.m_ARBProgram || (m_Caps.m_VertexShader && m_Caps.m_FragmentShader && g_RenderingOptions.GetPreferGLSL())))
 		{
 			LOGWARNING("Falling back to fixed function\n");
 			rp = RenderPath::FIXED;
 		}
 	}
 
 	// TODO: remove this once capabilities have been properly extracted and the above checks have been moved elsewhere.
 	g_RenderingOptions.m_RenderPath = rp;
 
 	MakeShadersDirty();
 	RecomputeSystemShaderDefines();
 
 	// We might need to regenerate some render data after changing path
 	if (g_Game)
 		g_Game->GetWorld()->GetTerrain()->MakeDirty(RENDERDATA_UPDATE_COLOR);
 }
 
 //////////////////////////////////////////////////////////////////////////////////////////
 // BeginFrame: signal frame start
 void CRenderer::BeginFrame()
 {
 	PROFILE("begin frame");
 
 	// zero out all the per-frame stats
 	m_Stats.Reset();
 
 	// choose model renderers for this frame
 
 	if (m->ShadersDirty)
 		ReloadShaders();
 
 	m->Model.ModShader->SetShadowMap(&m->shadow);
 	m->Model.ModShader->SetLightEnv(m_LightEnv);
 }
 
 //////////////////////////////////////////////////////////////////////////////////////////
 void CRenderer::SetSimulation(CSimulation2* simulation)
 {
 	// set current simulation context for terrain renderer
 	m->terrainRenderer.SetSimulation(simulation);
 }
 
 // SetClearColor: set color used to clear screen in BeginFrame()
 void CRenderer::SetClearColor(SColor4ub color)
 {
 	m_ClearColor[0] = float(color.R) / 255.0f;
 	m_ClearColor[1] = float(color.G) / 255.0f;
 	m_ClearColor[2] = float(color.B) / 255.0f;
 	m_ClearColor[3] = float(color.A) / 255.0f;
 }
 
 void CRenderer::RenderShadowMap(const CShaderDefines& context)
 {
 	PROFILE3_GPU("shadow map");
 
 	m->shadow.BeginRender();
 
 	{
 		PROFILE("render patches");
 		glCullFace(GL_FRONT);
 		glEnable(GL_CULL_FACE);
 		m->terrainRenderer.RenderPatches(CULL_SHADOWS);
 		glCullFace(GL_BACK);
 	}
 
 	CShaderDefines contextCast = context;
 	contextCast.Add(str_MODE_SHADOWCAST, str_1);
 
 	{
 		PROFILE("render models");
 		m->CallModelRenderers(contextCast, CULL_SHADOWS, MODELFLAG_CASTSHADOWS);
 	}
 
 	{
 		PROFILE("render transparent models");
 		// disable face-culling for two-sided models
 		glDisable(GL_CULL_FACE);
 		m->CallTranspModelRenderers(contextCast, CULL_SHADOWS, MODELFLAG_CASTSHADOWS);
 		glEnable(GL_CULL_FACE);
 	}
 
 	m->shadow.EndRender();
 
 	m->SetOpenGLCamera(m_ViewCamera);
 }
 
 void CRenderer::RenderPatches(const CShaderDefines& context, int cullGroup)
 {
 	PROFILE3_GPU("patches");
 
 #if CONFIG2_GLES
 #warning TODO: implement wireface/edged rendering mode GLES
 #else
 	// switch on wireframe if we need it
 	if (m_TerrainRenderMode == WIREFRAME)
 	{
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 	}
 #endif
 
 	// render all the patches, including blend pass
 	ENSURE(g_RenderingOptions.GetRenderPath() != RenderPath::FIXED);
 	m->terrainRenderer.RenderTerrainShader(context, cullGroup, (m_Caps.m_Shadows && g_RenderingOptions.GetShadows()) ? &m->shadow : 0);
 
 #if !CONFIG2_GLES
 	if (m_TerrainRenderMode == WIREFRAME)
 	{
 		// switch wireframe off again
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 	else if (m_TerrainRenderMode == EDGED_FACES)
 	{
 		// edged faces: need to make a second pass over the data:
 		// first switch on wireframe
 		glPolygonMode(GL_FRONT_AND_BACK,GL_LINE);
 
 		// setup some renderstate ..
 		pglActiveTextureARB(GL_TEXTURE0);
 		glDisable(GL_TEXTURE_2D);
 		glLineWidth(2.0f);
 
 		// render tiles edges
 		m->terrainRenderer.RenderPatches(cullGroup, CColor(0.5f, 0.5f, 1.0f, 1.0f));
 
 		// set color for outline
 		glColor3f(0, 0, 1);
 		glLineWidth(4.0f);
 
 		// render outline of each patch
 		m->terrainRenderer.RenderOutlines(cullGroup);
 
 		// .. and restore the renderstates
 		glLineWidth(1.0f);
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 #endif
 }
 
 void CRenderer::RenderModels(const CShaderDefines& context, int cullGroup)
 {
 	PROFILE3_GPU("models");
 
 	int flags = 0;
 
 #if !CONFIG2_GLES
 	if (m_ModelRenderMode == WIREFRAME)
 	{
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 	}
 #endif
 
 	m->CallModelRenderers(context, cullGroup, flags);
 
 #if !CONFIG2_GLES
 	if (m_ModelRenderMode == WIREFRAME)
 	{
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 	else if (m_ModelRenderMode == EDGED_FACES)
 	{
 		CShaderDefines contextWireframe = context;
 		contextWireframe.Add(str_MODE_WIREFRAME, str_1);
 
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 		glDisable(GL_TEXTURE_2D);
 
 		m->CallModelRenderers(contextWireframe, cullGroup, flags);
 
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 #endif
 }
 
 void CRenderer::RenderTransparentModels(const CShaderDefines& context, int cullGroup, ETransparentMode transparentMode, bool disableFaceCulling)
 {
 	PROFILE3_GPU("transparent models");
 
 	int flags = 0;
 
 #if !CONFIG2_GLES
 	// switch on wireframe if we need it
 	if (m_ModelRenderMode == WIREFRAME)
 	{
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 	}
 #endif
 
 	// disable face culling for two-sided models in sub-renders
 	if (disableFaceCulling)
 		glDisable(GL_CULL_FACE);
 
 	CShaderDefines contextOpaque = context;
 	contextOpaque.Add(str_ALPHABLEND_PASS_OPAQUE, str_1);
 
 	CShaderDefines contextBlend = context;
 	contextBlend.Add(str_ALPHABLEND_PASS_BLEND, str_1);
 
 	if (transparentMode == TRANSPARENT || transparentMode == TRANSPARENT_OPAQUE)
 		m->CallTranspModelRenderers(contextOpaque, cullGroup, flags);
 
 	if (transparentMode == TRANSPARENT || transparentMode == TRANSPARENT_BLEND)
 		m->CallTranspModelRenderers(contextBlend, cullGroup, flags);
 
 	if (disableFaceCulling)
 		glEnable(GL_CULL_FACE);
 
 #if !CONFIG2_GLES
 	if (m_ModelRenderMode == WIREFRAME)
 	{
 		// switch wireframe off again
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 	else if (m_ModelRenderMode == EDGED_FACES)
 	{
 		CShaderDefines contextWireframe = contextOpaque;
 		contextWireframe.Add(str_MODE_WIREFRAME, str_1);
 
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 		glDisable(GL_TEXTURE_2D);
 
 		m->CallTranspModelRenderers(contextWireframe, cullGroup, flags);
 
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 #endif
 }
 
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // SetObliqueFrustumClipping: change the near plane to the given clip plane (in world space)
 // Based on code from Game Programming Gems 5, from http://www.terathon.com/code/oblique.html
 // - worldPlane is a clip plane in world space (worldPlane.Dot(v) >= 0 for any vector v passing the clipping test)
 void CRenderer::SetObliqueFrustumClipping(CCamera& camera, const CVector4D& worldPlane) const
 {
 	// First, we'll convert the given clip plane to camera space, then we'll
 	// Get the view matrix and normal matrix (top 3x3 part of view matrix)
 	CMatrix3D normalMatrix = camera.GetOrientation().GetTranspose();
 	CVector4D camPlane = normalMatrix.Transform(worldPlane);
 
 	CMatrix3D matrix = camera.GetProjection();
 
 	// Calculate the clip-space corner point opposite the clipping plane
 	// as (sgn(camPlane.x), sgn(camPlane.y), 1, 1) and
 	// transform it into camera space by multiplying it
 	// by the inverse of the projection matrix
 
 	CVector4D q;
 	q.X = (sgn(camPlane.X) - matrix[8]/matrix[11]) / matrix[0];
 	q.Y = (sgn(camPlane.Y) - matrix[9]/matrix[11]) / matrix[5];
 	q.Z = 1.0f/matrix[11];
 	q.W = (1.0f - matrix[10]/matrix[11]) / matrix[14];
 
 	// Calculate the scaled plane vector
 	CVector4D c = camPlane * (2.0f * matrix[11] / camPlane.Dot(q));
 
 	// Replace the third row of the projection matrix
 	matrix[2] = c.X;
 	matrix[6] = c.Y;
 	matrix[10] = c.Z - matrix[11];
 	matrix[14] = c.W;
 
 	// Load it back into the camera
 	camera.SetProjection(matrix);
 }
 
 void CRenderer::ComputeReflectionCamera(CCamera& camera, const CBoundingBoxAligned& scissor) const
 {
 	WaterManager& wm = m->waterManager;
 
 	ENSURE(m_ViewCamera.GetProjectionType() == CCamera::PERSPECTIVE);
 	float fov = m_ViewCamera.GetFOV();
 
 	// Expand fov slightly since ripples can reflect parts of the scene that
 	// are slightly outside the normal camera view, and we want to avoid any
 	// noticeable edge-filtering artifacts
 	fov *= 1.05f;
 
 	camera = m_ViewCamera;
 
 	// Temporarily change the camera to one that is reflected.
 	// Also, for texturing purposes, make it render to a view port the size of the
 	// water texture, stretch the image according to our aspect ratio so it covers
 	// the whole screen despite being rendered into a square, and cover slightly more
 	// of the view so we can see wavy reflections of slightly off-screen objects.
 	camera.m_Orientation.Scale(1, -1, 1);
 	camera.m_Orientation.Translate(0, 2*wm.m_WaterHeight, 0);
 	camera.UpdateFrustum(scissor);
 	// Clip slightly above the water to improve reflections of objects on the water
 	// when the reflections are distorted.
 	camera.ClipFrustum(CVector4D(0, 1, 0, -wm.m_WaterHeight + 2.0f));
 
 	SViewPort vp;
 	vp.m_Height = wm.m_RefTextureSize;
 	vp.m_Width = wm.m_RefTextureSize;
 	vp.m_X = 0;
 	vp.m_Y = 0;
 	camera.SetViewPort(vp);
 	camera.SetPerspectiveProjection(m_ViewCamera.GetNearPlane(), m_ViewCamera.GetFarPlane(), fov);
 	CMatrix3D scaleMat;
 	scaleMat.SetScaling(m_Height/float(std::max(1, m_Width)), 1.0f, 1.0f);
 	camera.SetProjection(scaleMat * camera.GetProjection());
 
 	CVector4D camPlane(0, 1, 0, -wm.m_WaterHeight + 0.5f);
 	SetObliqueFrustumClipping(camera, camPlane);
 
 }
 
 void CRenderer::ComputeRefractionCamera(CCamera& camera, const CBoundingBoxAligned& scissor) const
 {
 	WaterManager& wm = m->waterManager;
 
 	ENSURE(m_ViewCamera.GetProjectionType() == CCamera::PERSPECTIVE);
 	float fov = m_ViewCamera.GetFOV();
 
 	// Expand fov slightly since ripples can reflect parts of the scene that
 	// are slightly outside the normal camera view, and we want to avoid any
 	// noticeable edge-filtering artifacts
 	fov *= 1.05f;
 
 	camera = m_ViewCamera;
 
 	// Temporarily change the camera to make it render to a view port the size of the
 	// water texture, stretch the image according to our aspect ratio so it covers
 	// the whole screen despite being rendered into a square, and cover slightly more
 	// of the view so we can see wavy refractions of slightly off-screen objects.
 	camera.UpdateFrustum(scissor);
 	camera.ClipFrustum(CVector4D(0, -1, 0, wm.m_WaterHeight + 0.5f));	// add some to avoid artifacts near steep shores.
 
 	SViewPort vp;
 	vp.m_Height = wm.m_RefTextureSize;
 	vp.m_Width = wm.m_RefTextureSize;
 	vp.m_X = 0;
 	vp.m_Y = 0;
 	camera.SetViewPort(vp);
 	camera.SetPerspectiveProjection(m_ViewCamera.GetNearPlane(), m_ViewCamera.GetFarPlane(), fov);
 	CMatrix3D scaleMat;
 	scaleMat.SetScaling(m_Height/float(std::max(1, m_Width)), 1.0f, 1.0f);
 	camera.SetProjection(scaleMat * camera.GetProjection());
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // RenderReflections: render the water reflections to the reflection texture
 void CRenderer::RenderReflections(const CShaderDefines& context, const CBoundingBoxAligned& scissor)
 {
 	PROFILE3_GPU("water reflections");
 
 	WaterManager& wm = m->waterManager;
 
 	// Remember old camera
 	CCamera normalCamera = m_ViewCamera;
 
 	ComputeReflectionCamera(m_ViewCamera, scissor);
 
 	m->SetOpenGLCamera(m_ViewCamera);
 
 	// Save the model-view-projection matrix so the shaders can use it for projective texturing
 	wm.m_ReflectionMatrix = m_ViewCamera.GetViewProjection();
 
 	float vpHeight = wm.m_RefTextureSize;
 	float vpWidth = wm.m_RefTextureSize;
 
 	SScreenRect screenScissor;
 	screenScissor.x1 = (GLint)floor((scissor[0].X*0.5f+0.5f)*vpWidth);
 	screenScissor.y1 = (GLint)floor((scissor[0].Y*0.5f+0.5f)*vpHeight);
 	screenScissor.x2 = (GLint)ceil((scissor[1].X*0.5f+0.5f)*vpWidth);
 	screenScissor.y2 = (GLint)ceil((scissor[1].Y*0.5f+0.5f)*vpHeight);
 
 	glEnable(GL_SCISSOR_TEST);
 	glScissor(screenScissor.x1, screenScissor.y1, screenScissor.x2 - screenScissor.x1, screenScissor.y2 - screenScissor.y1);
 
 	// try binding the framebuffer
 	pglBindFramebufferEXT(GL_FRAMEBUFFER_EXT, wm.m_ReflectionFbo);
 
 	glClearColor(0.5f,0.5f,1.0f,0.0f);
 	glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
 
 	glFrontFace(GL_CW);
 
 	if (!g_RenderingOptions.GetWaterReflection())
 	{
 		m->skyManager.RenderSky();
 		ogl_WarnIfError();
 	}
 	else
 	{
 		// Render terrain and models
 		RenderPatches(context, CULL_REFLECTIONS);
 		ogl_WarnIfError();
 		RenderModels(context, CULL_REFLECTIONS);
 		ogl_WarnIfError();
 		RenderTransparentModels(context, CULL_REFLECTIONS, TRANSPARENT, true);
 		ogl_WarnIfError();
 	}
 	glFrontFace(GL_CCW);
 
 	// Particles are always oriented to face the camera in the vertex shader,
 	// so they don't need the inverted glFrontFace
 	if (g_RenderingOptions.GetParticles())
 	{
 		RenderParticles(CULL_REFLECTIONS);
 		ogl_WarnIfError();
 	}
 
 	glDisable(GL_SCISSOR_TEST);
 
   	// Reset old camera
   	m_ViewCamera = normalCamera;
   	m->SetOpenGLCamera(m_ViewCamera);
 
 	pglBindFramebufferEXT(GL_FRAMEBUFFER_EXT, 0);
 }
 
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // RenderRefractions: render the water refractions to the refraction texture
 void CRenderer::RenderRefractions(const CShaderDefines& context, const CBoundingBoxAligned &scissor)
 {
 	PROFILE3_GPU("water refractions");
 
 	WaterManager& wm = m->waterManager;
 
 	// Remember old camera
 	CCamera normalCamera = m_ViewCamera;
 
 	ComputeRefractionCamera(m_ViewCamera, scissor);
 
 	CVector4D camPlane(0, -1, 0, wm.m_WaterHeight + 2.0f);
 	SetObliqueFrustumClipping(m_ViewCamera, camPlane);
 
 	m->SetOpenGLCamera(m_ViewCamera);
 
 	// Save the model-view-projection matrix so the shaders can use it for projective texturing
 	wm.m_RefractionMatrix = m_ViewCamera.GetViewProjection();
 	wm.m_RefractionProjInvMatrix = m_ViewCamera.GetProjection().GetInverse();
 	wm.m_RefractionViewInvMatrix = m_ViewCamera.GetOrientation();
 
 	float vpHeight = wm.m_RefTextureSize;
 	float vpWidth = wm.m_RefTextureSize;
 
 	SScreenRect screenScissor;
 	screenScissor.x1 = (GLint)floor((scissor[0].X*0.5f+0.5f)*vpWidth);
 	screenScissor.y1 = (GLint)floor((scissor[0].Y*0.5f+0.5f)*vpHeight);
 	screenScissor.x2 = (GLint)ceil((scissor[1].X*0.5f+0.5f)*vpWidth);
 	screenScissor.y2 = (GLint)ceil((scissor[1].Y*0.5f+0.5f)*vpHeight);
 
 	glEnable(GL_SCISSOR_TEST);
 	glScissor(screenScissor.x1, screenScissor.y1, screenScissor.x2 - screenScissor.x1, screenScissor.y2 - screenScissor.y1);
 
 	// try binding the framebuffer
 	pglBindFramebufferEXT(GL_FRAMEBUFFER_EXT, wm.m_RefractionFbo);
 
 	glClearColor(1.0f,0.0f,0.0f,0.0f);
 	glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
 
 	// Render terrain and models
 	RenderPatches(context, CULL_REFRACTIONS);
 	ogl_WarnIfError();
 	RenderModels(context, CULL_REFRACTIONS);
 	ogl_WarnIfError();
 	RenderTransparentModels(context, CULL_REFRACTIONS, TRANSPARENT_OPAQUE, false);
 	ogl_WarnIfError();
 
 	glDisable(GL_SCISSOR_TEST);
 
   	// Reset old camera
   	m_ViewCamera = normalCamera;
   	m->SetOpenGLCamera(m_ViewCamera);
 
 	pglBindFramebufferEXT(GL_FRAMEBUFFER_EXT, 0);
 }
 
 void CRenderer::RenderSilhouettes(const CShaderDefines& context)
 {
 	PROFILE3_GPU("silhouettes");
 
 	CShaderDefines contextOccluder = context;
 	contextOccluder.Add(str_MODE_SILHOUETTEOCCLUDER, str_1);
 
 	CShaderDefines contextDisplay = context;
 	contextDisplay.Add(str_MODE_SILHOUETTEDISPLAY, str_1);
 
 	// Render silhouettes of units hidden behind terrain or occluders.
 	// To avoid breaking the standard rendering of alpha-blended objects, this
 	// has to be done in a separate pass.
 	// First we render all occluders into depth, then render all units with
 	// inverted depth test so any behind an occluder will get drawn in a constant
 	// color.
 
 	float silhouetteAlpha = 0.75f;
 
 	// Silhouette blending requires an almost-universally-supported extension;
 	// fall back to non-blended if unavailable
 	if (!ogl_HaveExtension("GL_EXT_blend_color"))
 		silhouetteAlpha = 1.f;
 
 	glClear(GL_DEPTH_BUFFER_BIT | GL_STENCIL_BUFFER_BIT);
 
 	glColorMask(0, 0, 0, 0);
 
 	// Render occluders:
 
 	{
 		PROFILE("render patches");
 
 		// To prevent units displaying silhouettes when parts of their model
 		// protrude into the ground, only occlude with the back faces of the
 		// terrain (so silhouettes will still display when behind hills)
 		glCullFace(GL_FRONT);
 		m->terrainRenderer.RenderPatches(CULL_SILHOUETTE_OCCLUDER);
 		glCullFace(GL_BACK);
 	}
 
 	{
 		PROFILE("render model occluders");
 		m->CallModelRenderers(contextOccluder, CULL_SILHOUETTE_OCCLUDER, 0);
 	}
 
 	{
 		PROFILE("render transparent occluders");
 		m->CallTranspModelRenderers(contextOccluder, CULL_SILHOUETTE_OCCLUDER, 0);
 	}
 
 	glDepthFunc(GL_GEQUAL);
 	glColorMask(1, 1, 1, 1);
 
 	// Render more efficiently if alpha == 1
 	if (silhouetteAlpha == 1.f)
 	{
 		// Ideally we'd render objects back-to-front so nearer silhouettes would
 		// appear on top, but sorting has non-zero cost. So we'll keep the depth
 		// write enabled, to do the opposite - far objects will consistently appear
 		// on top.
 		glDepthMask(0);
 	}
 	else
 	{
 		// Since we can't sort, we'll use the stencil buffer to ensure we only draw
 		// a pixel once (using the color of whatever model happens to be drawn first).
 		glEnable(GL_BLEND);
 		glBlendFunc(GL_CONSTANT_ALPHA, GL_ONE_MINUS_CONSTANT_ALPHA);
 		pglBlendColorEXT(0, 0, 0, silhouetteAlpha);
 
 		glEnable(GL_STENCIL_TEST);
 		glStencilFunc(GL_NOTEQUAL, 1, (GLuint)-1);
 		glStencilOp(GL_KEEP, GL_KEEP, GL_REPLACE);
 	}
 
 	{
 		PROFILE("render model casters");
 		m->CallModelRenderers(contextDisplay, CULL_SILHOUETTE_CASTER, 0);
 	}
 
 	{
 		PROFILE("render transparent casters");
 		m->CallTranspModelRenderers(contextDisplay, CULL_SILHOUETTE_CASTER, 0);
 	}
 
 	// Restore state
 	glDepthFunc(GL_LEQUAL);
 	if (silhouetteAlpha == 1.f)
 	{
 		glDepthMask(1);
 	}
 	else
 	{
 		glDisable(GL_BLEND);
 		glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
 		pglBlendColorEXT(0, 0, 0, 0);
 		glDisable(GL_STENCIL_TEST);
 	}
 }
 
 void CRenderer::RenderParticles(int cullGroup)
 {
 	PROFILE3_GPU("particles");
 
 	m->particleRenderer.RenderParticles(cullGroup);
 
 #if !CONFIG2_GLES
 	if (m_ModelRenderMode == EDGED_FACES)
 	{
 		glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 
 		glDisable(GL_TEXTURE_2D);
 		glColor3f(0.0f, 0.5f, 0.0f);
 
 		m->particleRenderer.RenderParticles(true);
 
 		CShaderTechniquePtr shaderTech = g_Renderer.GetShaderManager().LoadEffect(str_gui_solid);
 		shaderTech->BeginPass();
 		CShaderProgramPtr shader = shaderTech->GetShader();
 		shader->Uniform(str_color, 0.0f, 1.0f, 0.0f, 1.0f);
 		shader->Uniform(str_transform, m_ViewCamera.GetViewProjection());
 
 		m->particleRenderer.RenderBounds(cullGroup, shader);
 
 		shaderTech->EndPass();
 
 		glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 	}
 #endif
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // RenderSubmissions: force rendering of any batched objects
 void CRenderer::RenderSubmissions(const CBoundingBoxAligned& waterScissor)
 {
 	PROFILE3("render submissions");
 
 	GetScene().GetLOSTexture().InterpolateLOS();
 
 	CShaderDefines context = m->globalContext;
 
 	int cullGroup = CULL_DEFAULT;
 
 	ogl_WarnIfError();
 
 	// Set the camera
 	m->SetOpenGLCamera(m_ViewCamera);
 
 	// Prepare model renderers
 	{
 	PROFILE3("prepare models");
 	m->Model.NormalSkinned->PrepareModels();
 	m->Model.TranspSkinned->PrepareModels();
 	if (m->Model.NormalUnskinned != m->Model.NormalSkinned)
 		m->Model.NormalUnskinned->PrepareModels();
 	if (m->Model.TranspUnskinned != m->Model.TranspSkinned)
 		m->Model.TranspUnskinned->PrepareModels();
 	}
 
 	m->terrainRenderer.PrepareForRendering();
 
 	m->overlayRenderer.PrepareForRendering();
 
 	m->particleRenderer.PrepareForRendering(context);
 
 	if (m_Caps.m_Shadows && g_RenderingOptions.GetShadows())
 	{
 		RenderShadowMap(context);
 	}
 
 	ogl_WarnIfError();
 
 	if (m_WaterManager->m_RenderWater)
 	{
 		if (waterScissor.GetVolume() > 0 && m_WaterManager->WillRenderFancyWater())
 		{
 			PROFILE3_GPU("water scissor");
 			RenderReflections(context, waterScissor);
 
 			if (g_RenderingOptions.GetWaterRefraction())
 				RenderRefractions(context, waterScissor);
 		}
 	}
 
 	if (g_RenderingOptions.GetPostProc())
 	{
 		// We have to update the post process manager with real near/far planes
 		// that we use for the scene rendering.
 		m->postprocManager.SetDepthBufferClipPlanes(
 			m_ViewCamera.GetNearPlane(), m_ViewCamera.GetFarPlane()
 		);
 		m->postprocManager.Initialize();
 		m->postprocManager.CaptureRenderOutput();
 	}
 
 	{
 		PROFILE3_GPU("clear buffers");
 		glClearColor(m_ClearColor[0], m_ClearColor[1], m_ClearColor[2], m_ClearColor[3]);
 		glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT | GL_STENCIL_BUFFER_BIT);
 	}
 
 	m->skyManager.RenderSky();
 
 	// render submitted patches and models
 	RenderPatches(context, cullGroup);
 	ogl_WarnIfError();
 
 	// render debug-related terrain overlays
 	ITerrainOverlay::RenderOverlaysBeforeWater();
 	ogl_WarnIfError();
 
 	// render other debug-related overlays before water (so they can be seen when underwater)
 	m->overlayRenderer.RenderOverlaysBeforeWater();
 	ogl_WarnIfError();
 
 	RenderModels(context, cullGroup);
 	ogl_WarnIfError();
 
 	// render water
 	if (m_WaterManager->m_RenderWater && g_Game && waterScissor.GetVolume() > 0)
 	{
-		// render transparent stuff, but only the solid parts that can occlude block water
-		RenderTransparentModels(context, cullGroup, TRANSPARENT_OPAQUE, false);
-		ogl_WarnIfError();
-
-		m->terrainRenderer.RenderWater(context, cullGroup, &m->shadow);
-		ogl_WarnIfError();
+		if (m_WaterManager->WillRenderFancyWater())
+		{
+			// Render transparent stuff, but only the solid parts that can occlude block water.
+			RenderTransparentModels(context, cullGroup, TRANSPARENT_OPAQUE, false);
+			ogl_WarnIfError();
+
+			m->terrainRenderer.RenderWater(context, cullGroup, &m->shadow);
+			ogl_WarnIfError();
+
+			// Render transparent stuff again, but only the blended parts that overlap water.
+			RenderTransparentModels(context, cullGroup, TRANSPARENT_BLEND, false);
+			ogl_WarnIfError();
+		}
+		else
+		{
+			m->terrainRenderer.RenderWater(context, cullGroup, &m->shadow);
+			ogl_WarnIfError();
 
-		// render transparent stuff again, but only the blended parts that overlap water
-		RenderTransparentModels(context, cullGroup, TRANSPARENT_BLEND, false);
-		ogl_WarnIfError();
+			// Render transparent stuff, so it can overlap models/terrain.
+			RenderTransparentModels(context, cullGroup, TRANSPARENT, false);
+			ogl_WarnIfError();
+		}
 	}
 	else
 	{
 		// render transparent stuff, so it can overlap models/terrain
 		RenderTransparentModels(context, cullGroup, TRANSPARENT, false);
 		ogl_WarnIfError();
 	}
 
 	// render debug-related terrain overlays
 	ITerrainOverlay::RenderOverlaysAfterWater(cullGroup);
 	ogl_WarnIfError();
 
 	// render some other overlays after water (so they can be displayed on top of water)
 	m->overlayRenderer.RenderOverlaysAfterWater();
 	ogl_WarnIfError();
 
 	// particles are transparent so render after water
 	if (g_RenderingOptions.GetParticles())
 	{
 		RenderParticles(cullGroup);
 		ogl_WarnIfError();
 	}
 
 	if (g_RenderingOptions.GetPostProc())
 	{
 		if (g_Renderer.GetPostprocManager().IsMultisampleEnabled())
 			g_Renderer.GetPostprocManager().ResolveMultisampleFramebuffer();
 
 		m->postprocManager.ApplyPostproc();
 		m->postprocManager.ReleaseRenderOutput();
 	}
 
 	if (g_RenderingOptions.GetSilhouettes())
 	{
 		RenderSilhouettes(context);
 	}
 
 	// render debug lines
 	if (g_RenderingOptions.GetDisplayFrustum())
 		DisplayFrustum();
 
 	if (g_RenderingOptions.GetDisplayShadowsFrustum())
 	{
 		m->shadow.RenderDebugBounds();
 		m->shadow.RenderDebugTexture();
 	}
 
 	m->silhouetteRenderer.RenderDebugOverlays(m_ViewCamera);
 
 	// render overlays that should appear on top of all other objects
 	m->overlayRenderer.RenderForegroundOverlays(m_ViewCamera);
 	ogl_WarnIfError();
 
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // EndFrame: signal frame end
 void CRenderer::EndFrame()
 {
 	PROFILE3("end frame");
 
 	// empty lists
 	m->terrainRenderer.EndFrame();
 	m->overlayRenderer.EndFrame();
 	m->particleRenderer.EndFrame();
 	m->silhouetteRenderer.EndFrame();
 
 	// Finish model renderers
 	m->Model.NormalSkinned->EndFrame();
 	m->Model.TranspSkinned->EndFrame();
 	if (m->Model.NormalUnskinned != m->Model.NormalSkinned)
 		m->Model.NormalUnskinned->EndFrame();
 	if (m->Model.TranspUnskinned != m->Model.TranspSkinned)
 		m->Model.TranspUnskinned->EndFrame();
 
 	ogl_tex_bind(0, 0);
 }
 
 void CRenderer::OnSwapBuffers()
 {
 	PROFILE3("error check");
 	// We have to check GL errors after SwapBuffer to avoid possible
 	// synchronizations during rendering.
 	if (GLenum  err = glGetError())
 		ONCE(LOGERROR("GL error %s (0x%04x) occurred", ogl_GetErrorName(err), err));
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // DisplayFrustum: debug displays
 //  - white: cull camera frustum
 //  - red: bounds of shadow casting objects
 void CRenderer::DisplayFrustum()
 {
 #if CONFIG2_GLES
 #warning TODO: implement CRenderer::DisplayFrustum for GLES
 #else
 	glDepthMask(0);
 	glDisable(GL_CULL_FACE);
 	glDisable(GL_TEXTURE_2D);
 
 	glEnable(GL_BLEND);
 	glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
 	glColor4ub(255,255,255,64);
 	m_CullCamera.Render(2);
 	glDisable(GL_BLEND);
 
 	glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
 	glColor3ub(255,255,255);
 	m_CullCamera.Render(2);
 	glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
 
 	glEnable(GL_CULL_FACE);
 	glDepthMask(1);
 #endif
 
 	ogl_WarnIfError();
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Text overlay rendering
 void CRenderer::RenderTextOverlays()
 {
 	PROFILE3_GPU("text overlays");
 
 	if (m_DisplayTerrainPriorities)
 		m->terrainRenderer.RenderPriorities(CULL_DEFAULT);
 
 	ogl_WarnIfError();
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // SetSceneCamera: setup projection and transform of camera and adjust viewport to current view
 // The camera always represents the actual camera used to render a scene, not any virtual camera
 // used for shadow rendering or reflections.
 void CRenderer::SetSceneCamera(const CCamera& viewCamera, const CCamera& cullCamera)
 {
 	m_ViewCamera = viewCamera;
 	m_CullCamera = cullCamera;
 
 	if (m_Caps.m_Shadows && g_RenderingOptions.GetShadows())
 		m->shadow.SetupFrame(m_CullCamera, m_LightEnv->GetSunDir());
 }
 
 
 void CRenderer::SetViewport(const SViewPort &vp)
 {
 	m_Viewport = vp;
 	glViewport((GLint)vp.m_X,(GLint)vp.m_Y,(GLsizei)vp.m_Width,(GLsizei)vp.m_Height);
 }
 
 SViewPort CRenderer::GetViewport()
 {
 	return m_Viewport;
 }
 
 void CRenderer::Submit(CPatch* patch)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 	{
 		m->shadow.AddShadowReceiverBound(patch->GetWorldBounds());
 		m->silhouetteRenderer.AddOccluder(patch);
 	}
 
 	if (m_CurrentCullGroup == CULL_SHADOWS)
 	{
 		m->shadow.AddShadowCasterBound(patch->GetWorldBounds());
 	}
 
 	m->terrainRenderer.Submit(m_CurrentCullGroup, patch);
 }
 
 void CRenderer::Submit(SOverlayLine* overlay)
 {
 	// Overlays are only needed in the default cull group for now,
 	// so just ignore submissions to any other group
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 		m->overlayRenderer.Submit(overlay);
 }
 
 void CRenderer::Submit(SOverlayTexturedLine* overlay)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 		m->overlayRenderer.Submit(overlay);
 }
 
 void CRenderer::Submit(SOverlaySprite* overlay)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 		m->overlayRenderer.Submit(overlay);
 }
 
 void CRenderer::Submit(SOverlayQuad* overlay)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 		m->overlayRenderer.Submit(overlay);
 }
 
 void CRenderer::Submit(SOverlaySphere* overlay)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 		m->overlayRenderer.Submit(overlay);
 }
 
 void CRenderer::Submit(CModelDecal* decal)
 {
 	// Decals can't cast shadows since they're flat on the terrain.
 	// They can receive shadows, but the terrain under them will have
 	// already been passed to AddShadowCasterBound, so don't bother
 	// doing it again here.
 
 	m->terrainRenderer.Submit(m_CurrentCullGroup, decal);
 }
 
 void CRenderer::Submit(CParticleEmitter* emitter)
 {
 	m->particleRenderer.Submit(m_CurrentCullGroup, emitter);
 }
 
 void CRenderer::SubmitNonRecursive(CModel* model)
 {
 	if (m_CurrentCullGroup == CULL_DEFAULT)
 	{
 		m->shadow.AddShadowReceiverBound(model->GetWorldBounds());
 
 		if (model->GetFlags() & MODELFLAG_SILHOUETTE_OCCLUDER)
 			m->silhouetteRenderer.AddOccluder(model);
 		if (model->GetFlags() & MODELFLAG_SILHOUETTE_DISPLAY)
 			m->silhouetteRenderer.AddCaster(model);
 	}
 
 	if (m_CurrentCullGroup == CULL_SHADOWS)
 	{
 		if (!(model->GetFlags() & MODELFLAG_CASTSHADOWS))
 			return;
 
 		m->shadow.AddShadowCasterBound(model->GetWorldBounds());
 	}
 
 	bool requiresSkinning = (model->GetModelDef()->GetNumBones() != 0);
 
 	if (model->GetMaterial().UsesAlphaBlending())
 	{
 		if (requiresSkinning)
 			m->Model.TranspSkinned->Submit(m_CurrentCullGroup, model);
 		else
 			m->Model.TranspUnskinned->Submit(m_CurrentCullGroup, model);
 	}
 	else
 	{
 		if (requiresSkinning)
 			m->Model.NormalSkinned->Submit(m_CurrentCullGroup, model);
 		else
 			m->Model.NormalUnskinned->Submit(m_CurrentCullGroup, model);
 	}
 }
 
 
 ///////////////////////////////////////////////////////////
 // Render the given scene
 void CRenderer::RenderScene(Scene& scene)
 {
 	m_CurrentScene = &scene;
 
 	CFrustum frustum = m_CullCamera.GetFrustum();
 
 	m_CurrentCullGroup = CULL_DEFAULT;
 
 	scene.EnumerateObjects(frustum, this);
 
 	m->particleManager.RenderSubmit(*this, frustum);
 
 	if (g_RenderingOptions.GetSilhouettes())
 	{
 		m->silhouetteRenderer.ComputeSubmissions(m_ViewCamera);
 
 		m_CurrentCullGroup = CULL_DEFAULT;
 		m->silhouetteRenderer.RenderSubmitOverlays(*this);
 
 		m_CurrentCullGroup = CULL_SILHOUETTE_OCCLUDER;
 		m->silhouetteRenderer.RenderSubmitOccluders(*this);
 
 		m_CurrentCullGroup = CULL_SILHOUETTE_CASTER;
 		m->silhouetteRenderer.RenderSubmitCasters(*this);
 	}
 
 	if (m_Caps.m_Shadows && g_RenderingOptions.GetShadows())
 	{
 		m_CurrentCullGroup = CULL_SHADOWS;
 
 		CFrustum shadowFrustum = m->shadow.GetShadowCasterCullFrustum();
 		scene.EnumerateObjects(shadowFrustum, this);
 	}
 
 	CBoundingBoxAligned waterScissor;
 	if (m_WaterManager->m_RenderWater)
 	{
 		waterScissor = m->terrainRenderer.ScissorWater(CULL_DEFAULT, m_ViewCamera.GetViewProjection());
 
 		if (waterScissor.GetVolume() > 0 && m_WaterManager->WillRenderFancyWater())
 		{
 			if (g_RenderingOptions.GetWaterReflection())
 			{
 				m_CurrentCullGroup = CULL_REFLECTIONS;
 
 				CCamera reflectionCamera;
 				ComputeReflectionCamera(reflectionCamera, waterScissor);
 
 				scene.EnumerateObjects(reflectionCamera.GetFrustum(), this);
 			}
 
 			if (g_RenderingOptions.GetWaterRefraction())
 			{
 				m_CurrentCullGroup = CULL_REFRACTIONS;
 
 				CCamera refractionCamera;
 				ComputeRefractionCamera(refractionCamera, waterScissor);
 
 				scene.EnumerateObjects(refractionCamera.GetFrustum(), this);
 			}
 
 			// Render the waves to the Fancy effects texture
 			m_WaterManager->RenderWaves(frustum);
 		}
 	}
 
 	m_CurrentCullGroup = -1;
 
 	ogl_WarnIfError();
 
 	RenderSubmissions(waterScissor);
 
 	m_CurrentScene = NULL;
 }
 
 Scene& CRenderer::GetScene()
 {
 	ENSURE(m_CurrentScene);
 	return *m_CurrentScene;
 }
 
 //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
 // BindTexture: bind a GL texture object to current active unit
 void CRenderer::BindTexture(int unit, GLuint tex)
 {
 	pglActiveTextureARB(GL_TEXTURE0+unit);
 
 	glBindTexture(GL_TEXTURE_2D, tex);
 #if !CONFIG2_GLES
 	if (tex) {
 		glEnable(GL_TEXTURE_2D);
 	} else {
 		glDisable(GL_TEXTURE_2D);
 	}
 #endif
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // LoadAlphaMaps: load the 14 default alpha maps, pack them into one composite texture and
 // calculate the coordinate of each alphamap within this packed texture
 // NB: A variant of this function is duplicated in TerrainTextureEntry.cpp, for use with the Shader
 // renderpath. This copy is kept to load the 'standard' maps for the fixed pipeline and should
 // be removed if/when the fixed pipeline goes.
 int CRenderer::LoadAlphaMaps()
 {
 	const wchar_t* const key = L"(alpha map composite)";
 	Handle ht = ogl_tex_find(key);
 	// alpha map texture had already been created and is still in memory:
 	// reuse it, do not load again.
 	if(ht > 0)
 	{
 		m_hCompositeAlphaMap = ht;
 		return 0;
 	}
 
 	//
 	// load all textures and store Handle in array
 	//
 	Handle textures[NumAlphaMaps] = {0};
 	VfsPath path(L"art/textures/terrain/alphamaps/standard");
 	const wchar_t* fnames[NumAlphaMaps] = {
 		L"blendcircle.png",
 		L"blendlshape.png",
 		L"blendedge.png",
 		L"blendedgecorner.png",
 		L"blendedgetwocorners.png",
 		L"blendfourcorners.png",
 		L"blendtwooppositecorners.png",
 		L"blendlshapecorner.png",
 		L"blendtwocorners.png",
 		L"blendcorner.png",
 		L"blendtwoedges.png",
 		L"blendthreecorners.png",
 		L"blendushape.png",
 		L"blendbad.png"
 	};
 	size_t base = 0;	// texture width/height (see below)
 	// for convenience, we require all alpha maps to be of the same BPP
 	// (avoids another ogl_tex_get_size call, and doesn't hurt)
 	size_t bpp = 0;
 	for(size_t i=0;i<NumAlphaMaps;i++)
 	{
 		// note: these individual textures can be discarded afterwards;
 		// we cache the composite.
 		textures[i] = ogl_tex_load(g_VFS, path / fnames[i]);
 		RETURN_STATUS_IF_ERR(textures[i]);
 
 		// get its size and make sure they are all equal.
 		// (the packing algo assumes this)
 		size_t this_width = 0, this_height = 0, this_bpp = 0;	// fail-safe
 		ignore_result(ogl_tex_get_size(textures[i], &this_width, &this_height, &this_bpp));
 		if(this_width != this_height)
 			DEBUG_DISPLAY_ERROR(L"Alpha maps are not square");
 		// .. first iteration: establish size
 		if(i == 0)
 		{
 			base = this_width;
 			bpp  = this_bpp;
 		}
 		// .. not first: make sure texture size matches
 		else if(base != this_width || bpp != this_bpp)
 			DEBUG_DISPLAY_ERROR(L"Alpha maps are not identically sized (including pixel depth)");
 	}
 
 	//
 	// copy each alpha map (tile) into one buffer, arrayed horizontally.
 	//
 	size_t tile_w = 2+base+2;	// 2 pixel border (avoids bilinear filtering artifacts)
 	size_t total_w = round_up_to_pow2(tile_w * NumAlphaMaps);
 	size_t total_h = base; ENSURE(is_pow2(total_h));
 	shared_ptr<u8> data;
 	AllocateAligned(data, total_w*total_h, maxSectorSize);
 	// for each tile on row
 	for (size_t i = 0; i < NumAlphaMaps; i++)
 	{
 		// get src of copy
 		u8* src = 0;
 		ignore_result(ogl_tex_get_data(textures[i], &src));
 
 		size_t srcstep = bpp/8;
 
 		// get destination of copy
 		u8* dst = data.get() + (i*tile_w);
 
 		// for each row of image
 		for (size_t j = 0; j < base; j++)
 		{
 			// duplicate first pixel
 			*dst++ = *src;
 			*dst++ = *src;
 
 			// copy a row
 			for (size_t k = 0; k < base; k++)
 			{
 				*dst++ = *src;
 				src += srcstep;
 			}
 
 			// duplicate last pixel
 			*dst++ = *(src-srcstep);
 			*dst++ = *(src-srcstep);
 
 			// advance write pointer for next row
 			dst += total_w-tile_w;
 		}
 
 		m_AlphaMapCoords[i].u0 = float(i*tile_w+2) / float(total_w);
 		m_AlphaMapCoords[i].u1 = float((i+1)*tile_w-2) / float(total_w);
 		m_AlphaMapCoords[i].v0 = 0.0f;
 		m_AlphaMapCoords[i].v1 = 1.0f;
 	}
 
 	for (size_t i = 0; i < NumAlphaMaps; i++)
 		ignore_result(ogl_tex_free(textures[i]));
 
 	// upload the composite texture
 	Tex t;
 	ignore_result(t.wrap(total_w, total_h, 8, TEX_GREY, data, 0));
 
 	/*VfsPath filename("blendtex.png");
 
 	DynArray da;
 	RETURN_STATUS_IF_ERR(tex_encode(&t, filename.Extension(), &da));
 
 	// write to disk
 	//Status ret = INFO::OK;
 	{
 		shared_ptr<u8> file = DummySharedPtr(da.base);
 		const ssize_t bytes_written = g_VFS->CreateFile(filename, file, da.pos);
 		if(bytes_written > 0)
 			ENSURE(bytes_written == (ssize_t)da.pos);
 		//else
 		//	ret = (Status)bytes_written;
 	}
 
 	ignore_result(da_free(&da));*/
 
 	m_hCompositeAlphaMap = ogl_tex_wrap(&t, g_VFS, key);
 	ignore_result(ogl_tex_set_filter(m_hCompositeAlphaMap, GL_LINEAR));
 	ignore_result(ogl_tex_set_wrap  (m_hCompositeAlphaMap, GL_CLAMP_TO_EDGE, GL_CLAMP_TO_EDGE));
 	int ret = ogl_tex_upload(m_hCompositeAlphaMap, GL_ALPHA, 0, 0);
 
 	return ret;
 }
 
 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // UnloadAlphaMaps: frees the resources allocates by LoadAlphaMaps
 void CRenderer::UnloadAlphaMaps()
 {
 	ogl_tex_free(m_hCompositeAlphaMap);
 	m_hCompositeAlphaMap = 0;
 }
 
 
 
 Status CRenderer::ReloadChangedFileCB(void* param, const VfsPath& path)
 {
 	CRenderer* renderer = static_cast<CRenderer*>(param);
 
 	// If an alpha map changed, and we already loaded them, then reload them
 	if (boost::algorithm::starts_with(path.string(), L"art/textures/terrain/alphamaps/"))
 	{
 		if (renderer->m_hCompositeAlphaMap)
 		{
 			renderer->UnloadAlphaMaps();
 			renderer->LoadAlphaMaps();
 		}
 	}
 
 	return INFO::OK;
 }
 
 void CRenderer::MakeShadersDirty()
 {
 	m->ShadersDirty = true;
 	m_WaterManager->m_NeedsReloading = true;
 }
 
 CTextureManager& CRenderer::GetTextureManager()
 {
 	return m->textureManager;
 }
 
 CShaderManager& CRenderer::GetShaderManager()
 {
 	return m->shaderManager;
 }
 
 CParticleManager& CRenderer::GetParticleManager()
 {
 	return m->particleManager;
 }
 
 TerrainRenderer& CRenderer::GetTerrainRenderer()
 {
 	return m->terrainRenderer;
 }
 
 CTimeManager& CRenderer::GetTimeManager()
 {
 	return m->timeManager;
 }
 
 CMaterialManager& CRenderer::GetMaterialManager()
 {
 	return m->materialManager;
 }
 
 CPostprocManager& CRenderer::GetPostprocManager()
 {
 	return m->postprocManager;
 }
 
 CFontManager& CRenderer::GetFontManager()
 {
 	return m->fontManager;
 }
 
 ShadowMap& CRenderer::GetShadowMap()
 {
 	return m->shadow;
 }
 
 void CRenderer::ResetState()
 {
 	// Clear all emitters, that were created in previous games
 	GetParticleManager().ClearUnattachedEmitters();
 }