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hl2sdk/cl_dll/clientshadowmgr.cpp

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Added most recent version of unmodified HL2 SDK for Episode 1 engine
2008-09-15 01:00:17 -05:00
//===== Copyright <20> 1996-2005, Valve Corporation, All rights reserved. ======//
//
// Purpose:
//
// $NoKeywords: $
//
// Interface to the client system responsible for dealing with shadows
//
// Boy is this complicated. OK, lets talk about how this works at the moment
//
// The ClientShadowMgr contains all of the highest-level state for rendering
// shadows, and it controls the ShadowMgr in the engine which is the central
// clearing house for rendering shadows.
//
// There are two important types of objects with respect to shadows:
// the shadow receiver, and the shadow caster. How is the association made
// between casters + the receivers? Turns out it's done slightly differently
// depending on whether the receiver is the world, or if it's an entity.
//
// In the case of the world, every time the engine's ProjectShadow() is called,
// any previous receiver state stored (namely, which world surfaces are
// receiving shadows) are cleared. Then, when ProjectShadow is called,
// the engine iterates over all nodes + leaves within the shadow volume and
// marks front-facing surfaces in them as potentially being affected by the
// shadow. Later on, if those surfaces are actually rendered, the surfaces
// are clipped by the shadow volume + rendered.
//
// In the case of entities, there are slightly different methods depending
// on whether the receiver is a brush model or a studio model. However, there
// are a couple central things that occur with both.
//
// Every time a shadow caster is moved, the ClientLeafSystem's ProjectShadow
// method is called to tell it to remove the shadow from all leaves + all
// renderables it's currently associated with. Then it marks each leaf in the
// shadow volume as being affected by that shadow, and it marks every renderable
// in that volume as being potentially affected by the shadow (the function
// AddShadowToRenderable is called for each renderable in leaves affected
// by the shadow volume).
//
// Every time a shadow receiver is moved, the ClientLeafSystem first calls
// RemoveAllShadowsFromRenderable to have it clear out its state, and then
// the ClientLeafSystem calls AddShadowToRenderable() for all shadows in all
// leaves the renderable has moved into.
//
// Now comes the difference between brush models + studio models. In the case
// of brush models, when a shadow is added to the studio model, it's done in
// the exact same way as for the world. Surfaces on the brush model are marked
// as potentially being affected by the shadow, and if those surfaces are
// rendered, the surfaces are clipped to the shadow volume. When ProjectShadow()
// is called, turns out the same operation that removes the shadow that moved
// from the world surfaces also works to remove the shadow from brush surfaces.
//
// In the case of studio models, we need a separate operation to remove
// the shadow from all studio models
//===========================================================================//
#include "cbase.h"
#include "engine/IShadowMgr.h"
#include "model_types.h"
#include "bitmap/imageformat.h"
#include "materialsystem/IMaterialProxy.h"
#include "materialsystem/IMaterialVar.h"
#include "materialsystem/IMaterial.h"
#include "materialsystem/IMesh.h"
#include "materialsystem/ITexture.h"
#include "utlmultilist.h"
#include "CollisionUtils.h"
#include "IVRenderView.h"
#include "tier0/vprof.h"
#include "engine/ivmodelinfo.h"
#include "view_shared.h"
#include "engine/IVDebugOverlay.h"
#include "engine/IStaticPropMgr.h"
#include "datacache/imdlcache.h"
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
static ConVar r_flashlightdrawfrustum( "r_flashlightdrawfrustum", "0" );
static ConVar r_flashlightmodels( "r_flashlightmodels", "1" );
static ConVar r_shadowrendertotexture( "r_shadowrendertotexture", "1" );
#ifdef DOSHADOWEDFLASHLIGHT
static ConVar r_flashlightdepthtexture( "r_flashlightdepthtexture", "0" );
static ConVar r_flashlightdepthres( "r_flashlightdepthres", "512" );
#endif
#ifdef _WIN32
#pragma warning( disable: 4701 )
#endif
//-----------------------------------------------------------------------------
// A texture allocator used to batch textures together
// At the moment, the implementation simply allocates blocks of max 256x256
// and each block stores an array of uniformly-sized textures
//-----------------------------------------------------------------------------
typedef unsigned short TextureHandle_t;
enum
{
INVALID_TEXTURE_HANDLE = (TextureHandle_t)~0
};
class CTextureAllocator
{
public:
// Initialize the allocator with something that knows how to refresh the bits
void Init();
void Shutdown();
// Resets the allocator
void Reset();
// Deallocates everything
void DeallocateAllTextures();
// Allocate, deallocate texture
TextureHandle_t AllocateTexture( int w, int h );
void DeallocateTexture( TextureHandle_t h );
// Mark texture as being used... (return true if re-render is needed)
bool UseTexture( TextureHandle_t h, bool bWillRedraw, float flArea );
// Advance frame...
void AdvanceFrame();
// Get at the location of the texture
void GetTextureRect(TextureHandle_t handle, int& x, int& y, int& w, int& h );
// Get at the texture it's a part of
ITexture* GetTexture();
// Get at the total texture size.
void GetTotalTextureSize( int& w, int& h );
void DebugPrintCache( void );
private:
typedef unsigned short FragmentHandle_t;
enum
{
INVALID_FRAGMENT_HANDLE = (FragmentHandle_t)~0,
#ifndef _XBOX
TEXTURE_PAGE_SIZE = 1024,
MAX_TEXTURE_POWER = 8,
MIN_TEXTURE_POWER = 4,
#else
TEXTURE_PAGE_SIZE = 512,
MAX_TEXTURE_POWER = 7,
MIN_TEXTURE_POWER = 3,
#endif
MAX_TEXTURE_SIZE = (1 << MAX_TEXTURE_POWER),
MIN_TEXTURE_SIZE = (1 << MIN_TEXTURE_POWER),
BLOCK_SIZE = MAX_TEXTURE_SIZE,
BLOCKS_PER_ROW = (TEXTURE_PAGE_SIZE / MAX_TEXTURE_SIZE),
BLOCK_COUNT = (BLOCKS_PER_ROW * BLOCKS_PER_ROW),
};
struct TextureInfo_t
{
FragmentHandle_t m_Fragment;
unsigned short m_Size;
unsigned short m_Power;
};
struct FragmentInfo_t
{
unsigned short m_Block;
unsigned short m_Index;
TextureHandle_t m_Texture;
// Makes sure we don't overflow
unsigned int m_FrameUsed;
};
struct BlockInfo_t
{
unsigned short m_FragmentPower;
};
struct Cache_t
{
unsigned short m_List;
};
// Adds a block worth of fragments to the LRU
void AddBlockToLRU( int block );
// Unlink fragment from cache
void UnlinkFragmentFromCache( Cache_t& cache, FragmentHandle_t fragment );
// Mark something as being used (MRU)..
void MarkUsed( FragmentHandle_t fragment );
// Mark something as being unused (LRU)..
void MarkUnused( FragmentHandle_t fragment );
// Disconnect texture from fragment
void DisconnectTextureFromFragment( FragmentHandle_t f );
// Returns the size of a particular fragment
int GetFragmentPower( FragmentHandle_t f ) const;
// Stores the actual texture we're writing into
CTextureReference m_TexturePage;
CUtlLinkedList< TextureInfo_t, TextureHandle_t > m_Textures;
CUtlMultiList< FragmentInfo_t, FragmentHandle_t > m_Fragments;
Cache_t m_Cache[MAX_TEXTURE_POWER+1];
BlockInfo_t m_Blocks[BLOCK_COUNT];
unsigned int m_CurrentFrame;
};
//-----------------------------------------------------------------------------
// Allocate/deallocate the texture page
//-----------------------------------------------------------------------------
void CTextureAllocator::Init()
{
for ( int i = 0; i <= MAX_TEXTURE_POWER; ++i )
{
m_Cache[i].m_List = m_Fragments.InvalidIndex();
}
#ifndef _XBOX
// GR: don't need depth buffer for shadows
m_TexturePage.InitRenderTarget( TEXTURE_PAGE_SIZE, TEXTURE_PAGE_SIZE, RT_SIZE_NO_CHANGE, IMAGE_FORMAT_ARGB8888, MATERIAL_RT_DEPTH_NONE, false );
#else
// xboxissue - has to be linear format because swizzled render targets cannot be subrect cleared.
// can use a 16 bit format, and use rgb channel instead of alpha for shadow info
m_TexturePage.InitRenderTarget( TEXTURE_PAGE_SIZE, TEXTURE_PAGE_SIZE, RT_SIZE_NO_CHANGE, IMAGE_FORMAT_LINEAR_BGRX5551, MATERIAL_RT_DEPTH_NONE, false );
#endif
}
void CTextureAllocator::Shutdown()
{
m_TexturePage.Shutdown( );
}
//-----------------------------------------------------------------------------
// Initialize the allocator with something that knows how to refresh the bits
//-----------------------------------------------------------------------------
void CTextureAllocator::Reset()
{
DeallocateAllTextures();
m_Textures.EnsureCapacity(256);
m_Fragments.EnsureCapacity(256);
// Set up the block sizes....
// FIXME: Improve heuristic?!?
#ifndef _XBOX
m_Blocks[0].m_FragmentPower = 4; // 128 x 16
m_Blocks[1].m_FragmentPower = 5; // 64 x 32
m_Blocks[2].m_FragmentPower = 6; // 32 x 64
m_Blocks[3].m_FragmentPower = 6;
m_Blocks[4].m_FragmentPower = 7; // 24 x 128
m_Blocks[5].m_FragmentPower = 7;
m_Blocks[6].m_FragmentPower = 7;
m_Blocks[7].m_FragmentPower = 7;
m_Blocks[8].m_FragmentPower = 7;
m_Blocks[9].m_FragmentPower = 7;
m_Blocks[10].m_FragmentPower = 8; // 6 x 256
m_Blocks[11].m_FragmentPower = 8;
m_Blocks[12].m_FragmentPower = 8;
m_Blocks[13].m_FragmentPower = 8;
m_Blocks[14].m_FragmentPower = 8;
m_Blocks[15].m_FragmentPower = 8;
#else
m_Blocks[0].m_FragmentPower = MAX_TEXTURE_POWER-4; // 128 cells at ExE
m_Blocks[1].m_FragmentPower = MAX_TEXTURE_POWER-3; // 64 cells at DxD
m_Blocks[2].m_FragmentPower = MAX_TEXTURE_POWER-2; // 32 cells at CxC
m_Blocks[3].m_FragmentPower = MAX_TEXTURE_POWER-2;
m_Blocks[4].m_FragmentPower = MAX_TEXTURE_POWER-1; // 24 cells at BxB
m_Blocks[5].m_FragmentPower = MAX_TEXTURE_POWER-1;
m_Blocks[6].m_FragmentPower = MAX_TEXTURE_POWER-1;
m_Blocks[7].m_FragmentPower = MAX_TEXTURE_POWER-1;
m_Blocks[8].m_FragmentPower = MAX_TEXTURE_POWER-1;
m_Blocks[9].m_FragmentPower = MAX_TEXTURE_POWER-1;
m_Blocks[10].m_FragmentPower = MAX_TEXTURE_POWER; // 6 cells at AxA
m_Blocks[11].m_FragmentPower = MAX_TEXTURE_POWER;
m_Blocks[12].m_FragmentPower = MAX_TEXTURE_POWER;
m_Blocks[13].m_FragmentPower = MAX_TEXTURE_POWER;
m_Blocks[14].m_FragmentPower = MAX_TEXTURE_POWER;
m_Blocks[15].m_FragmentPower = MAX_TEXTURE_POWER;
#endif
// Initialize the LRU
int i;
for ( i = 0; i <= MAX_TEXTURE_POWER; ++i )
{
m_Cache[i].m_List = m_Fragments.CreateList();
}
// Now that the block sizes are allocated, create LRUs for the various block sizes
for ( i = 0; i < BLOCK_COUNT; ++i)
{
// Initialize LRU
AddBlockToLRU( i );
}
m_CurrentFrame = 0;
}
void CTextureAllocator::DeallocateAllTextures()
{
m_Textures.Purge();
m_Fragments.Purge();
for ( int i = 0; i <= MAX_TEXTURE_POWER; ++i )
{
m_Cache[i].m_List = m_Fragments.InvalidIndex();
}
}
//-----------------------------------------------------------------------------
// Dump the state of the cache to debug out
//-----------------------------------------------------------------------------
void CTextureAllocator::DebugPrintCache( void )
{
// For each fragment
int nNumFragments = m_Fragments.TotalCount();
int nNumInvalidFragments = 0;
Warning("Fragments (%d):\n===============\n", nNumFragments);
for ( int f = 0; f < nNumFragments; f++ )
{
if ( ( m_Fragments[f].m_FrameUsed != 0 ) && ( m_Fragments[f].m_Texture != INVALID_TEXTURE_HANDLE ) )
Warning("Fragment %d, Block: %d, Index: %d, Texture: %d Frame Used: %d\n", f, m_Fragments[f].m_Block, m_Fragments[f].m_Index, m_Fragments[f].m_Texture, m_Fragments[f].m_FrameUsed );
else
nNumInvalidFragments++;
}
Warning("Invalid Fragments: %d\n", nNumInvalidFragments);
// for ( int c = 0; c <= MAX_TEXTURE_POWER; ++c )
// {
// Warning("Cache Index (%d)\n", m_Cache[c].m_List);
// }
}
//-----------------------------------------------------------------------------
// Adds a block worth of fragments to the LRU
//-----------------------------------------------------------------------------
void CTextureAllocator::AddBlockToLRU( int block )
{
int power = m_Blocks[block].m_FragmentPower;
int size = (1 << power);
// Compute the number of fragments in this block
int fragmentCount = MAX_TEXTURE_SIZE / size;
fragmentCount *= fragmentCount;
// For each fragment, indicate which block it's a part of (and the index)
// and then stick in at the top of the LRU
while (--fragmentCount >= 0 )
{
FragmentHandle_t f = m_Fragments.Alloc( );
m_Fragments[f].m_Block = block;
m_Fragments[f].m_Index = fragmentCount;
m_Fragments[f].m_Texture = INVALID_TEXTURE_HANDLE;
m_Fragments[f].m_FrameUsed = 0xFFFFFFFF;
m_Fragments.LinkToHead( m_Cache[power].m_List, f );
}
}
//-----------------------------------------------------------------------------
// Unlink fragment from cache
//-----------------------------------------------------------------------------
void CTextureAllocator::UnlinkFragmentFromCache( Cache_t& cache, FragmentHandle_t fragment )
{
m_Fragments.Unlink( cache.m_List, fragment);
}
//-----------------------------------------------------------------------------
// Mark something as being used (MRU)..
//-----------------------------------------------------------------------------
void CTextureAllocator::MarkUsed( FragmentHandle_t fragment )
{
int block = m_Fragments[fragment].m_Block;
int power = m_Blocks[block].m_FragmentPower;
// Hook it at the end of the LRU
Cache_t& cache = m_Cache[power];
m_Fragments.LinkToTail( cache.m_List, fragment );
m_Fragments[fragment].m_FrameUsed = m_CurrentFrame;
}
//-----------------------------------------------------------------------------
// Mark something as being unused (LRU)..
//-----------------------------------------------------------------------------
void CTextureAllocator::MarkUnused( FragmentHandle_t fragment )
{
int block = m_Fragments[fragment].m_Block;
int power = m_Blocks[block].m_FragmentPower;
// Hook it at the end of the LRU
Cache_t& cache = m_Cache[power];
m_Fragments.LinkToHead( cache.m_List, fragment );
}
//-----------------------------------------------------------------------------
// Allocate, deallocate texture
//-----------------------------------------------------------------------------
TextureHandle_t CTextureAllocator::AllocateTexture( int w, int h )
{
// Implementational detail for now
Assert( w == h );
// Clamp texture size
if (w < MIN_TEXTURE_SIZE)
w = MIN_TEXTURE_SIZE;
else if (w > MAX_TEXTURE_SIZE)
w = MAX_TEXTURE_SIZE;
TextureHandle_t handle = m_Textures.AddToTail();
m_Textures[handle].m_Fragment = INVALID_FRAGMENT_HANDLE;
m_Textures[handle].m_Size = w;
// Find the power of two
int power = 0;
int size = 1;
while(size < w)
{
size <<= 1;
++power;
}
Assert( size == w );
m_Textures[handle].m_Power = power;
return handle;
}
void CTextureAllocator::DeallocateTexture( TextureHandle_t h )
{
// Warning("Beginning of DeallocateTexture\n");
// DebugPrintCache();
if (m_Textures[h].m_Fragment != INVALID_FRAGMENT_HANDLE)
{
MarkUnused(m_Textures[h].m_Fragment);
m_Fragments[m_Textures[h].m_Fragment].m_FrameUsed = 0xFFFFFFFF; // non-zero frame
DisconnectTextureFromFragment( m_Textures[h].m_Fragment );
}
m_Textures.Remove(h);
// Warning("End of DeallocateTexture\n");
// DebugPrintCache();
}
//-----------------------------------------------------------------------------
// Disconnect texture from fragment
//-----------------------------------------------------------------------------
void CTextureAllocator::DisconnectTextureFromFragment( FragmentHandle_t f )
{
// Warning( "Beginning of DisconnectTextureFromFragment\n" );
// DebugPrintCache();
FragmentInfo_t& info = m_Fragments[f];
if (info.m_Texture != INVALID_TEXTURE_HANDLE)
{
m_Textures[info.m_Texture].m_Fragment = INVALID_FRAGMENT_HANDLE;
info.m_Texture = INVALID_TEXTURE_HANDLE;
}
// Warning( "End of DisconnectTextureFromFragment\n" );
// DebugPrintCache();
}
//-----------------------------------------------------------------------------
// Mark texture as being used...
//-----------------------------------------------------------------------------
bool CTextureAllocator::UseTexture( TextureHandle_t h, bool bWillRedraw, float flArea )
{
// Warning( "Top of UseTexture\n" );
// DebugPrintCache();
TextureInfo_t& info = m_Textures[h];
// 4 is the minimum power we have allocated
int nDesiredPower = 4;
int nDesiredWidth = 16;
while ( (nDesiredWidth * nDesiredWidth) < flArea )
{
if ( nDesiredPower >= info.m_Power )
{
nDesiredPower = info.m_Power;
break;
}
++nDesiredPower;
nDesiredWidth *= 2;
}
// If we've got a valid fragment for this texture, no worries!
int nCurrentPower = -1;
FragmentHandle_t currentFragment = info.m_Fragment;
if (currentFragment != INVALID_FRAGMENT_HANDLE)
{
// If the current fragment is at or near the desired power, we're done
nCurrentPower = GetFragmentPower(info.m_Fragment);
Assert( nCurrentPower <= info.m_Power );
bool bShouldKeepTexture = (!bWillRedraw) && (nDesiredPower < 8) && (nDesiredPower - nCurrentPower <= 1);
if ((nCurrentPower == nDesiredPower) || bShouldKeepTexture)
{
// Move to the back of the LRU
MarkUsed( currentFragment );
return false;
}
}
// Warning( "\n\nUseTexture B\n" );
// DebugPrintCache();
// Grab the LRU fragment from the appropriate cache
// If that fragment is connected to a texture, disconnect it.
int power = nDesiredPower;
FragmentHandle_t f = INVALID_FRAGMENT_HANDLE;
bool done = false;
while (!done && power >= 0)
{
f = m_Fragments.Head( m_Cache[power].m_List );
// This represents an overflow condition (used too many textures of
// the same size in a single frame). It that happens, just use a texture
// of lower res.
if ( (f != m_Fragments.InvalidIndex()) && (m_Fragments[f].m_FrameUsed != m_CurrentFrame) )
{
done = true;
}
else
{
--power;
}
}
// Warning( "\n\nUseTexture C\n" );
// DebugPrintCache();
// Ok, lets see if we're better off than we were...
if (currentFragment != INVALID_FRAGMENT_HANDLE)
{
if (power <= nCurrentPower)
{
// Oops... we're not. Let's leave well enough alone
// Move to the back of the LRU
MarkUsed( currentFragment );
return false;
}
else
{
// Clear out the old fragment
DisconnectTextureFromFragment(currentFragment);
}
}
if ( f == INVALID_FRAGMENT_HANDLE )
{
return false;
}
// Disconnect existing texture from this fragment (if necessary)
DisconnectTextureFromFragment(f);
// Connnect new texture to this fragment
info.m_Fragment = f;
m_Fragments[f].m_Texture = h;
// Move to the back of the LRU
MarkUsed( f );
// Indicate we need a redraw
return true;
}
//-----------------------------------------------------------------------------
// Returns the size of a particular fragment
//-----------------------------------------------------------------------------
int CTextureAllocator::GetFragmentPower( FragmentHandle_t f ) const
{
return m_Blocks[m_Fragments[f].m_Block].m_FragmentPower;
}
//-----------------------------------------------------------------------------
// Advance frame...
//-----------------------------------------------------------------------------
void CTextureAllocator::AdvanceFrame()
{
// Be sure that this is called as infrequently as possible (i.e. once per frame,
// NOT once per view) to prevent cache thrash when rendering multiple views in a single frame
m_CurrentFrame++;
}
//-----------------------------------------------------------------------------
// Prepare to render into texture...
//-----------------------------------------------------------------------------
ITexture* CTextureAllocator::GetTexture()
{
return m_TexturePage;
}
//-----------------------------------------------------------------------------
// Get at the total texture size.
//-----------------------------------------------------------------------------
void CTextureAllocator::GetTotalTextureSize( int& w, int& h )
{
w = h = TEXTURE_PAGE_SIZE;
}
//-----------------------------------------------------------------------------
// Returns the rectangle the texture lives in..
//-----------------------------------------------------------------------------
void CTextureAllocator::GetTextureRect(TextureHandle_t handle, int& x, int& y, int& w, int& h )
{
TextureInfo_t& info = m_Textures[handle];
Assert( info.m_Fragment != INVALID_FRAGMENT_HANDLE );
// Compute the position of the fragment in the page
FragmentInfo_t& fragment = m_Fragments[info.m_Fragment];
int blockY = fragment.m_Block / BLOCKS_PER_ROW;
int blockX = fragment.m_Block - blockY * BLOCKS_PER_ROW;
int fragmentSize = (1 << m_Blocks[fragment.m_Block].m_FragmentPower);
int fragmentsPerRow = BLOCK_SIZE / fragmentSize;
int fragmentY = fragment.m_Index / fragmentsPerRow;
int fragmentX = fragment.m_Index - fragmentY * fragmentsPerRow;
x = blockX * BLOCK_SIZE + fragmentX * fragmentSize;
y = blockY * BLOCK_SIZE + fragmentY * fragmentSize;
w = fragmentSize;
h = fragmentSize;
}
//-----------------------------------------------------------------------------
// Defines how big of a shadow texture we should be making per caster...
//-----------------------------------------------------------------------------
#define TEXEL_SIZE_PER_CASTER_SIZE 2.0f
#define MAX_FALLOFF_AMOUNT 240
#define MAX_CLIP_PLANE_COUNT 4
#define SHADOW_CULL_TOLERANCE 0.5f
static ConVar r_shadows( "r_shadows", "1" ); // hook into engine's cvars..
static ConVar r_shadowmaxrendered("r_shadowmaxrendered", "32");
static ConVar r_shadows_gamecontrol( "r_shadows_gamecontrol", "-1" ); // hook into engine's cvars..
//-----------------------------------------------------------------------------
// The class responsible for dealing with shadows on the client side
// Oh, and let's take a moment and notice how happy Robin and John must be
// owing to the lack of space between this lovely comment and the class name =)
//-----------------------------------------------------------------------------
class CClientShadowMgr : public IClientShadowMgr
{
public:
CClientShadowMgr();
virtual char const *Name() { return "CCLientShadowMgr"; }
// Inherited from IClientShadowMgr
virtual bool Init();
virtual void Shutdown();
virtual void LevelInitPreEntity();
virtual void LevelInitPostEntity() {}
virtual void LevelShutdownPreEntity() {}
virtual void LevelShutdownPostEntity();
virtual bool IsPerFrame() { return true; }
virtual void PreRender();
virtual void Update( float frametime ) { }
virtual void PostRender() {}
virtual void OnSave() {}
virtual void OnRestore() {}
virtual void SafeRemoveIfDesired() {}
virtual ClientShadowHandle_t CreateShadow( ClientEntityHandle_t entity, int flags );
virtual void DestroyShadow( ClientShadowHandle_t handle );
// Create flashlight (projected texture light source)
virtual ClientShadowHandle_t CreateFlashlight( const FlashlightState_t &lightState );
virtual void UpdateFlashlightState( ClientShadowHandle_t shadowHandle, const FlashlightState_t &lightState );
virtual void DestroyFlashlight( ClientShadowHandle_t shadowHandle );
// Update a shadow
virtual void UpdateProjectedTexture( ClientShadowHandle_t handle, bool force );
void ComputeBoundingSphere( IClientRenderable* pRenderable, Vector& origin, float& radius );
virtual void AddToDirtyShadowList( ClientShadowHandle_t handle, bool bForce );
virtual void AddToDirtyShadowList( IClientRenderable *pRenderable, bool force );
// Marks the render-to-texture shadow as needing to be re-rendered
virtual void MarkRenderToTextureShadowDirty( ClientShadowHandle_t handle );
// deals with shadows being added to shadow receivers
void AddShadowToReceiver( ClientShadowHandle_t handle,
IClientRenderable* pRenderable, ShadowReceiver_t type );
// deals with shadows being added to shadow receivers
void RemoveAllShadowsFromReceiver( IClientRenderable* pRenderable, ShadowReceiver_t type );
// Re-renders all shadow textures for shadow casters that lie in the leaf list
void ComputeShadowTextures( const CViewSetup *pView, int leafCount, LeafIndex_t* pLeafList );
// Returns the shadow texture
ITexture* GetShadowTexture( unsigned short h );
// Returns shadow information
const ShadowInfo_t& GetShadowInfo( ClientShadowHandle_t h );
// Renders the shadow texture to screen...
void RenderShadowTexture( int w, int h );
// Sets the shadow direction
virtual void SetShadowDirection( const Vector& dir );
const Vector &GetShadowDirection() const;
// Sets the shadow color
virtual void SetShadowColor( unsigned char r, unsigned char g, unsigned char b );
void GetShadowColor( unsigned char *r, unsigned char *g, unsigned char *b ) const;
// Sets the shadow distance
virtual void SetShadowDistance( float flMaxDistance );
float GetShadowDistance( ) const;
// Sets the screen area at which blobby shadows are always used
virtual void SetShadowBlobbyCutoffArea( float flMinArea );
float GetBlobbyCutoffArea( ) const;
// Set the darkness falloff bias
virtual void SetFalloffBias( ClientShadowHandle_t handle, unsigned char ucBias );
void RestoreRenderState();
// Computes a rough bounding box encompassing the volume of the shadow
void ComputeShadowBBox( IClientRenderable *pRenderable, const Vector &vecAbsCenter, float flRadius, Vector *pAbsMins, Vector *pAbsMaxs );
// Returns true if the shadow is far enough to want to use blobby shadows
bool ShouldUseBlobbyShadows( float flRadius, float flScreenArea );
bool WillParentRenderBlobbyShadow( IClientRenderable *pRenderable );
// Are we the child of a shadow with render-to-texture?
bool ShouldUseParentShadow( IClientRenderable *pRenderable );
void SetShadowsDisabled( bool bDisabled )
{
r_shadows_gamecontrol.SetValue( bDisabled != 1 );
}
private:
enum
{
SHADOW_FLAGS_TEXTURE_DIRTY = (CLIENT_SHADOW_FLAGS_LAST_FLAG << 1),
SHADOW_FLAGS_BRUSH_MODEL = (CLIENT_SHADOW_FLAGS_LAST_FLAG << 2),
SHADOW_FLAGS_USING_LOD_SHADOW = (CLIENT_SHADOW_FLAGS_LAST_FLAG << 3),
};
struct ClientShadow_t
{
ClientEntityHandle_t m_Entity;
ShadowHandle_t m_ShadowHandle;
ClientLeafShadowHandle_t m_ClientLeafShadowHandle;
unsigned short m_Flags;
VMatrix m_WorldToShadow;
Vector2D m_WorldSize;
Vector m_LastOrigin;
QAngle m_LastAngles;
TextureHandle_t m_ShadowTexture;
CTextureReference m_ShadowDepthTexture;
int m_nRenderFrame;
EHANDLE m_hTargetEntity;
bool m_bLightWorld;
};
private:
// Shadow update functions
void UpdateStudioShadow( IClientRenderable *pRenderable, ClientShadowHandle_t handle );
void UpdateBrushShadow( IClientRenderable *pRenderable, ClientShadowHandle_t handle );
void UpdateShadow( ClientShadowHandle_t handle, bool force );
// Gets the entity whose shadow this shadow will render into
IClientRenderable *GetParentShadowEntity( ClientShadowHandle_t handle );
// Adds the child bounds to the bounding box
void AddChildBounds( matrix3x4_t &worldToBBox, IClientRenderable* pParent, Vector &vecMins, Vector &vecMaxs );
// Compute a bounds for the entity + children
void ComputeHierarchicalBounds( IClientRenderable *pRenderable, Vector &vecMins, Vector &vecMaxs );
// Builds matrices transforming from world space to shadow space
void BuildGeneralWorldToShadowMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec );
void BuildOrthoWorldToShadowMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec );
void BuildPerspectiveWorldToFlashlightMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec, float fovDegrees,
float zNear, float zFar );
// Update a shadow
void UpdateProjectedTextureInternal( ClientShadowHandle_t handle, bool force );
// Compute the shadow origin and attenuation start distance
float ComputeLocalShadowOrigin( IClientRenderable* pRenderable,
const Vector& mins, const Vector& maxs, const Vector& localShadowDir, float backupFactor, Vector& origin );
// Remove a shadow from the dirty list
void RemoveShadowFromDirtyList( ClientShadowHandle_t handle );
// NOTE: this will ONLY return SHADOWS_NONE, SHADOWS_SIMPLE, or SHADOW_RENDER_TO_TEXTURE.
ShadowType_t GetActualShadowCastType( ClientShadowHandle_t handle ) const;
ShadowType_t GetActualShadowCastType( IClientRenderable *pRenderable ) const;
// Builds a simple blobby shadow
void BuildOrthoShadow( IClientRenderable* pRenderable, ClientShadowHandle_t handle, const Vector& mins, const Vector& maxs);
// Builds a more complex shadow...
void BuildRenderToTextureShadow( IClientRenderable* pRenderable,
ClientShadowHandle_t handle, const Vector& mins, const Vector& maxs );
// Build a projected-texture flashlight
void BuildFlashlight( ClientShadowHandle_t handle );
// Does all the lovely stuff we need to do to have render-to-texture shadows
void SetupRenderToTextureShadow( ClientShadowHandle_t h );
void CleanUpRenderToTextureShadow( ClientShadowHandle_t h );
void CleanUpDepthTextureShadow( ClientShadowHandle_t h );
// Compute the extra shadow planes
void ComputeExtraClipPlanes( IClientRenderable* pRenderable,
ClientShadowHandle_t handle, const Vector* vec,
const Vector& mins, const Vector& maxs, const Vector& localShadowDir );
// Set extra clip planes related to shadows...
void ClearExtraClipPlanes( ClientShadowHandle_t h );
void AddExtraClipPlane( ClientShadowHandle_t h, const Vector& normal, float dist );
// Cull if the origin is on the wrong side of a shadow clip plane....
bool CullReceiver( ClientShadowHandle_t handle, IClientRenderable* pRenderable, IClientRenderable* pSourceRenderable );
bool ComputeSeparatingPlane( IClientRenderable* pRend1, IClientRenderable* pRend2, cplane_t* pPlane );
// Causes all shadows to be re-updated
void UpdateAllShadows();
// One of these gets called with every shadow that potentially will need to re-render
bool DrawRenderToTextureShadow( unsigned short clientShadowHandle, float flArea );
void DrawRenderToTextureShadowLOD( unsigned short clientShadowHandle );
// Draws all children shadows into our own
bool DrawShadowHierarchy( IClientRenderable *pRenderable, const ClientShadow_t &shadow, bool bChild = false );
// Computes + sets the render-to-texture texcoords
void SetRenderToTextureShadowTexCoords( ShadowHandle_t handle, int x, int y, int w, int h );
// Visualization....
void DrawRenderToTextureDebugInfo( IClientRenderable* pRenderable, const Vector& mins, const Vector& maxs );
// Advance frame
void AdvanceFrame();
// Returns renderable-specific shadow info
float GetShadowDistance( IClientRenderable *pRenderable ) const;
const Vector &GetShadowDirection( IClientRenderable *pRenderable ) const;
// Initialize, shutdown render-to-texture shadows
void InitDepthTextureShadows();
void ShutdownDepthTextureShadows();
// Initialize, shutdown render-to-texture shadows
void InitRenderToTextureShadows();
void ShutdownRenderToTextureShadows();
static bool ShadowHandleCompareFunc( const ClientShadowHandle_t& lhs, const ClientShadowHandle_t& rhs )
{
return lhs < rhs;
}
ClientShadowHandle_t CreateProjectedTexture( ClientEntityHandle_t entity, int flags );
// Allocate/deallocate a depth buffer for use by a shadow map
bool AllocateDepthBuffer( CTextureReference &depthBuffer );
void DeallocateDepthBuffer( CTextureReference &depthBuffer );
// Set and clear flashlight target renderable
void SetFlashlightTarget( ClientShadowHandle_t shadowHandle, EHANDLE targetEntity );
// Set flashlight light world flag
void SetFlashlightLightWorld( ClientShadowHandle_t shadowHandle, bool bLightWorld );
bool IsFlashlightTarget( ClientShadowHandle_t shadowHandle, IClientRenderable *pRenderable );
private:
Vector m_SimpleShadowDir;
color32 m_AmbientLightColor;
CMaterialReference m_SimpleShadow;
CMaterialReference m_RenderShadow;
CMaterialReference m_RenderModelShadow;
CUtlLinkedList< ClientShadow_t, ClientShadowHandle_t > m_Shadows;
CTextureAllocator m_ShadowAllocator;
bool m_RenderToTextureActive;
bool m_bRenderTargetNeedsClear;
bool m_bUpdatingDirtyShadows;
float m_flShadowCastDist;
float m_flMinShadowArea;
CUtlRBTree< ClientShadowHandle_t, unsigned short > m_DirtyShadows;
bool m_DepthTextureActive;
CUtlVector< CTextureReference > m_DepthTextureCache;
int m_nMaxDepthTextureShadows;
friend class CVisibleShadowList;
};
//-----------------------------------------------------------------------------
// Singleton
//-----------------------------------------------------------------------------
static CClientShadowMgr s_ClientShadowMgr;
IClientShadowMgr* g_pClientShadowMgr = &s_ClientShadowMgr;
CClientShadowMgr::CClientShadowMgr() :
m_DirtyShadows( 0, 0, ShadowHandleCompareFunc ),
m_DepthTextureActive( false )
{
}
//-----------------------------------------------------------------------------
// Changes the shadow direction...
//-----------------------------------------------------------------------------
static void ShadowDir_f()
{
Vector dir;
if (engine->Cmd_Argc() == 1)
{
Vector dir = s_ClientShadowMgr.GetShadowDirection();
Msg( "%.2f %.2f %.2f\n", dir.x, dir.y, dir.z );
return;
}
if (engine->Cmd_Argc() == 4)
{
dir.x = atof( engine->Cmd_Argv(1) );
dir.y = atof( engine->Cmd_Argv(2) );
dir.z = atof( engine->Cmd_Argv(3) );
s_ClientShadowMgr.SetShadowDirection(dir);
}
}
static void ShadowAngles_f()
{
Vector dir;
QAngle angles;
if (engine->Cmd_Argc() == 1)
{
Vector dir = s_ClientShadowMgr.GetShadowDirection();
QAngle angles;
VectorAngles( dir, angles );
Msg( "%.2f %.2f %.2f\n", angles.x, angles.y, angles.z );
return;
}
if (engine->Cmd_Argc() == 4)
{
angles.x = atof( engine->Cmd_Argv(1) );
angles.y = atof( engine->Cmd_Argv(2) );
angles.z = atof( engine->Cmd_Argv(3) );
AngleVectors( angles, &dir );
s_ClientShadowMgr.SetShadowDirection(dir);
}
}
static void ShadowColor_f()
{
if (engine->Cmd_Argc() == 1)
{
unsigned char r, g, b;
s_ClientShadowMgr.GetShadowColor( &r, &g, &b );
Msg( "Shadow color %d %d %d\n", r, g, b );
return;
}
if (engine->Cmd_Argc() == 4)
{
int r = atoi( engine->Cmd_Argv(1) );
int g = atoi( engine->Cmd_Argv(2) );
int b = atoi( engine->Cmd_Argv(3) );
s_ClientShadowMgr.SetShadowColor(r, g, b);
}
}
static void ShadowDistance_f()
{
if (engine->Cmd_Argc() == 1)
{
float flDist = s_ClientShadowMgr.GetShadowDistance( );
Msg( "Shadow distance %.2f\n", flDist );
return;
}
if (engine->Cmd_Argc() == 2)
{
float flDistance = atof( engine->Cmd_Argv(1) );
s_ClientShadowMgr.SetShadowDistance( flDistance );
}
}
static void ShadowBlobbyCutoff_f()
{
if (engine->Cmd_Argc() == 1)
{
float flArea = s_ClientShadowMgr.GetBlobbyCutoffArea( );
Msg( "Cutoff area %.2f\n", flArea );
return;
}
if (engine->Cmd_Argc() == 2)
{
float flArea = atof( engine->Cmd_Argv(1) );
s_ClientShadowMgr.SetShadowBlobbyCutoffArea( flArea );
}
}
static ConCommand r_shadowdir("r_shadowdir", ShadowDir_f, "Set shadow direction", FCVAR_CHEAT );
static ConCommand r_shadowangles("r_shadowangles", ShadowAngles_f, "Set shadow angles", FCVAR_CHEAT );
static ConCommand r_shadowcolor("r_shadowcolor", ShadowColor_f, "Set shadow color", FCVAR_CHEAT );
static ConCommand r_shadowdist("r_shadowdist", ShadowDistance_f, "Set shadow distance", FCVAR_CHEAT );
static ConCommand r_shadowblobbycutoff("r_shadowblobbycutoff", ShadowBlobbyCutoff_f, "some shadow stuff", FCVAR_CHEAT );
static void ShadowRestoreFunc( int nChangeFlags )
{
s_ClientShadowMgr.RestoreRenderState();
}
//-----------------------------------------------------------------------------
// Initialization, shutdown
//-----------------------------------------------------------------------------
bool CClientShadowMgr::Init()
{
m_bRenderTargetNeedsClear = false;
m_SimpleShadow.Init( "decals/simpleshadow", TEXTURE_GROUP_DECAL );
Vector dir( 0.1, 0.1, -1 );
SetShadowDirection(dir);
SetShadowDistance( 50 );
#ifndef _XBOX
SetShadowBlobbyCutoffArea( 0.005 );
#else
SetShadowBlobbyCutoffArea( 5000 );
#endif
m_nMaxDepthTextureShadows = 4;
if ( r_shadowrendertotexture.GetBool() )
{
InitRenderToTextureShadows();
}
#ifdef DOSHADOWEDFLASHLIGHT
if ( r_flashlightdepthtexture.GetBool() )
{
InitDepthTextureShadows();
}
#endif
materials->AddRestoreFunc( ShadowRestoreFunc );
return true;
}
void CClientShadowMgr::Shutdown()
{
m_SimpleShadow.Shutdown();
m_Shadows.RemoveAll();
ShutdownRenderToTextureShadows();
ShutdownDepthTextureShadows();
materials->RemoveRestoreFunc( ShadowRestoreFunc );
}
//-----------------------------------------------------------------------------
// Initialize, shutdown depth-texture shadows
//-----------------------------------------------------------------------------
void CClientShadowMgr::InitDepthTextureShadows()
{
#ifdef DOSHADOWEDFLASHLIGHT
if( !m_DepthTextureActive )
{
m_DepthTextureActive = true;
materials->BeginRenderTargetAllocation();
m_DepthTextureCache.Purge();
for( int i=0;i<m_nMaxDepthTextureShadows;i++ )
{
CTextureReference depthTex;
depthTex.InitRenderTarget( r_flashlightdepthres.GetInt(), r_flashlightdepthres.GetInt(), RT_SIZE_DEFAULT, IMAGE_FORMAT_RGBA16161616F, MATERIAL_RT_DEPTH_SEPARATE, false );
m_DepthTextureCache.AddToTail( depthTex );
}
materials->EndRenderTargetAllocation();
}
#endif
}
void CClientShadowMgr::ShutdownDepthTextureShadows()
{
if( m_DepthTextureActive )
{
while( m_DepthTextureCache.Count() )
{
m_DepthTextureCache[ m_DepthTextureCache.Count()-1 ].Shutdown();
m_DepthTextureCache.Remove( m_DepthTextureCache.Count()-1 );
}
m_DepthTextureActive = false;
}
}
//-----------------------------------------------------------------------------
// Initialize, shutdown render-to-texture shadows
//-----------------------------------------------------------------------------
void CClientShadowMgr::InitRenderToTextureShadows()
{
if (!m_RenderToTextureActive)
{
m_RenderToTextureActive = true;
m_RenderShadow.Init( "decals/rendershadow", TEXTURE_GROUP_DECAL );
m_RenderModelShadow.Init( "decals/rendermodelshadow", TEXTURE_GROUP_DECAL );
m_ShadowAllocator.Init();
m_ShadowAllocator.Reset();
m_bRenderTargetNeedsClear = true;
float fr = (float)m_AmbientLightColor.r / 255.0f;
float fg = (float)m_AmbientLightColor.g / 255.0f;
float fb = (float)m_AmbientLightColor.b / 255.0f;
m_RenderShadow->ColorModulate( fr, fg, fb );
m_RenderModelShadow->ColorModulate( fr, fg, fb );
// Iterate over all existing textures and allocate shadow textures
for (ClientShadowHandle_t i = m_Shadows.Head(); i != m_Shadows.InvalidIndex(); i = m_Shadows.Next(i) )
{
ClientShadow_t& shadow = m_Shadows[i];
if ( shadow.m_Flags & SHADOW_FLAGS_USE_RENDER_TO_TEXTURE )
{
SetupRenderToTextureShadow( i );
MarkRenderToTextureShadowDirty( i );
// Switch the material to use render-to-texture shadows
shadowmgr->SetShadowMaterial( shadow.m_ShadowHandle, m_RenderShadow, m_RenderModelShadow, (void*)i );
}
}
}
}
void CClientShadowMgr::ShutdownRenderToTextureShadows()
{
if (m_RenderToTextureActive)
{
// Iterate over all existing textures and deallocate shadow textures
for (ClientShadowHandle_t i = m_Shadows.Head(); i != m_Shadows.InvalidIndex(); i = m_Shadows.Next(i) )
{
CleanUpRenderToTextureShadow( i );
// Switch the material to use blobby shadows
ClientShadow_t& shadow = m_Shadows[i];
shadowmgr->SetShadowMaterial( shadow.m_ShadowHandle, m_SimpleShadow, m_SimpleShadow, (void*)CLIENTSHADOW_INVALID_HANDLE );
shadowmgr->SetShadowTexCoord( shadow.m_ShadowHandle, 0, 0, 1, 1 );
ClearExtraClipPlanes( i );
}
m_RenderShadow.Shutdown();
m_RenderModelShadow.Shutdown();
m_ShadowAllocator.DeallocateAllTextures();
m_ShadowAllocator.Shutdown();
// Cause the render target to go away
materials->UncacheUnusedMaterials();
m_RenderToTextureActive = false;
}
}
//-----------------------------------------------------------------------------
// Sets the shadow color
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetShadowColor( unsigned char r, unsigned char g, unsigned char b )
{
float fr = (float)r / 255.0f;
float fg = (float)g / 255.0f;
float fb = (float)b / 255.0f;
// Hook the shadow color into the shadow materials
m_SimpleShadow->ColorModulate( fr, fg, fb );
if (m_RenderToTextureActive)
{
m_RenderShadow->ColorModulate( fr, fg, fb );
m_RenderModelShadow->ColorModulate( fr, fg, fb );
}
m_AmbientLightColor.r = r;
m_AmbientLightColor.g = g;
m_AmbientLightColor.b = b;
}
void CClientShadowMgr::GetShadowColor( unsigned char *r, unsigned char *g, unsigned char *b ) const
{
*r = m_AmbientLightColor.r;
*g = m_AmbientLightColor.g;
*b = m_AmbientLightColor.b;
}
//-----------------------------------------------------------------------------
// Level init... get the shadow color
//-----------------------------------------------------------------------------
void CClientShadowMgr::LevelInitPreEntity()
{
m_bUpdatingDirtyShadows = false;
Vector ambientColor;
engine->GetAmbientLightColor( ambientColor );
ambientColor *= 3;
ambientColor += Vector( 0.3f, 0.3f, 0.3f );
unsigned char r = ambientColor[0] > 1.0 ? 255 : 255 * ambientColor[0];
unsigned char g = ambientColor[1] > 1.0 ? 255 : 255 * ambientColor[1];
unsigned char b = ambientColor[2] > 1.0 ? 255 : 255 * ambientColor[2];
SetShadowColor(r, g, b);
// Set up the texture allocator
if (m_RenderToTextureActive)
{
m_ShadowAllocator.Reset();
m_bRenderTargetNeedsClear = true;
}
}
//-----------------------------------------------------------------------------
// Clean up all shadows
//-----------------------------------------------------------------------------
void CClientShadowMgr::LevelShutdownPostEntity()
{
// All shadows *should* have been cleaned up when the entities went away
// but, just in case....
Assert( m_Shadows.Count() == 0 );
ClientShadowHandle_t h = m_Shadows.Head();
while (h != CLIENTSHADOW_INVALID_HANDLE)
{
ClientShadowHandle_t next = m_Shadows.Next(h);
DestroyShadow( h );
h = next;
}
// Deallocate all textures
if (m_RenderToTextureActive)
{
m_ShadowAllocator.DeallocateAllTextures();
}
r_shadows_gamecontrol.SetValue( -1 );
}
//-----------------------------------------------------------------------------
// Deals with alt-tab
//-----------------------------------------------------------------------------
void CClientShadowMgr::RestoreRenderState()
{
// Mark all shadows dirty; they need to regenerate their state
ClientShadowHandle_t h;
for ( h = m_Shadows.Head(); h != m_Shadows.InvalidIndex(); h = m_Shadows.Next(h) )
{
m_Shadows[h].m_Flags |= SHADOW_FLAGS_TEXTURE_DIRTY;
}
SetShadowColor(m_AmbientLightColor.r, m_AmbientLightColor.g, m_AmbientLightColor.b);
m_bRenderTargetNeedsClear = true;
}
//-----------------------------------------------------------------------------
// Does all the lovely stuff we need to do to have render-to-texture shadows
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetupRenderToTextureShadow( ClientShadowHandle_t h )
{
// First, compute how much texture memory we want to use.
ClientShadow_t& shadow = m_Shadows[h];
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
if ( !pRenderable )
return;
Vector mins, maxs;
pRenderable->GetShadowRenderBounds( mins, maxs, GetActualShadowCastType( h ) );
// Compute the maximum dimension
Vector size;
VectorSubtract( maxs, mins, size );
Fixed conflict between min/max macros and std::min/max when using GCC >= 4.2.
2011-04-28 01:29:22 -05:00
float maxSize = MAX( size.x, size.y );
maxSize = MAX( maxSize, size.z );
Added most recent version of unmodified HL2 SDK for Episode 1 engine
2008-09-15 01:00:17 -05:00
// Figure out the texture size
// For now, we're going to assume a fixed number of shadow texels
// per shadow-caster size; add in some extra space at the boundary.
int texelCount = TEXEL_SIZE_PER_CASTER_SIZE * maxSize;
// Pick the first power of 2 larger...
int textureSize = 1;
while (textureSize < texelCount)
{
textureSize <<= 1;
}
shadow.m_ShadowTexture = m_ShadowAllocator.AllocateTexture( textureSize, textureSize );
}
void CClientShadowMgr::CleanUpRenderToTextureShadow( ClientShadowHandle_t h )
{
ClientShadow_t& shadow = m_Shadows[h];
if (m_RenderToTextureActive && (shadow.m_Flags & SHADOW_FLAGS_USE_RENDER_TO_TEXTURE))
{
m_ShadowAllocator.DeallocateTexture( shadow.m_ShadowTexture );
shadow.m_ShadowTexture = INVALID_TEXTURE_HANDLE;
}
}
void CClientShadowMgr::CleanUpDepthTextureShadow( ClientShadowHandle_t h )
{
ClientShadow_t& shadow = m_Shadows[h];
if( m_DepthTextureActive && (shadow.m_Flags & SHADOW_FLAGS_USE_DEPTH_TEXTURE ) )
{
DeallocateDepthBuffer( shadow.m_ShadowDepthTexture );
}
}
//-----------------------------------------------------------------------------
// Causes all shadows to be re-updated
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateAllShadows()
{
m_bUpdatingDirtyShadows = true;
for (ClientShadowHandle_t i = m_Shadows.Head(); i != m_Shadows.InvalidIndex(); i = m_Shadows.Next(i) )
{
UpdateProjectedTextureInternal( i, true );
}
m_DirtyShadows.RemoveAll();
m_bUpdatingDirtyShadows = false;
}
//-----------------------------------------------------------------------------
// Sets the shadow direction
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetShadowDirection( const Vector& dir )
{
VectorCopy( dir, m_SimpleShadowDir );
VectorNormalize( m_SimpleShadowDir );
if ( m_RenderToTextureActive )
{
UpdateAllShadows();
}
}
const Vector &CClientShadowMgr::GetShadowDirection() const
{
// This will cause blobby shadows to always project straight down
static Vector s_vecDown( 0, 0, -1 );
if ( !m_RenderToTextureActive )
return s_vecDown;
return m_SimpleShadowDir;
}
//-----------------------------------------------------------------------------
// Gets shadow information for a particular renderable
//-----------------------------------------------------------------------------
float CClientShadowMgr::GetShadowDistance( IClientRenderable *pRenderable ) const
{
float flDist = m_flShadowCastDist;
// Allow the renderable to override the default
pRenderable->GetShadowCastDistance( &flDist, GetActualShadowCastType( pRenderable ) );
return flDist;
}
const Vector &CClientShadowMgr::GetShadowDirection( IClientRenderable *pRenderable ) const
{
Vector &vecResult = AllocTempVector();
vecResult = GetShadowDirection();
// Allow the renderable to override the default
pRenderable->GetShadowCastDirection( &vecResult, GetActualShadowCastType( pRenderable ) );
return vecResult;
}
//-----------------------------------------------------------------------------
// Sets the shadow distance
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetShadowDistance( float flMaxDistance )
{
m_flShadowCastDist = flMaxDistance;
UpdateAllShadows();
}
float CClientShadowMgr::GetShadowDistance( ) const
{
return m_flShadowCastDist;
}
//-----------------------------------------------------------------------------
// Sets the screen area at which blobby shadows are always used
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetShadowBlobbyCutoffArea( float flMinArea )
{
m_flMinShadowArea = flMinArea;
}
float CClientShadowMgr::GetBlobbyCutoffArea( ) const
{
return m_flMinShadowArea;
}
//-----------------------------------------------------------------------------
// Purpose:
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetFalloffBias( ClientShadowHandle_t handle, unsigned char ucBias )
{
shadowmgr->SetFalloffBias( m_Shadows[handle].m_ShadowHandle, ucBias );
}
//-----------------------------------------------------------------------------
// Returns the shadow texture
//-----------------------------------------------------------------------------
ITexture* CClientShadowMgr::GetShadowTexture( unsigned short h )
{
return m_ShadowAllocator.GetTexture();
}
//-----------------------------------------------------------------------------
// Returns information needed by the model proxy
//-----------------------------------------------------------------------------
const ShadowInfo_t& CClientShadowMgr::GetShadowInfo( ClientShadowHandle_t h )
{
return shadowmgr->GetInfo( m_Shadows[h].m_ShadowHandle );
}
//-----------------------------------------------------------------------------
// Renders the shadow texture to screen...
//-----------------------------------------------------------------------------
void CClientShadowMgr::RenderShadowTexture( int w, int h )
{
if (m_RenderToTextureActive)
{
float flTexWidth, flTexHeight;
#ifdef _XBOX
// xboxissue - need non-normalized texture coords
int textureW, textureH;
m_ShadowAllocator.GetTotalTextureSize( textureW, textureH );
flTexWidth = textureW;
flTexHeight = textureH;
#else
flTexWidth = 1.0f;
flTexHeight = 1.0f;
#endif
materials->Bind( m_RenderShadow );
IMesh* pMesh = materials->GetDynamicMesh( true );
CMeshBuilder meshBuilder;
meshBuilder.Begin( pMesh, MATERIAL_QUADS, 1 );
meshBuilder.Position3f( 0.0f, 0.0f, 0.0f );
meshBuilder.TexCoord2f( 0, 0.0f, 0.0f );
meshBuilder.Color4ub( 0, 0, 0, 0 );
meshBuilder.AdvanceVertex();
meshBuilder.Position3f( w, 0.0f, 0.0f );
meshBuilder.TexCoord2f( 0, flTexWidth, 0.0f );
meshBuilder.Color4ub( 0, 0, 0, 0 );
meshBuilder.AdvanceVertex();
meshBuilder.Position3f( w, h, 0.0f );
meshBuilder.TexCoord2f( 0, flTexWidth, flTexHeight );
meshBuilder.Color4ub( 0, 0, 0, 0 );
meshBuilder.AdvanceVertex();
meshBuilder.Position3f( 0.0f, h, 0.0f );
meshBuilder.TexCoord2f( 0, 0.0f, flTexHeight );
meshBuilder.Color4ub( 0, 0, 0, 0 );
meshBuilder.AdvanceVertex();
meshBuilder.End();
pMesh->Draw();
}
}
//-----------------------------------------------------------------------------
// Create/destroy a shadow
//-----------------------------------------------------------------------------
ClientShadowHandle_t CClientShadowMgr::CreateProjectedTexture( ClientEntityHandle_t entity, int flags )
{
// We need to know if it's a brush model for shadows
if( !( flags & SHADOW_FLAGS_FLASHLIGHT ) )
{
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( entity );
int modelType = modelinfo->GetModelType( pRenderable->GetModel() );
if (modelType == mod_brush)
{
flags |= SHADOW_FLAGS_BRUSH_MODEL;
}
}
ClientShadowHandle_t h = m_Shadows.AddToTail();
ClientShadow_t& shadow = m_Shadows[h];
shadow.m_Entity = entity;
shadow.m_ClientLeafShadowHandle = ClientLeafSystem()->AddShadow( h, flags );
shadow.m_Flags = flags;
shadow.m_nRenderFrame = -1;
shadow.m_LastOrigin.Init( FLT_MAX, FLT_MAX, FLT_MAX );
shadow.m_LastAngles.Init( FLT_MAX, FLT_MAX, FLT_MAX );
Assert( ( ( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT ) == 0 ) !=
( ( shadow.m_Flags & SHADOW_FLAGS_SHADOW ) == 0 ) );
// Set up the flags....
IMaterial* pShadowMaterial = m_SimpleShadow;
IMaterial* pShadowModelMaterial = m_SimpleShadow;
void* pShadowProxyData = (void*)CLIENTSHADOW_INVALID_HANDLE;
if ( m_RenderToTextureActive && (flags & SHADOW_FLAGS_USE_RENDER_TO_TEXTURE) )
{
SetupRenderToTextureShadow(h);
pShadowMaterial = m_RenderShadow;
pShadowModelMaterial = m_RenderModelShadow;
pShadowProxyData = (void*)h;
}
if( flags & SHADOW_FLAGS_USE_DEPTH_TEXTURE )
{
// This should be changed to handle the error more gracefully
AllocateDepthBuffer( shadow.m_ShadowDepthTexture );
pShadowMaterial = m_RenderShadow;
pShadowModelMaterial = m_RenderModelShadow;
pShadowProxyData = (void*)h;
}
int createShadowFlags;
if( flags & SHADOW_FLAGS_FLASHLIGHT )
{
// don't use SHADOW_CACHE_VERTS with projective lightsources since we expect that they will change every frame.
// FIXME: might want to make it cache optionally if it's an entity light that is static.
createShadowFlags = SHADOW_FLASHLIGHT;
}
else
{
createShadowFlags = SHADOW_CACHE_VERTS;
}
shadow.m_ShadowHandle = shadowmgr->CreateShadowEx( pShadowMaterial, pShadowModelMaterial, pShadowProxyData, createShadowFlags, shadow.m_ShadowDepthTexture );
return h;
}
ClientShadowHandle_t CClientShadowMgr::CreateFlashlight( const FlashlightState_t &lightState )
{
// We don't really need a model entity handle for a projective light source, so use an invalid one.
static ClientEntityHandle_t invalidHandle = INVALID_CLIENTENTITY_HANDLE;
int shadowFlags = SHADOW_FLAGS_FLASHLIGHT;
#ifdef DOSHADOWEDFLASHLIGHT
if( lightState.m_bEnableShadows && r_flashlightdepthtexture.GetBool() )
shadowFlags |= SHADOW_FLAGS_USE_DEPTH_TEXTURE;
#endif
ClientShadowHandle_t shadowHandle = CreateProjectedTexture( invalidHandle, shadowFlags );
m_Shadows[ shadowHandle ].m_bLightWorld = true;
UpdateFlashlightState( shadowHandle, lightState );
UpdateProjectedTexture( shadowHandle, true );
return shadowHandle;
}
ClientShadowHandle_t CClientShadowMgr::CreateShadow( ClientEntityHandle_t entity, int flags )
{
// We don't really need a model entity handle for a projective light source, so use an invalid one.
flags &= ~SHADOW_FLAGS_PROJECTED_TEXTURE_TYPE_MASK;
flags |= SHADOW_FLAGS_SHADOW | SHADOW_FLAGS_TEXTURE_DIRTY;
ClientShadowHandle_t shadowHandle = CreateProjectedTexture( entity, flags );
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( entity );
if ( pRenderable )
{
Assert( !pRenderable->IsShadowDirty( ) );
pRenderable->MarkShadowDirty( true );
}
// NOTE: We *have * to call the version that takes a shadow handle
// even if we have an entity because this entity hasn't set its shadow handle yet
AddToDirtyShadowList( shadowHandle, true );
return shadowHandle;
}
//-----------------------------------------------------------------------------
// Updates the flashlight direction and re-computes surfaces it should lie on
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateFlashlightState( ClientShadowHandle_t shadowHandle, const FlashlightState_t &flashlightState )
{
Vector lightXVec;
Vector lightYVec( 0.0f, 0.0f, 1.0f );
if( fabs( DotProduct( lightYVec, flashlightState.m_vecLightDirection ) ) > 0.9f )
{
// Don't want lightYVec and m_vecLightDirection to be parallel
lightYVec.Init( 0.0f, 1.0f, 0.0f );
}
CrossProduct( lightYVec, flashlightState.m_vecLightDirection, lightXVec );
VectorNormalize( lightXVec );
CrossProduct( flashlightState.m_vecLightDirection, lightXVec, lightYVec );
VectorNormalize( lightYVec );
BuildPerspectiveWorldToFlashlightMatrix( m_Shadows[shadowHandle].m_WorldToShadow, flashlightState.m_vecLightOrigin, flashlightState.m_vecLightDirection,
lightXVec, lightYVec, flashlightState.m_fVerticalFOVDegrees, flashlightState.m_NearZ, flashlightState.m_FarZ );
shadowmgr->UpdateFlashlightStateEx( m_Shadows[shadowHandle].m_ShadowHandle, flashlightState, m_Shadows[shadowHandle].m_ShadowDepthTexture );
}
void CClientShadowMgr::DestroyFlashlight( ClientShadowHandle_t shadowHandle )
{
DestroyShadow( shadowHandle );
}
//-----------------------------------------------------------------------------
// Remove a shadow from the dirty list
//-----------------------------------------------------------------------------
void CClientShadowMgr::RemoveShadowFromDirtyList( ClientShadowHandle_t handle )
{
int idx = m_DirtyShadows.Find( handle );
if ( idx != m_DirtyShadows.InvalidIndex() )
{
// Clean up the shadow update bit.
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( m_Shadows[handle].m_Entity );
if ( pRenderable )
{
pRenderable->MarkShadowDirty( false );
}
m_DirtyShadows.RemoveAt( idx );
}
}
//-----------------------------------------------------------------------------
// Remove a shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::DestroyShadow( ClientShadowHandle_t handle )
{
Assert( m_Shadows.IsValidIndex(handle) );
RemoveShadowFromDirtyList( handle );
shadowmgr->DestroyShadow( m_Shadows[handle].m_ShadowHandle );
ClientLeafSystem()->RemoveShadow( m_Shadows[handle].m_ClientLeafShadowHandle );
CleanUpRenderToTextureShadow( handle );
CleanUpDepthTextureShadow( handle );
m_Shadows.Remove(handle);
}
//-----------------------------------------------------------------------------
// Build the worldtotexture matrix
//-----------------------------------------------------------------------------
void CClientShadowMgr::BuildGeneralWorldToShadowMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec )
{
// We're assuming here that xvec + yvec aren't necessary perpendicular
// The shadow->world matrix is pretty simple:
// Just stick the origin in the translation component
// and the vectors in the columns...
worldToShadow.SetBasisVectors( xvec, yvec, dir );
worldToShadow.SetTranslation( origin );
worldToShadow[3][0] = worldToShadow[3][1] = worldToShadow[3][2] = 0.0f;
worldToShadow[3][3] = 1.0f;
// Now do a general inverse to get worldToShadow
MatrixInverseGeneral( worldToShadow, worldToShadow );
}
void CClientShadowMgr::BuildOrthoWorldToShadowMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec )
{
// This version is faster and assumes dir, xvec, yvec are perpendicular
AssertFloatEquals( DotProduct( dir, xvec ), 0.0f, 1e-3 );
AssertFloatEquals( DotProduct( dir, yvec ), 0.0f, 1e-3 );
AssertFloatEquals( DotProduct( xvec, yvec ), 0.0f, 1e-3 );
// The shadow->world matrix is pretty simple:
// Just stick the origin in the translation component
// and the vectors in the columns...
// The inverse of this transposes the rotational component
// and the translational component = - (rotation transpose) * origin
worldToShadow.SetBasisVectors( xvec, yvec, dir );
MatrixTranspose( worldToShadow, worldToShadow );
Vector translation;
Vector3DMultiply( worldToShadow, origin, translation );
translation *= -1.0f;
worldToShadow.SetTranslation( translation );
// The the bottom row.
worldToShadow[3][0] = worldToShadow[3][1] = worldToShadow[3][2] = 0.0f;
worldToShadow[3][3] = 1.0f;
}
void CClientShadowMgr::BuildPerspectiveWorldToFlashlightMatrix( VMatrix& worldToShadow,
const Vector& origin, const Vector& dir, const Vector& xvec, const Vector& yvec, float fovDegrees,
float zNear, float zFar )
{
// build the ortho shadow matrix to get us from world to shadow space. We'll build the perspective
// part separately and concatenate.
VMatrix worldToShadowView;
BuildOrthoWorldToShadowMatrix( worldToShadowView, origin, dir, xvec, yvec );
VMatrix perspective;
MatrixBuildPerspective( perspective, fovDegrees, fovDegrees, zNear, zFar );
MatrixMultiply( perspective, worldToShadowView, worldToShadow );
}
//-----------------------------------------------------------------------------
// Compute the shadow origin and attenuation start distance
//-----------------------------------------------------------------------------
float CClientShadowMgr::ComputeLocalShadowOrigin( IClientRenderable* pRenderable,
const Vector& mins, const Vector& maxs, const Vector& localShadowDir, float backupFactor, Vector& origin )
{
// Compute the centroid of the object...
Vector vecCentroid;
VectorAdd( mins, maxs, vecCentroid );
vecCentroid *= 0.5f;
Vector vecSize;
VectorSubtract( maxs, mins, vecSize );
float flRadius = vecSize.Length() * 0.5f;
// NOTE: The *origin* of the shadow cast is a point on a line passing through
// the centroid of the caster. The direction of this line is the shadow cast direction,
// and the point on that line corresponds to the endpoint of the box that is
// furthest *back* along the shadow direction
// For the first point at which the shadow could possibly start falling off,
// we need to use the point at which the ray described above leaves the
// bounding sphere surrounding the entity. This is necessary because otherwise,
// tall, thin objects would have their shadows appear + disappear as then spun about their origin
// Figure out the corner corresponding to the min + max projection
// along the shadow direction
// We're basically finding the point on the cube that has the largest and smallest
// dot product with the local shadow dir. Then we're taking the dot product
// of that with the localShadowDir. lastly, we're subtracting out the
// centroid projection to give us a distance along the localShadowDir to
// the front and back of the cube along the direction of the ray.
float centroidProjection = DotProduct( vecCentroid, localShadowDir );
float minDist = -centroidProjection;
for (int i = 0; i < 3; ++i)
{
if ( localShadowDir[i] > 0.0f )
{
minDist += localShadowDir[i] * mins[i];
}
else
{
minDist += localShadowDir[i] * maxs[i];
}
}
minDist *= backupFactor;
VectorMA( vecCentroid, minDist, localShadowDir, origin );
return flRadius - minDist;
}
//-----------------------------------------------------------------------------
// Sorts the components of a vector
//-----------------------------------------------------------------------------
static inline void SortAbsVectorComponents( const Vector& src, int* pVecIdx )
{
Vector absVec( fabs(src[0]), fabs(src[1]), fabs(src[2]) );
int maxIdx = (absVec[0] > absVec[1]) ? 0 : 1;
if (absVec[2] > absVec[maxIdx])
{
maxIdx = 2;
}
// always choose something right-handed....
switch( maxIdx )
{
case 0:
pVecIdx[0] = 1;
pVecIdx[1] = 2;
pVecIdx[2] = 0;
break;
case 1:
pVecIdx[0] = 2;
pVecIdx[1] = 0;
pVecIdx[2] = 1;
break;
case 2:
pVecIdx[0] = 0;
pVecIdx[1] = 1;
pVecIdx[2] = 2;
break;
}
}
//-----------------------------------------------------------------------------
// Build the worldtotexture matrix
//-----------------------------------------------------------------------------
static void BuildWorldToTextureMatrix( const VMatrix& worldToShadow,
const Vector2D& size, VMatrix& worldToTexture )
{
// Build a matrix that maps from shadow space to (u,v) coordinates
VMatrix shadowToUnit;
MatrixBuildScale( shadowToUnit, 1.0f / size.x, 1.0f / size.y, 1.0f );
shadowToUnit[0][3] = shadowToUnit[1][3] = 0.5f;
// Store off the world to (u,v) transformation
MatrixMultiply( shadowToUnit, worldToShadow, worldToTexture );
}
//-----------------------------------------------------------------------------
// Set extra clip planes related to shadows...
//-----------------------------------------------------------------------------
void CClientShadowMgr::ClearExtraClipPlanes( ClientShadowHandle_t h )
{
shadowmgr->ClearExtraClipPlanes( m_Shadows[h].m_ShadowHandle );
}
void CClientShadowMgr::AddExtraClipPlane( ClientShadowHandle_t h, const Vector& normal, float dist )
{
shadowmgr->AddExtraClipPlane( m_Shadows[h].m_ShadowHandle, normal, dist );
}
//-----------------------------------------------------------------------------
// Compute the extra shadow planes
//-----------------------------------------------------------------------------
void CClientShadowMgr::ComputeExtraClipPlanes( IClientRenderable* pRenderable,
ClientShadowHandle_t handle, const Vector* vec,
const Vector& mins, const Vector& maxs, const Vector& localShadowDir )
{
// Compute the world-space position of the corner of the bounding box
// that's got the highest dotproduct with the local shadow dir...
Vector origin = pRenderable->GetRenderOrigin( );
float dir[3];
int i;
for ( i = 0; i < 3; ++i )
{
if (localShadowDir[i] < 0.0f)
{
VectorMA( origin, maxs[i], vec[i], origin );
dir[i] = 1;
}
else
{
VectorMA( origin, mins[i], vec[i], origin );
dir[i] = -1;
}
}
// Now that we have it, create 3 planes...
Vector normal;
ClearExtraClipPlanes(handle);
for ( i = 0; i < 3; ++i )
{
VectorMultiply( vec[i], dir[i], normal );
float dist = DotProduct( normal, origin );
AddExtraClipPlane( handle, normal, dist );
}
}
inline ShadowType_t CClientShadowMgr::GetActualShadowCastType( ClientShadowHandle_t handle ) const
{
if ( handle == CLIENTSHADOW_INVALID_HANDLE )
{
return SHADOWS_NONE;
}
if ( m_Shadows[handle].m_Flags & SHADOW_FLAGS_USE_RENDER_TO_TEXTURE )
{
return ( m_RenderToTextureActive ? SHADOWS_RENDER_TO_TEXTURE : SHADOWS_SIMPLE );
}
else if( m_Shadows[handle].m_Flags & SHADOW_FLAGS_USE_DEPTH_TEXTURE )
{
return SHADOWS_RENDER_TO_DEPTH_TEXTURE;
}
else
{
return SHADOWS_SIMPLE;
}
}
inline ShadowType_t CClientShadowMgr::GetActualShadowCastType( IClientRenderable *pEnt ) const
{
return GetActualShadowCastType( pEnt->GetShadowHandle() );
}
//-----------------------------------------------------------------------------
// Builds a simple blobby shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::BuildOrthoShadow( IClientRenderable* pRenderable,
ClientShadowHandle_t handle, const Vector& mins, const Vector& maxs)
{
// Get the object's basis
Vector vec[3];
AngleVectors( pRenderable->GetRenderAngles(), &vec[0], &vec[1], &vec[2] );
vec[1] *= -1.0f;
Vector vecShadowDir = GetShadowDirection( pRenderable );
// Project the shadow casting direction into the space of the object
Vector localShadowDir;
localShadowDir[0] = DotProduct( vec[0], vecShadowDir );
localShadowDir[1] = DotProduct( vec[1], vecShadowDir );
localShadowDir[2] = DotProduct( vec[2], vecShadowDir );
// Figure out which vector has the largest component perpendicular
// to the shadow handle...
// Sort by how perpendicular it is
int vecIdx[3];
SortAbsVectorComponents( localShadowDir, vecIdx );
// Here's our shadow basis vectors; namely the ones that are
// most perpendicular to the shadow casting direction
Vector xvec = vec[vecIdx[0]];
Vector yvec = vec[vecIdx[1]];
// Project them into a plane perpendicular to the shadow direction
xvec -= vecShadowDir * DotProduct( vecShadowDir, xvec );
yvec -= vecShadowDir * DotProduct( vecShadowDir, yvec );
VectorNormalize( xvec );
VectorNormalize( yvec );
// Compute the box size
Vector boxSize;
VectorSubtract( maxs, mins, boxSize );
// We project the two longest sides into the vectors perpendicular
// to the projection direction, then add in the projection of the perp direction
Vector2D size( boxSize[vecIdx[0]], boxSize[vecIdx[1]] );
size.x *= fabs( DotProduct( vec[vecIdx[0]], xvec ) );
size.y *= fabs( DotProduct( vec[vecIdx[1]], yvec ) );
// Add the third component into x and y
size.x += boxSize[vecIdx[2]] * fabs( DotProduct( vec[vecIdx[2]], xvec ) );
size.y += boxSize[vecIdx[2]] * fabs( DotProduct( vec[vecIdx[2]], yvec ) );
// Bloat a bit, since the shadow wants to extend outside the model a bit
size.x += 10.0f;
size.y += 10.0f;
// Clamp the minimum size
Vector2DMax( size, Vector2D(10.0f, 10.0f), size );
// Place the origin at the point with min dot product with shadow dir
Vector org;
float falloffStart = ComputeLocalShadowOrigin( pRenderable, mins, maxs, localShadowDir, 2.0f, org );
// Transform the local origin into world coordinates
Vector worldOrigin = pRenderable->GetRenderOrigin( );
VectorMA( worldOrigin, org.x, vec[0], worldOrigin );
VectorMA( worldOrigin, org.y, vec[1], worldOrigin );
VectorMA( worldOrigin, org.z, vec[2], worldOrigin );
// FUNKY: A trick to reduce annoying texelization artifacts!?
float dx = 1.0f / TEXEL_SIZE_PER_CASTER_SIZE;
worldOrigin.x = (int)(worldOrigin.x / dx) * dx;
worldOrigin.y = (int)(worldOrigin.y / dx) * dx;
worldOrigin.z = (int)(worldOrigin.z / dx) * dx;
// NOTE: We gotta use the general matrix because xvec and yvec aren't perp
VMatrix worldToShadow, worldToTexture;
BuildGeneralWorldToShadowMatrix( m_Shadows[handle].m_WorldToShadow, worldOrigin, vecShadowDir, xvec, yvec );
BuildWorldToTextureMatrix( m_Shadows[handle].m_WorldToShadow, size, worldToTexture );
Vector2DCopy( size, m_Shadows[handle].m_WorldSize );
// Compute the falloff attenuation
// Area computation isn't exact since xvec is not perp to yvec, but close enough
// float shadowArea = size.x * size.y;
// The entity may be overriding our shadow cast distance
float flShadowCastDistance = GetShadowDistance( pRenderable );
float maxHeight = flShadowCastDistance + falloffStart; //3.0f * sqrt( shadowArea );
shadowmgr->ProjectShadow( m_Shadows[handle].m_ShadowHandle, worldOrigin,
vecShadowDir, worldToTexture, size, maxHeight, falloffStart, MAX_FALLOFF_AMOUNT, pRenderable->GetRenderOrigin() );
// Compute extra clip planes to prevent poke-thru
// FIXME!!!!!!!!!!!!!! Removing this for now since it seems to mess up the blobby shadows.
// ComputeExtraClipPlanes( pEnt, handle, vec, mins, maxs, localShadowDir );
// Add the shadow to the client leaf system so it correctly marks
// leafs as being affected by a particular shadow
ClientLeafSystem()->ProjectShadow( m_Shadows[handle].m_ClientLeafShadowHandle,
worldOrigin, vecShadowDir, size, maxHeight );
}
//-----------------------------------------------------------------------------
// Visualization....
//-----------------------------------------------------------------------------
void CClientShadowMgr::DrawRenderToTextureDebugInfo( IClientRenderable* pRenderable, const Vector& mins, const Vector& maxs )
{
// Get the object's basis
Vector vec[3];
AngleVectors( pRenderable->GetRenderAngles(), &vec[0], &vec[1], &vec[2] );
vec[1] *= -1.0f;
Vector vecSize;
VectorSubtract( maxs, mins, vecSize );
Vector vecOrigin = pRenderable->GetRenderOrigin();
Vector start, end, end2;
VectorMA( vecOrigin, mins.x, vec[0], start );
VectorMA( start, mins.y, vec[1], start );
VectorMA( start, mins.z, vec[2], start );
VectorMA( start, vecSize.x, vec[0], end );
VectorMA( end, vecSize.z, vec[2], end2 );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
debugoverlay->AddLineOverlay( end2, end, 255, 0, 0, true, 0.01 );
VectorMA( start, vecSize.y, vec[1], end );
VectorMA( end, vecSize.z, vec[2], end2 );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
debugoverlay->AddLineOverlay( end2, end, 255, 0, 0, true, 0.01 );
VectorMA( start, vecSize.z, vec[2], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
start = end;
VectorMA( start, vecSize.x, vec[0], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
VectorMA( start, vecSize.y, vec[1], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
VectorMA( end, vecSize.x, vec[0], start );
VectorMA( start, -vecSize.x, vec[0], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
VectorMA( start, -vecSize.y, vec[1], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
VectorMA( start, -vecSize.z, vec[2], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
start = end;
VectorMA( start, -vecSize.x, vec[0], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
VectorMA( start, -vecSize.y, vec[1], end );
debugoverlay->AddLineOverlay( start, end, 255, 0, 0, true, 0.01 );
C_BaseEntity *pEnt = pRenderable->GetIClientUnknown()->GetBaseEntity();
if ( pEnt )
{
debugoverlay->AddTextOverlay( vecOrigin, 0, "%d", pEnt->entindex() );
}
else
{
debugoverlay->AddTextOverlay( vecOrigin, 0, "%X", (size_t)pRenderable );
}
}
//-----------------------------------------------------------------------------
// Builds a more complex shadow...
//-----------------------------------------------------------------------------
void CClientShadowMgr::BuildRenderToTextureShadow( IClientRenderable* pRenderable,
ClientShadowHandle_t handle, const Vector& mins, const Vector& maxs)
{
// DrawRenderToTextureDebugInfo( pRenderable, mins, maxs );
// Get the object's basis
Vector vec[3];
AngleVectors( pRenderable->GetRenderAngles(), &vec[0], &vec[1], &vec[2] );
vec[1] *= -1.0f;
Vector vecShadowDir = GetShadowDirection( pRenderable );
// Project the shadow casting direction into the space of the object
Vector localShadowDir;
localShadowDir[0] = DotProduct( vec[0], vecShadowDir );
localShadowDir[1] = DotProduct( vec[1], vecShadowDir );
localShadowDir[2] = DotProduct( vec[2], vecShadowDir );
// Figure out which vector has the largest component perpendicular
// to the shadow handle...
// Sort by how perpendicular it is
int vecIdx[3];
SortAbsVectorComponents( localShadowDir, vecIdx );
// Here's our shadow basis vectors; namely the ones that are
// most perpendicular to the shadow casting direction
Vector yvec = vec[vecIdx[0]];
// Project it into a plane perpendicular to the shadow direction
yvec -= vecShadowDir * DotProduct( vecShadowDir, yvec );
VectorNormalize( yvec );
// Compute the x vector
Vector xvec;
CrossProduct( yvec, vecShadowDir, xvec );
// Compute the box size
Vector boxSize;
VectorSubtract( maxs, mins, boxSize );
// We project the two longest sides into the vectors perpendicular
// to the projection direction, then add in the projection of the perp direction
Vector2D size;
size.x = boxSize.x * fabs( DotProduct( vec[0], xvec ) ) +
boxSize.y * fabs( DotProduct( vec[1], xvec ) ) +
boxSize.z * fabs( DotProduct( vec[2], xvec ) );
size.y = boxSize.x * fabs( DotProduct( vec[0], yvec ) ) +
boxSize.y * fabs( DotProduct( vec[1], yvec ) ) +
boxSize.z * fabs( DotProduct( vec[2], yvec ) );
size.x += 2.0f * TEXEL_SIZE_PER_CASTER_SIZE;
size.y += 2.0f * TEXEL_SIZE_PER_CASTER_SIZE;
// Place the origin at the point with min dot product with shadow dir
Vector org;
float falloffStart = ComputeLocalShadowOrigin( pRenderable, mins, maxs, localShadowDir, 1.0f, org );
// Transform the local origin into world coordinates
Vector worldOrigin = pRenderable->GetRenderOrigin( );
VectorMA( worldOrigin, org.x, vec[0], worldOrigin );
VectorMA( worldOrigin, org.y, vec[1], worldOrigin );
VectorMA( worldOrigin, org.z, vec[2], worldOrigin );
VMatrix worldToTexture;
BuildOrthoWorldToShadowMatrix( m_Shadows[handle].m_WorldToShadow, worldOrigin, vecShadowDir, xvec, yvec );
BuildWorldToTextureMatrix( m_Shadows[handle].m_WorldToShadow, size, worldToTexture );
Vector2DCopy( size, m_Shadows[handle].m_WorldSize );
// Compute the falloff attenuation
// Area computation isn't exact since xvec is not perp to yvec, but close enough
// Extra factor of 4 in the maxHeight due to the size being half as big
// float shadowArea = size.x * size.y;
// The entity may be overriding our shadow cast distance
float flShadowCastDistance = GetShadowDistance( pRenderable );
float maxHeight = flShadowCastDistance + falloffStart; //3.0f * sqrt( shadowArea );
shadowmgr->ProjectShadow( m_Shadows[handle].m_ShadowHandle, worldOrigin,
vecShadowDir, worldToTexture, size, maxHeight, falloffStart, MAX_FALLOFF_AMOUNT, pRenderable->GetRenderOrigin() );
// Compute extra clip planes to prevent poke-thru
ComputeExtraClipPlanes( pRenderable, handle, vec, mins, maxs, localShadowDir );
// Add the shadow to the client leaf system so it correctly marks
// leafs as being affected by a particular shadow
ClientLeafSystem()->ProjectShadow( m_Shadows[handle].m_ClientLeafShadowHandle,
worldOrigin, vecShadowDir, size, maxHeight );
}
static void LineDrawHelper( const Vector &startShadowSpace, const Vector &endShadowSpace,
const VMatrix &shadowToWorld, unsigned char r = 255, unsigned char g = 255,
unsigned char b = 255 )
{
Vector startWorldSpace, endWorldSpace;
Vector3DMultiplyPositionProjective( shadowToWorld, startShadowSpace, startWorldSpace );
Vector3DMultiplyPositionProjective( shadowToWorld, endShadowSpace, endWorldSpace );
debugoverlay->AddLineOverlay( startWorldSpace + Vector( 0.0f, 0.0f, 1.0f ),
endWorldSpace + Vector( 0.0f, 0.0f, 1.0f ), r, g, b, false
, 0.0 );
}
static void DebugDrawFrustum( const VMatrix &worldToFlashlight )
{
VMatrix flashlightToWorld;
MatrixInverseGeneral( worldToFlashlight, flashlightToWorld );
LineDrawHelper( Vector( 0.0f, 0.0f, 0.0f ), Vector( 0.0f, 0.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 0.0f, 1.0f ), Vector( 0.0f, 1.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 1.0f, 1.0f ), Vector( 0.0f, 1.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 1.0f, 0.0f ), Vector( 0.0f, 0.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 1.0f, 0.0f, 0.0f ), Vector( 1.0f, 0.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 1.0f, 0.0f, 1.0f ), Vector( 1.0f, 1.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 1.0f, 1.0f, 1.0f ), Vector( 1.0f, 1.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 1.0f, 1.0f, 0.0f ), Vector( 1.0f, 0.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 0.0f, 0.0f ), Vector( 1.0f, 0.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 0.0f, 1.0f ), Vector( 1.0f, 0.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 1.0f, 1.0f ), Vector( 1.0f, 1.0f, 1.0f ), flashlightToWorld, 255, 0, 0 );
LineDrawHelper( Vector( 0.0f, 1.0f, 0.0f ), Vector( 1.0f, 1.0f, 0.0f ), flashlightToWorld, 255, 0, 0 );
}
void CClientShadowMgr::BuildFlashlight( ClientShadowHandle_t handle )
{
ClientShadow_t &shadow = m_Shadows[handle];
if( r_flashlightdrawfrustum.GetBool() )
{
DebugDrawFrustum( shadow.m_WorldToShadow );
}
if( shadow.m_bLightWorld )
{
shadowmgr->ProjectFlashlight( shadow.m_ShadowHandle, shadow.m_WorldToShadow );
}
else
{
// This should clear all models and surfaces from this shadow
shadowmgr->EnableShadow( shadow.m_ShadowHandle, false );
shadowmgr->EnableShadow( shadow.m_ShadowHandle, true );
}
if( r_flashlightmodels.GetBool() )
{
if( shadow.m_hTargetEntity==NULL )
{
// Add the shadow to the client leaf system so it correctly marks
// leafs as being affected by a particular shadow
ClientLeafSystem()->ProjectFlashlight( shadow.m_ClientLeafShadowHandle, shadow.m_WorldToShadow );
}
else
{
// We know what we are focused on, so just add the shadow directly to that receiver
Assert( shadow.m_hTargetEntity->GetModel() );
C_BaseEntity *pChild = shadow.m_hTargetEntity->FirstMoveChild();
while( pChild )
{
int modelType = modelinfo->GetModelType( pChild->GetModel() );
if (modelType == mod_brush)
{
AddShadowToReceiver( handle, pChild, SHADOW_RECEIVER_BRUSH_MODEL );
}
else if ( modelType == mod_studio )
{
AddShadowToReceiver( handle, pChild, SHADOW_RECEIVER_STUDIO_MODEL );
}
pChild = pChild->NextMovePeer();
}
int modelType = modelinfo->GetModelType( shadow.m_hTargetEntity->GetModel() );
if (modelType == mod_brush)
{
AddShadowToReceiver( handle, shadow.m_hTargetEntity, SHADOW_RECEIVER_BRUSH_MODEL );
}
else if ( modelType == mod_studio )
{
AddShadowToReceiver( handle, shadow.m_hTargetEntity, SHADOW_RECEIVER_STUDIO_MODEL );
}
}
}
}
//-----------------------------------------------------------------------------
// Adds the child bounds to the bounding box
//-----------------------------------------------------------------------------
void CClientShadowMgr::AddChildBounds( matrix3x4_t &worldToBBox, IClientRenderable* pParent, Vector &vecMins, Vector &vecMaxs )
{
Vector vecChildMins, vecChildMaxs;
Vector vecNewChildMins, vecNewChildMaxs;
matrix3x4_t childToBBox;
IClientRenderable *pChild = pParent->FirstShadowChild();
while( pChild )
{
// Transform the child bbox into the space of the main bbox
// FIXME: Optimize this?
if ( GetActualShadowCastType( pChild ) != SHADOWS_NONE)
{
pChild->GetShadowRenderBounds( vecChildMins, vecChildMaxs, SHADOWS_RENDER_TO_TEXTURE );
ConcatTransforms( worldToBBox, pChild->RenderableToWorldTransform(), childToBBox );
TransformAABB( childToBBox, vecChildMins, vecChildMaxs, vecNewChildMins, vecNewChildMaxs );
VectorMin( vecMins, vecNewChildMins, vecMins );
VectorMax( vecMaxs, vecNewChildMaxs, vecMaxs );
}
AddChildBounds( worldToBBox, pChild, vecMins, vecMaxs );
pChild = pChild->NextShadowPeer();
}
}
//-----------------------------------------------------------------------------
// Compute a bounds for the entity + children
//-----------------------------------------------------------------------------
void CClientShadowMgr::ComputeHierarchicalBounds( IClientRenderable *pRenderable, Vector &vecMins, Vector &vecMaxs )
{
ShadowType_t shadowType = GetActualShadowCastType( pRenderable );
pRenderable->GetShadowRenderBounds( vecMins, vecMaxs, shadowType );
// We could use a good solution for this in the regular PC build, since
// it causes lots of extra bone setups for entities you can't see.
if ( IsPC() )
{
IClientRenderable *pChild = pRenderable->FirstShadowChild();
// Don't recurse down the tree when we hit a blobby shadow
if ( pChild && shadowType != SHADOWS_SIMPLE )
{
matrix3x4_t worldToBBox;
MatrixInvert( pRenderable->RenderableToWorldTransform(), worldToBBox );
AddChildBounds( worldToBBox, pRenderable, vecMins, vecMaxs );
}
}
}
//-----------------------------------------------------------------------------
// Shadow update functions
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateStudioShadow( IClientRenderable *pRenderable, ClientShadowHandle_t handle )
{
if( !( m_Shadows[handle].m_Flags & SHADOW_FLAGS_FLASHLIGHT ) )
{
Vector mins, maxs;
ComputeHierarchicalBounds( pRenderable, mins, maxs );
ShadowType_t shadowType = GetActualShadowCastType( handle );
if ( shadowType != SHADOWS_RENDER_TO_TEXTURE )
{
BuildOrthoShadow( pRenderable, handle, mins, maxs );
}
else
{
BuildRenderToTextureShadow( pRenderable, handle, mins, maxs );
}
}
else
{
BuildFlashlight( handle );
}
}
void CClientShadowMgr::UpdateBrushShadow( IClientRenderable *pRenderable, ClientShadowHandle_t handle )
{
if( !( m_Shadows[handle].m_Flags & SHADOW_FLAGS_FLASHLIGHT ) )
{
// Compute the bounding box in the space of the shadow...
Vector mins, maxs;
ComputeHierarchicalBounds( pRenderable, mins, maxs );
ShadowType_t shadowType = GetActualShadowCastType( handle );
if ( shadowType != SHADOWS_RENDER_TO_TEXTURE )
{
BuildOrthoShadow( pRenderable, handle, mins, maxs );
}
else
{
BuildRenderToTextureShadow( pRenderable, handle, mins, maxs );
}
}
else
{
BuildFlashlight( handle );
}
}
#ifdef _DEBUG
static bool s_bBreak = false;
void ShadowBreak_f()
{
s_bBreak = true;
}
static ConCommand r_shadowbreak("r_shadowbreak", ShadowBreak_f);
#endif // _DEBUG
bool CClientShadowMgr::WillParentRenderBlobbyShadow( IClientRenderable *pRenderable )
{
if ( !pRenderable )
return false;
IClientRenderable *pShadowParent = pRenderable->GetShadowParent();
if ( !pShadowParent )
return false;
// If there's *no* shadow casting type, then we want to see if we can render into its parent
ShadowType_t shadowType = GetActualShadowCastType( pShadowParent );
if ( shadowType == SHADOWS_NONE )
return WillParentRenderBlobbyShadow( pShadowParent );
return shadowType == SHADOWS_SIMPLE;
}
//-----------------------------------------------------------------------------
// Are we the child of a shadow with render-to-texture?
//-----------------------------------------------------------------------------
bool CClientShadowMgr::ShouldUseParentShadow( IClientRenderable *pRenderable )
{
if ( !pRenderable )
return false;
IClientRenderable *pShadowParent = pRenderable->GetShadowParent();
if ( !pShadowParent )
return false;
// Can't render into the parent if the parent is blobby
ShadowType_t shadowType = GetActualShadowCastType( pShadowParent );
if ( shadowType == SHADOWS_SIMPLE )
return false;
// If there's *no* shadow casting type, then we want to see if we can render into its parent
if ( shadowType == SHADOWS_NONE )
return ShouldUseParentShadow( pShadowParent );
// Here, the parent uses a render-to-texture shadow
return true;
}
//-----------------------------------------------------------------------------
// Before we render any view, make sure all shadows are re-projected vs world
//-----------------------------------------------------------------------------
void CClientShadowMgr::PreRender()
{
VPROF_BUDGET( "CClientShadowMgr::PreRender", VPROF_BUDGETGROUP_SHADOW_RENDERING );
MDLCACHE_CRITICAL_SECTION();
bool bRenderToTextureActive = r_shadowrendertotexture.GetBool();
if ( bRenderToTextureActive != m_RenderToTextureActive )
{
if ( m_RenderToTextureActive )
{
ShutdownRenderToTextureShadows();
}
else
{
InitRenderToTextureShadows();
}
UpdateAllShadows();
return;
}
#ifdef DOSHADOWEDFLASHLIGHT
bool bDepthTextureActive = r_flashlightdepthtexture.GetBool();
if ( bDepthTextureActive != m_DepthTextureActive )
{
if( m_DepthTextureActive )
{
ShutdownDepthTextureShadows();
}
else
{
InitDepthTextureShadows();
}
UpdateAllShadows();
return;
}
#endif
m_bUpdatingDirtyShadows = true;
unsigned short i = m_DirtyShadows.FirstInorder();
while ( i != m_DirtyShadows.InvalidIndex() )
{
ClientShadowHandle_t& handle = m_DirtyShadows[ i ];
Assert( m_Shadows.IsValidIndex( handle ) );
UpdateProjectedTextureInternal( handle, false );
i = m_DirtyShadows.NextInorder(i);
}
m_DirtyShadows.RemoveAll();
m_bUpdatingDirtyShadows = false;
}
//-----------------------------------------------------------------------------
// Gets the entity whose shadow this shadow will render into
//-----------------------------------------------------------------------------
IClientRenderable *CClientShadowMgr::GetParentShadowEntity( ClientShadowHandle_t handle )
{
ClientShadow_t& shadow = m_Shadows[handle];
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
if ( pRenderable )
{
if ( ShouldUseParentShadow( pRenderable ) )
{
IClientRenderable *pParent = pRenderable->GetShadowParent();
while ( GetActualShadowCastType( pParent ) == SHADOWS_NONE )
{
pParent = pParent->GetShadowParent();
Assert( pParent );
}
return pParent;
}
}
return NULL;
}
//-----------------------------------------------------------------------------
// Marks a shadow as needing re-projection
//-----------------------------------------------------------------------------
void CClientShadowMgr::AddToDirtyShadowList( ClientShadowHandle_t handle, bool bForce )
{
// Don't add to the dirty shadow list while we're iterating over it
// The only way this can happen is if a child is being rendered into a parent
// shadow, and we don't need it to be added to the dirty list in that case.
if ( m_bUpdatingDirtyShadows )
return;
if ( handle == CLIENTSHADOW_INVALID_HANDLE )
return;
Assert( m_DirtyShadows.Find( handle ) == m_DirtyShadows.InvalidIndex() );
m_DirtyShadows.Insert( handle );
// This pretty much guarantees we'll recompute the shadow
if ( bForce )
{
m_Shadows[handle].m_LastAngles.Init( FLT_MAX, FLT_MAX, FLT_MAX );
}
// If we use our parent shadow, then it's dirty too...
IClientRenderable *pParent = GetParentShadowEntity( handle );
if ( pParent )
{
AddToDirtyShadowList( pParent, bForce );
}
}
//-----------------------------------------------------------------------------
// Marks a shadow as needing re-projection
//-----------------------------------------------------------------------------
void CClientShadowMgr::AddToDirtyShadowList( IClientRenderable *pRenderable, bool bForce )
{
// Don't add to the dirty shadow list while we're iterating over it
// The only way this can happen is if a child is being rendered into a parent
// shadow, and we don't need it to be added to the dirty list in that case.
if ( m_bUpdatingDirtyShadows )
return;
// Are we already in the dirty list?
if ( pRenderable->IsShadowDirty( ) )
return;
ClientShadowHandle_t handle = pRenderable->GetShadowHandle();
if ( handle == CLIENTSHADOW_INVALID_HANDLE )
return;
#ifdef _DEBUG
// Make sure everything's consistent
if ( pRenderable->GetShadowHandle() != CLIENTSHADOW_INVALID_HANDLE )
{
IClientRenderable *pShadowRenderable = ClientEntityList().GetClientRenderableFromHandle( m_Shadows[handle].m_Entity );
Assert( pRenderable == pShadowRenderable );
}
#endif
pRenderable->MarkShadowDirty( true );
AddToDirtyShadowList( handle, bForce );
}
//-----------------------------------------------------------------------------
// Marks the render-to-texture shadow as needing to be re-rendered
//-----------------------------------------------------------------------------
void CClientShadowMgr::MarkRenderToTextureShadowDirty( ClientShadowHandle_t handle )
{
// Don't add bogus handles!
if (handle != CLIENTSHADOW_INVALID_HANDLE)
{
// Mark the shadow has having a dirty renter-to-texture
ClientShadow_t& shadow = m_Shadows[handle];
shadow.m_Flags |= SHADOW_FLAGS_TEXTURE_DIRTY;
// If we use our parent shadow, then it's dirty too...
IClientRenderable *pParent = GetParentShadowEntity( handle );
if ( pParent )
{
ClientShadowHandle_t parentHandle = pParent->GetShadowHandle();
if ( parentHandle != CLIENTSHADOW_INVALID_HANDLE )
{
m_Shadows[parentHandle].m_Flags |= SHADOW_FLAGS_TEXTURE_DIRTY;
}
}
}
}
//-----------------------------------------------------------------------------
// Update a shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateShadow( ClientShadowHandle_t handle, bool force )
{
ClientShadow_t& shadow = m_Shadows[handle];
// Get the client entity....
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
if ( !pRenderable )
{
// Retire the shadow if the entity is gone
DestroyShadow( handle );
return;
}
if ( !pRenderable->GetModel() )
{
pRenderable->MarkShadowDirty( false );
return;
}
#ifdef _DEBUG
if (s_bBreak)
{
s_bBreak = false;
}
#endif
// Hierarchical children shouldn't be projecting shadows...
// Check to see if it's a child of an entity with a render-to-texture shadow...
if ( ShouldUseParentShadow( pRenderable ) || WillParentRenderBlobbyShadow( pRenderable ) )
{
shadowmgr->EnableShadow( shadow.m_ShadowHandle, false );
pRenderable->MarkShadowDirty( false );
return;
}
shadowmgr->EnableShadow( shadow.m_ShadowHandle, true );
// Figure out if the shadow moved...
// Even though we have dirty bits, some entities
// never clear those dirty bits
const Vector& origin = pRenderable->GetRenderOrigin();
const QAngle& angles = pRenderable->GetRenderAngles();
if (force || (origin != shadow.m_LastOrigin) || (angles != shadow.m_LastAngles))
{
// Store off the new pos/orientation
VectorCopy( origin, shadow.m_LastOrigin );
VectorCopy( angles, shadow.m_LastAngles );
const model_t *pModel = pRenderable->GetModel();
MaterialFogMode_t fogMode = materials->GetFogMode();
materials->FogMode( MATERIAL_FOG_NONE );
switch( modelinfo->GetModelType( pModel ) )
{
case mod_brush:
UpdateBrushShadow( pRenderable, handle );
break;
case mod_studio:
UpdateStudioShadow( pRenderable, handle );
break;
default:
// Shouldn't get here if not a brush or studio
Assert(0);
break;
}
materials->FogMode( fogMode );
}
// NOTE: We can't do this earlier because pEnt->GetRenderOrigin() can
// provoke a recomputation of render origin, which, for aiments, can cause everything
// to be marked as dirty. So don't clear the flag until this point.
pRenderable->MarkShadowDirty( false );
}
//-----------------------------------------------------------------------------
// Update a shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateProjectedTextureInternal( ClientShadowHandle_t handle, bool force )
{
ClientShadow_t& shadow = m_Shadows[handle];
if( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT )
{
Assert( ( shadow.m_Flags & SHADOW_FLAGS_SHADOW ) == 0 );
ClientShadow_t& shadow = m_Shadows[handle];
shadowmgr->EnableShadow( shadow.m_ShadowHandle, true );
// Make sure to allocate/deallocated shadow depth texture here
// if they are out of sync with flags
#ifdef DOSHADOWEDFLASHLIGHT
if( shadow.m_Flags & SHADOW_FLAGS_USE_DEPTH_TEXTURE )
{
if( !shadow.m_ShadowDepthTexture && r_flashlightdepthtexture.GetBool() )
{
AllocateDepthBuffer( shadow.m_ShadowDepthTexture );
}
}
else
#endif
{
if( shadow.m_ShadowDepthTexture )
{
DeallocateDepthBuffer( shadow.m_ShadowDepthTexture );
}
}
// FIXME: What's the difference between brush and model shadows for light projectors? Answer: nothing.
UpdateBrushShadow( NULL, handle );
}
else
{
Assert( shadow.m_Flags & SHADOW_FLAGS_SHADOW );
Assert( ( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT ) == 0 );
UpdateShadow( handle, force );
}
}
//-----------------------------------------------------------------------------
// Update a shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::UpdateProjectedTexture( ClientShadowHandle_t handle, bool force )
{
if (handle == CLIENTSHADOW_INVALID_HANDLE)
return;
UpdateProjectedTextureInternal( handle, force );
RemoveShadowFromDirtyList( handle );
}
//-----------------------------------------------------------------------------
// Computes bounding sphere
//-----------------------------------------------------------------------------
void CClientShadowMgr::ComputeBoundingSphere( IClientRenderable* pRenderable, Vector& origin, float& radius )
{
Assert( pRenderable );
Vector mins, maxs;
pRenderable->GetShadowRenderBounds( mins, maxs, GetActualShadowCastType( pRenderable ) );
Vector size;
VectorSubtract( maxs, mins, size );
radius = size.Length() * 0.5f;
// Compute centroid (local space)
Vector centroid;
VectorAdd( mins, maxs, centroid );
centroid *= 0.5f;
// Transform centroid into world space
Vector vec[3];
AngleVectors( pRenderable->GetRenderAngles(), &vec[0], &vec[1], &vec[2] );
vec[1] *= -1.0f;
VectorCopy( pRenderable->GetRenderOrigin(), origin );
VectorMA( origin, centroid.x, vec[0], origin );
VectorMA( origin, centroid.y, vec[1], origin );
VectorMA( origin, centroid.z, vec[2], origin );
}
//-----------------------------------------------------------------------------
// Computes a rough AABB encompassing the volume of the shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::ComputeShadowBBox( IClientRenderable *pRenderable, const Vector &vecAbsCenter, float flRadius, Vector *pAbsMins, Vector *pAbsMaxs )
{
// This is *really* rough. Basically we simply determine the
// maximum shadow casting length and extrude the box by that distance
Vector vecShadowDir = GetShadowDirection( pRenderable );
for (int i = 0; i < 3; ++i)
{
float flShadowCastDistance = GetShadowDistance( pRenderable );
float flDist = flShadowCastDistance * vecShadowDir[i];
if (vecShadowDir[i] < 0)
{
(*pAbsMins)[i] = vecAbsCenter[i] - flRadius + flDist;
(*pAbsMaxs)[i] = vecAbsCenter[i] + flRadius;
}
else
{
(*pAbsMins)[i] = vecAbsCenter[i] - flRadius;
(*pAbsMaxs)[i] = vecAbsCenter[i] + flRadius + flDist;
}
}
}
//-----------------------------------------------------------------------------
// Compute a separating axis...
//-----------------------------------------------------------------------------
bool CClientShadowMgr::ComputeSeparatingPlane( IClientRenderable* pRend1, IClientRenderable* pRend2, cplane_t* pPlane )
{
Vector min1, max1, min2, max2;
pRend1->GetShadowRenderBounds( min1, max1, GetActualShadowCastType( pRend1 ) );
pRend2->GetShadowRenderBounds( min2, max2, GetActualShadowCastType( pRend2 ) );
return ::ComputeSeparatingPlane(
pRend1->GetRenderOrigin(), pRend1->GetRenderAngles(), min1, max1,
pRend2->GetRenderOrigin(), pRend2->GetRenderAngles(), min2, max2,
3.0f, pPlane );
}
//-----------------------------------------------------------------------------
// Cull shadows based on rough bounding volumes
//-----------------------------------------------------------------------------
bool CClientShadowMgr::CullReceiver( ClientShadowHandle_t handle, IClientRenderable* pRenderable,
IClientRenderable* pSourceRenderable )
{
// check flags here instead and assert !pSourceRenderable
if( m_Shadows[handle].m_Flags & SHADOW_FLAGS_FLASHLIGHT )
{
Assert( !pSourceRenderable );
const Frustum_t &frustum = shadowmgr->GetFlashlightFrustum( m_Shadows[handle].m_ShadowHandle );
Vector mins, maxs;
pRenderable->GetRenderBoundsWorldspace( mins, maxs );
return R_CullBox( mins, maxs, frustum );
}
Assert( pSourceRenderable );
// Compute a bounding sphere for the renderable
Vector origin;
float radius;
ComputeBoundingSphere( pRenderable, origin, radius );
// Transform the sphere center into the space of the shadow
Vector localOrigin;
const ClientShadow_t& shadow = m_Shadows[handle];
const ShadowInfo_t& info = shadowmgr->GetInfo( shadow.m_ShadowHandle );
Vector3DMultiplyPosition( shadow.m_WorldToShadow, origin, localOrigin );
// Compute a rough bounding box for the shadow (in shadow space)
Vector shadowMin, shadowMax;
shadowMin.Init( -shadow.m_WorldSize.x * 0.5f, -shadow.m_WorldSize.y * 0.5f, 0 );
shadowMax.Init( shadow.m_WorldSize.x * 0.5f, shadow.m_WorldSize.y * 0.5f, info.m_FalloffOffset + info.m_MaxDist );
// If the bounding sphere doesn't intersect with the shadow volume, cull
if (!IsBoxIntersectingSphere( shadowMin, shadowMax, localOrigin, radius ))
return true;
Vector originSource;
float radiusSource;
ComputeBoundingSphere( pSourceRenderable, originSource, radiusSource );
// Fast check for separating plane...
bool foundSeparatingPlane = false;
cplane_t plane;
if (!IsSphereIntersectingSphere( originSource, radiusSource, origin, radius ))
{
foundSeparatingPlane = true;
// the plane normal doesn't need to be normalized...
VectorSubtract( origin, originSource, plane.normal );
}
else
{
foundSeparatingPlane = ComputeSeparatingPlane( pRenderable, pSourceRenderable, &plane );
}
if (foundSeparatingPlane)
{
// Compute which side of the plane the renderable is on..
Vector vecShadowDir = GetShadowDirection( pSourceRenderable );
float shadowDot = DotProduct( vecShadowDir, plane.normal );
float receiverDot = DotProduct( plane.normal, origin );
float sourceDot = DotProduct( plane.normal, originSource );
if (shadowDot > 0.0f)
{
if (receiverDot <= sourceDot)
{
// Vector dest;
// VectorMA( pSourceRenderable->GetRenderOrigin(), 50, plane.normal, dest );
// debugoverlay->AddLineOverlay( pSourceRenderable->GetRenderOrigin(), dest, 255, 255, 0, true, 1.0f );
return true;
}
else
{
// Vector dest;
// VectorMA( pSourceRenderable->GetRenderOrigin(), 50, plane.normal, dest );
// debugoverlay->AddLineOverlay( pSourceRenderable->GetRenderOrigin(), dest, 255, 0, 0, true, 1.0f );
}
}
else
{
if (receiverDot >= sourceDot)
{
// Vector dest;
// VectorMA( pSourceRenderable->GetRenderOrigin(), -50, plane.normal, dest );
// debugoverlay->AddLineOverlay( pSourceRenderable->GetRenderOrigin(), dest, 255, 255, 0, true, 1.0f );
return true;
}
else
{
// Vector dest;
// VectorMA( pSourceRenderable->GetRenderOrigin(), 50, plane.normal, dest );
// debugoverlay->AddLineOverlay( pSourceRenderable->GetRenderOrigin(), dest, 255, 0, 0, true, 1.0f );
}
}
}
// No additional clip planes? ok then it's a valid receiver
/*
if (shadow.m_ClipPlaneCount == 0)
return false;
// Check the additional cull planes
int i;
for ( i = 0; i < shadow.m_ClipPlaneCount; ++i)
{
// Fast sphere cull
if (DotProduct( origin, shadow.m_ClipPlane[i] ) - radius > shadow.m_ClipDist[i])
return true;
}
// More expensive box on plane side cull...
Vector vec[3];
Vector mins, maxs;
cplane_t plane;
AngleVectors( pRenderable->GetRenderAngles(), &vec[0], &vec[1], &vec[2] );
pRenderable->GetBounds( mins, maxs );
for ( i = 0; i < shadow.m_ClipPlaneCount; ++i)
{
// Transform the plane into the space of the receiver
plane.normal.x = DotProduct( vec[0], shadow.m_ClipPlane[i] );
plane.normal.y = DotProduct( vec[1], shadow.m_ClipPlane[i] );
plane.normal.z = DotProduct( vec[2], shadow.m_ClipPlane[i] );
plane.dist = shadow.m_ClipDist[i] - DotProduct( shadow.m_ClipPlane[i], pRenderable->GetRenderOrigin() );
// If the box is on the front side of the plane, we're done.
if (BoxOnPlaneSide2( mins, maxs, &plane, 3.0f ) == 1)
return true;
}
*/
return false;
}
//-----------------------------------------------------------------------------
// deals with shadows being added to shadow receivers
//-----------------------------------------------------------------------------
void CClientShadowMgr::AddShadowToReceiver( ClientShadowHandle_t handle,
IClientRenderable* pRenderable, ShadowReceiver_t type )
{
ClientShadow_t &shadow = m_Shadows[handle];
// Don't add a shadow cast by an object to itself...
IClientRenderable* pSourceRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
// NOTE: if pSourceRenderable == NULL, the source is probably a flashlight since there is no entity.
if (pSourceRenderable == pRenderable)
return;
// Don't bother if this renderable doesn't receive shadows or light from flashlights
if( !pRenderable->ShouldReceiveProjectedTextures( SHADOW_FLAGS_PROJECTED_TEXTURE_TYPE_MASK ) )
return;
// Cull if the origin is on the wrong side of a shadow clip plane....
if ( CullReceiver( handle, pRenderable, pSourceRenderable ) )
return;
// Do different things depending on the receiver type
switch( type )
{
case SHADOW_RECEIVER_BRUSH_MODEL:
if( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT )
{
if( (!shadow.m_hTargetEntity) || IsFlashlightTarget( handle, pRenderable ) )
{
shadowmgr->AddShadowToBrushModel( shadow.m_ShadowHandle,
const_cast<model_t*>(pRenderable->GetModel()),
pRenderable->GetRenderOrigin(), pRenderable->GetRenderAngles() );
shadowmgr->AddFlashlightRenderable( shadow.m_ShadowHandle, pRenderable );
}
}
else
{
shadowmgr->AddShadowToBrushModel( shadow.m_ShadowHandle,
const_cast<model_t*>(pRenderable->GetModel()),
pRenderable->GetRenderOrigin(), pRenderable->GetRenderAngles() );
}
break;
case SHADOW_RECEIVER_STATIC_PROP:
// Don't add shadows to props if we're not using render-to-texture
if ( GetActualShadowCastType( handle ) == SHADOWS_RENDER_TO_TEXTURE )
{
// Also don't add them unless an NPC or player casts them..
// They are wickedly expensive!!!
C_BaseEntity *pEnt = pSourceRenderable->GetIClientUnknown()->GetBaseEntity();
if ( pEnt && ( pEnt->GetFlags() & (FL_NPC | FL_CLIENT)) )
{
staticpropmgr->AddShadowToStaticProp( shadow.m_ShadowHandle, pRenderable );
}
}
else if( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT )
{
if( (!shadow.m_hTargetEntity) || IsFlashlightTarget( handle, pRenderable ) )
{
staticpropmgr->AddShadowToStaticProp( shadow.m_ShadowHandle, pRenderable );
shadowmgr->AddFlashlightRenderable( shadow.m_ShadowHandle, pRenderable );
}
}
break;
case SHADOW_RECEIVER_STUDIO_MODEL:
if( shadow.m_Flags & SHADOW_FLAGS_FLASHLIGHT )
{
if( (!shadow.m_hTargetEntity) || IsFlashlightTarget( handle, pRenderable ) )
{
pRenderable->CreateModelInstance();
shadowmgr->AddShadowToModel( shadow.m_ShadowHandle, pRenderable->GetModelInstance() );
shadowmgr->AddFlashlightRenderable( shadow.m_ShadowHandle, pRenderable );
}
}
break;
// default:
}
}
//-----------------------------------------------------------------------------
// deals with shadows being added to shadow receivers
//-----------------------------------------------------------------------------
void CClientShadowMgr::RemoveAllShadowsFromReceiver(
IClientRenderable* pRenderable, ShadowReceiver_t type )
{
// Don't bother if this renderable doesn't receive shadows
if ( !pRenderable->ShouldReceiveProjectedTextures( SHADOW_FLAGS_PROJECTED_TEXTURE_TYPE_MASK ) )
return;
// Do different things depending on the receiver type
switch( type )
{
case SHADOW_RECEIVER_BRUSH_MODEL:
{
model_t* pModel = const_cast<model_t*>(pRenderable->GetModel());
shadowmgr->RemoveAllShadowsFromBrushModel( pModel );
}
break;
case SHADOW_RECEIVER_STATIC_PROP:
staticpropmgr->RemoveAllShadowsFromStaticProp(pRenderable);
break;
case SHADOW_RECEIVER_STUDIO_MODEL:
if( pRenderable && pRenderable->GetModelInstance() != MODEL_INSTANCE_INVALID )
{
shadowmgr->RemoveAllShadowsFromModel( pRenderable->GetModelInstance() );
}
break;
// default:
// // FIXME: How do deal with this stuff? Add a method to IClientRenderable?
// C_BaseEntity* pEnt = static_cast<C_BaseEntity*>(pRenderable);
// pEnt->RemoveAllShadows();
}
}
//-----------------------------------------------------------------------------
// Computes + sets the render-to-texture texcoords
//-----------------------------------------------------------------------------
void CClientShadowMgr::SetRenderToTextureShadowTexCoords( ShadowHandle_t handle, int x, int y, int w, int h )
{
// Let the shadow mgr know about the texture coordinates...
// That way it'll be able to batch rendering better.
int textureW, textureH;
m_ShadowAllocator.GetTotalTextureSize( textureW, textureH );
// Go in a half-pixel to avoid blending with neighboring textures..
float u, v, du, dv;
#ifndef _XBOX
u = ((float)x + 0.5f) / (float)textureW;
v = ((float)y + 0.5f) / (float)textureH;
du = ((float)w - 1) / (float)textureW;
dv = ((float)h - 1) / (float)textureH;
#else
// xboxissue - need non-normalized tecture coords
u = ((float)x + 0.5f);
v = ((float)y + 0.5f);
du = ((float)w - 1);
dv = ((float)h - 1);
#endif
shadowmgr->SetShadowTexCoord( handle, u, v, du, dv );
}
//-----------------------------------------------------------------------------
// Draws all children shadows into our own
//-----------------------------------------------------------------------------
bool CClientShadowMgr::DrawShadowHierarchy( IClientRenderable *pRenderable, const ClientShadow_t &shadow, bool bChild )
{
bool bDrewTexture = false;
// Stop traversing when we hit a blobby shadow
ShadowType_t shadowType = GetActualShadowCastType( pRenderable );
if ( pRenderable && shadowType == SHADOWS_SIMPLE )
return false;
if ( !pRenderable || shadowType != SHADOWS_NONE )
{
bool bDrawModelShadow;
bool bDrawBrushShadow;
if ( !bChild )
{
bDrawModelShadow = ((shadow.m_Flags & SHADOW_FLAGS_BRUSH_MODEL) == 0);
bDrawBrushShadow = !bDrawModelShadow;
}
else
{
int nModelType = modelinfo->GetModelType( pRenderable->GetModel() );
bDrawModelShadow = nModelType == mod_studio;
bDrawBrushShadow = nModelType == mod_brush;
}
if ( bDrawModelShadow )
{
modelrender->DrawModelShadowEx( pRenderable, pRenderable->GetBody(), pRenderable->GetSkin() );
bDrewTexture = true;
}
else if ( bDrawBrushShadow )
{
render->DrawBrushModelShadow( pRenderable );
}
}
if ( !pRenderable )
return bDrewTexture;
IClientRenderable *pChild;
for ( pChild = pRenderable->FirstShadowChild(); pChild; pChild = pChild->NextShadowPeer() )
{
if ( DrawShadowHierarchy( pChild, shadow, true ) )
{
bDrewTexture = true;
}
}
return bDrewTexture;
}
//-----------------------------------------------------------------------------
// This gets called with every shadow that potentially will need to re-render
//-----------------------------------------------------------------------------
bool CClientShadowMgr::DrawRenderToTextureShadow( unsigned short clientShadowHandle, float flArea )
{
ClientShadow_t& shadow = m_Shadows[clientShadowHandle];
// If we were previously using the LOD shadow, set the material
if ( shadow.m_Flags & SHADOW_FLAGS_USING_LOD_SHADOW )
{
shadowmgr->SetShadowMaterial( shadow.m_ShadowHandle, m_RenderShadow, m_RenderModelShadow, (void*)clientShadowHandle );
}
// Mark texture as being used...
bool bDirtyTexture = (shadow.m_Flags & SHADOW_FLAGS_TEXTURE_DIRTY) != 0;
bool bDrewTexture = false;
bool needsRedraw = m_ShadowAllocator.UseTexture( shadow.m_ShadowTexture, bDirtyTexture, flArea );
if (needsRedraw || bDirtyTexture)
{
// shadow to be redrawn; for now, we'll always do it.
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
// Sets the viewport state
int x, y, w, h;
m_ShadowAllocator.GetTextureRect( shadow.m_ShadowTexture, x, y, w, h );
materials->Viewport( x, y, w, h );
// Clear the selected viewport only
// GR: don't need to clear depth
materials->ClearBuffers( true, false );
materials->MatrixMode( MATERIAL_VIEW );
materials->LoadMatrix( shadowmgr->GetInfo( shadow.m_ShadowHandle ).m_WorldToShadow );
if ( DrawShadowHierarchy( pRenderable, shadow ) )
{
bDrewTexture = true;
}
// Only clear the dirty flag if the caster isn't animating
if ( (shadow.m_Flags & SHADOW_FLAGS_ANIMATING_SOURCE) == 0 )
{
shadow.m_Flags &= ~SHADOW_FLAGS_TEXTURE_DIRTY;
}
SetRenderToTextureShadowTexCoords( shadow.m_ShadowHandle, x, y, w, h );
}
else if ( shadow.m_Flags & SHADOW_FLAGS_USING_LOD_SHADOW )
{
// In this case, we were previously using the LOD shadow, but we didn't
// have to reconstitute the texture. In this case, we need to reset the texcoord
int x, y, w, h;
m_ShadowAllocator.GetTextureRect( shadow.m_ShadowTexture, x, y, w, h );
SetRenderToTextureShadowTexCoords( shadow.m_ShadowHandle, x, y, w, h );
}
shadow.m_Flags &= ~SHADOW_FLAGS_USING_LOD_SHADOW;
return bDrewTexture;
}
//-----------------------------------------------------------------------------
// "Draws" the shadow LOD, which really means just set up the blobby shadow
//-----------------------------------------------------------------------------
void CClientShadowMgr::DrawRenderToTextureShadowLOD( unsigned short clientShadowHandle )
{
ClientShadow_t &shadow = m_Shadows[clientShadowHandle];
if ( (shadow.m_Flags & SHADOW_FLAGS_USING_LOD_SHADOW) == 0 )
{
shadowmgr->SetShadowMaterial( shadow.m_ShadowHandle, m_SimpleShadow, m_SimpleShadow, (void*)CLIENTSHADOW_INVALID_HANDLE );
shadowmgr->SetShadowTexCoord( shadow.m_ShadowHandle, 0, 0, 1, 1 );
ClearExtraClipPlanes( shadow.m_ShadowHandle );
shadow.m_Flags |= SHADOW_FLAGS_USING_LOD_SHADOW;
}
}
#define SMALL_OBJECT_FIXUP_FACTOR 10
//-----------------------------------------------------------------------------
// Returns true if the shadow is far enough to want to use blobby shadows
//-----------------------------------------------------------------------------
bool CClientShadowMgr::ShouldUseBlobbyShadows( float flRadius, float flScreenArea )
{
// Adjust the shadow area up for small objects; we don't want blobby shadows for
// really small things if we're real close to them...
float flMaxFixupRadius = 20;
float flMinFixupRadius = 6;
if (flRadius < flMaxFixupRadius)
{
if (flRadius >= flMinFixupRadius)
flScreenArea *= SMALL_OBJECT_FIXUP_FACTOR * (1.0f - (flRadius - flMinFixupRadius) / (flMaxFixupRadius - flMinFixupRadius) ) + 1.0f;
else
flScreenArea *= SMALL_OBJECT_FIXUP_FACTOR + 1.0f;
}
return (flScreenArea <= m_flMinShadowArea);
}
//-----------------------------------------------------------------------------
// Builds a list of potential shadows that lie within our PVS + view frustum
//-----------------------------------------------------------------------------
struct VisibleShadowInfo_t
{
ClientShadowHandle_t m_hShadow;
float m_flArea;
Vector m_vecAbsCenter;
float m_flRadius;
};
class CVisibleShadowList : public IClientLeafShadowEnum
{
public:
CVisibleShadowList();
int FindShadows( const CViewSetup *pView, int nLeafCount, LeafIndex_t *pLeafList );
int GetVisibleShadowCount() const;
const VisibleShadowInfo_t &GetVisibleShadow( int i ) const;
private:
void EnumShadow( unsigned short clientShadowHandle );
float ComputeScreenArea( const Vector &vecCenter, float r ) const;
void PrioritySort();
CUtlVector<VisibleShadowInfo_t> m_ShadowsInView;
CUtlVector<int> m_PriorityIndex;
};
//-----------------------------------------------------------------------------
// Singleton instance
//-----------------------------------------------------------------------------
static CVisibleShadowList s_VisibleShadowList;
CVisibleShadowList::CVisibleShadowList() : m_ShadowsInView( 0, 64 ), m_PriorityIndex( 0, 64 )
{
}
//-----------------------------------------------------------------------------
// Accessors
//-----------------------------------------------------------------------------
int CVisibleShadowList::GetVisibleShadowCount() const
{
return m_ShadowsInView.Count();
}
const VisibleShadowInfo_t &CVisibleShadowList::GetVisibleShadow( int i ) const
{
return m_ShadowsInView[m_PriorityIndex[i]];
}
//-----------------------------------------------------------------------------
// Computes approximate screen area of the shadow
//-----------------------------------------------------------------------------
float CVisibleShadowList::ComputeScreenArea( const Vector &vecCenter, float r ) const
{
float flScreenDiameter = materials->ComputePixelDiameterOfSphere( vecCenter, r );
return flScreenDiameter * flScreenDiameter;
}
//-----------------------------------------------------------------------------
// Visits every shadow in the list of leaves
//-----------------------------------------------------------------------------
void CVisibleShadowList::EnumShadow( unsigned short clientShadowHandle )
{
CClientShadowMgr::ClientShadow_t& shadow = s_ClientShadowMgr.m_Shadows[clientShadowHandle];
// Don't bother if we rendered it this frame, no matter which view it was rendered for
if (shadow.m_nRenderFrame == gpGlobals->framecount)
return;
// We don't need to bother with it
if ( s_ClientShadowMgr.GetActualShadowCastType( clientShadowHandle ) != SHADOWS_RENDER_TO_TEXTURE )
return;
IClientRenderable *pRenderable = ClientEntityList().GetClientRenderableFromHandle( shadow.m_Entity );
Assert( pRenderable );
// Don't bother with children of hierarchy; they will be drawn with their parents
if ( s_ClientShadowMgr.ShouldUseParentShadow( pRenderable ) || s_ClientShadowMgr.WillParentRenderBlobbyShadow( pRenderable ) )
return;
// Compute a sphere surrounding the shadow
// FIXME: This doesn't account for children of hierarchy... too bad!
Vector vecAbsCenter;
float flRadius;
s_ClientShadowMgr.ComputeBoundingSphere( pRenderable, vecAbsCenter, flRadius );
// Compute a box surrounding the shadow
Vector vecAbsMins, vecAbsMaxs;
s_ClientShadowMgr.ComputeShadowBBox( pRenderable, vecAbsCenter, flRadius, &vecAbsMins, &vecAbsMaxs );
// FIXME: Add distance check here?
// Make sure it's in the frustum. If it isn't it's not interesting
if (engine->CullBox( vecAbsMins, vecAbsMaxs ))
return;
int i = m_ShadowsInView.AddToTail( );
VisibleShadowInfo_t &info = m_ShadowsInView[i];
info.m_hShadow = clientShadowHandle;
info.m_vecAbsCenter = vecAbsCenter;
info.m_flRadius = flRadius;
m_ShadowsInView[i].m_flArea = ComputeScreenArea( vecAbsCenter, flRadius );
// Har, har. When water is rendering (or any multipass technique),
// we may well initially render from a viewpoint which doesn't include this shadow.
// That doesn't mean we shouldn't check it again though. Sucks that we need to compute
// the sphere + bbox multiply times though.
shadow.m_nRenderFrame = gpGlobals->framecount;
}
//-----------------------------------------------------------------------------
// Sort based on screen area/priority
//-----------------------------------------------------------------------------
void CVisibleShadowList::PrioritySort()
{
int nCount = m_ShadowsInView.Count();
m_PriorityIndex.EnsureCapacity( nCount );
m_PriorityIndex.RemoveAll();
int i, j;
for ( i = 0; i < nCount; ++i )
{
m_PriorityIndex.AddToTail(i);
}
for ( i = 0; i < nCount - 1; ++i )
{
int nLargestInd = i;
float flLargestArea = m_ShadowsInView[m_PriorityIndex[i]].m_flArea;
for ( j = i + 1; j < nCount; ++j )
{
int nIndex = m_PriorityIndex[j];
if ( flLargestArea < m_ShadowsInView[nIndex].m_flArea )
{
nLargestInd = j;
flLargestArea = m_ShadowsInView[nIndex].m_flArea;
}
}
Resolve conflicts with std::swap.
2020-06-01 22:17:46 -07:00
V_swap( m_PriorityIndex[i], m_PriorityIndex[nLargestInd] );
Added most recent version of unmodified HL2 SDK for Episode 1 engine
2008-09-15 01:00:17 -05:00
}
}
//-----------------------------------------------------------------------------
// Main entry point for finding shadows in the leaf list
//-----------------------------------------------------------------------------
int CVisibleShadowList::FindShadows( const CViewSetup *pView, int nLeafCount, LeafIndex_t *pLeafList )
{
VPROF_BUDGET( "CVisibleShadowList::FindShadows", VPROF_BUDGETGROUP_SHADOW_RENDERING );
m_ShadowsInView.RemoveAll();
ClientLeafSystem()->EnumerateShadowsInLeaves( nLeafCount, pLeafList, this );
int nCount = m_ShadowsInView.Count();
if (nCount != 0)
{
// Sort based on screen area/priority
PrioritySort();
}
return nCount;
}
//-----------------------------------------------------------------------------
// Advances to the next frame,
//-----------------------------------------------------------------------------
void CClientShadowMgr::AdvanceFrame()
{
// We're starting the next frame
m_ShadowAllocator.AdvanceFrame();
}
//-----------------------------------------------------------------------------
// Re-renders all shadow textures for shadow casters that lie in the leaf list
//-----------------------------------------------------------------------------
void CClientShadowMgr::ComputeShadowTextures( const CViewSetup *pView, int leafCount, LeafIndex_t* pLeafList )
{
VPROF_BUDGET( "CClientShadowMgr::ComputeShadowTextures", VPROF_BUDGETGROUP_SHADOW_RENDERING );
if ( !m_RenderToTextureActive || (r_shadows.GetInt() == 0) || r_shadows_gamecontrol.GetInt() == 0 )
return;
MDLCACHE_CRITICAL_SECTION();
// First grab all shadow textures we may want to render
int nCount = s_VisibleShadowList.FindShadows( pView, leafCount, pLeafList );
if ( nCount == 0 )
return;
// FIXME: Add heuristics based on distance, etc. to futz with
// the shadow allocator + to select blobby shadows
// Clear to white, black alpha
#ifndef _XBOX
materials->ClearColor4ub( 255, 255, 255, 0 );
#else
// xboxissue - using rgb instead
materials->ClearColor4ub( 0, 0, 0, 255 );
#endif
// No height clip mode please.
MaterialHeightClipMode_t oldHeightClipMode = materials->GetHeightClipMode();
materials->SetHeightClipMode( MATERIAL_HEIGHTCLIPMODE_DISABLE );
// No projection matrix (orthographic mode)
// FIXME: Make it work for projective shadows?
materials->MatrixMode( MATERIAL_PROJECTION );
materials->PushMatrix();
materials->LoadIdentity();
materials->Scale( 1, -1, 1 );
materials->Ortho( 0, 0, 1, 1, -9999, 0 );
materials->MatrixMode( MATERIAL_VIEW );
materials->PushMatrix();
materials->PushRenderTargetAndViewport( m_ShadowAllocator.GetTexture() );
if ( m_bRenderTargetNeedsClear )
{
// GR - draw with disabled depth buffer
// GR: don't need to clear depth
materials->ClearBuffers( true, false );
m_bRenderTargetNeedsClear = false;
}
int nMaxShadows = r_shadowmaxrendered.GetInt();
int nModelsRendered = 0;
for (int i = 0; i < nCount; ++i)
{
const VisibleShadowInfo_t &info = s_VisibleShadowList.GetVisibleShadow(i);
if ( (nModelsRendered < nMaxShadows) && ( !IsXbox() || !ShouldUseBlobbyShadows( info.m_flRadius, info.m_flArea ) ) )
{
if ( DrawRenderToTextureShadow( info.m_hShadow, info.m_flArea ) )
{
++nModelsRendered;
}
}
else
{
DrawRenderToTextureShadowLOD( info.m_hShadow );
}
}
// Render to the backbuffer again
materials->PopRenderTargetAndViewport();
// Restore the matrices
materials->MatrixMode( MATERIAL_PROJECTION );
materials->PopMatrix();
materials->MatrixMode( MATERIAL_VIEW );
materials->PopMatrix();
materials->SetHeightClipMode( oldHeightClipMode );
materials->SetHeightClipMode( oldHeightClipMode );
// Restore the clear color
materials->ClearColor3ub( 0, 0, 0 );
}
bool CClientShadowMgr::AllocateDepthBuffer( CTextureReference &depthBuffer )
{
if( !m_DepthTextureCache.Count() )
return false;
depthBuffer = m_DepthTextureCache[ m_DepthTextureCache.Count()-1 ];
m_DepthTextureCache.Remove( m_DepthTextureCache.Count()-1 );
return true;
}
void CClientShadowMgr::DeallocateDepthBuffer( CTextureReference &depthBuffer )
{
m_DepthTextureCache.AddToTail( depthBuffer );
depthBuffer.Shutdown();
}
void CClientShadowMgr::SetFlashlightTarget( ClientShadowHandle_t shadowHandle, EHANDLE targetEntity )
{
Assert( m_Shadows.IsValidIndex( shadowHandle ) );
CClientShadowMgr::ClientShadow_t &shadow = m_Shadows[ shadowHandle ];
if( (shadow.m_Flags&SHADOW_FLAGS_FLASHLIGHT) == 0 )
return;
// shadow.m_pTargetRenderable = pRenderable;
shadow.m_hTargetEntity = targetEntity;
}
void CClientShadowMgr::SetFlashlightLightWorld( ClientShadowHandle_t shadowHandle, bool bLightWorld )
{
Assert( m_Shadows.IsValidIndex( shadowHandle ) );
CClientShadowMgr::ClientShadow_t &shadow = m_Shadows[ shadowHandle ];
if( (shadow.m_Flags&SHADOW_FLAGS_FLASHLIGHT) == 0 )
return;
shadow.m_bLightWorld = bLightWorld;
}
bool CClientShadowMgr::IsFlashlightTarget( ClientShadowHandle_t shadowHandle, IClientRenderable *pRenderable )
{
ClientShadow_t &shadow = m_Shadows[ shadowHandle ];
if( shadow.m_hTargetEntity->GetClientRenderable() == pRenderable )
return true;
C_BaseEntity *pChild = shadow.m_hTargetEntity->FirstMoveChild();
while( pChild )
{
if( pChild->GetClientRenderable()==pRenderable )
return true;
pChild = pChild->NextMovePeer();
}
return false;
}
//-----------------------------------------------------------------------------
// A material proxy that resets the base texture to use the rendered shadow
//-----------------------------------------------------------------------------
class CShadowProxy : public IMaterialProxy
{
public:
CShadowProxy();
virtual ~CShadowProxy();
virtual bool Init( IMaterial *pMaterial, KeyValues *pKeyValues );
virtual void OnBind( void *pProxyData );
virtual void Release( void ) { delete this; }
private:
IMaterialVar* m_BaseTextureVar;
};
CShadowProxy::CShadowProxy()
{
m_BaseTextureVar = NULL;
}
CShadowProxy::~CShadowProxy()
{
}
bool CShadowProxy::Init( IMaterial *pMaterial, KeyValues *pKeyValues )
{
bool foundVar;
m_BaseTextureVar = pMaterial->FindVar( "$basetexture", &foundVar, false );
return foundVar;
}
void CShadowProxy::OnBind( void *pProxyData )
{
unsigned short clientShadowHandle = ( unsigned short )pProxyData;
ITexture* pTex = s_ClientShadowMgr.GetShadowTexture( clientShadowHandle );
if ((m_BaseTextureVar->GetType() != MATERIAL_VAR_TYPE_TEXTURE) ||
(pTex != m_BaseTextureVar->GetTextureValue()))
{
m_BaseTextureVar->SetTextureValue( pTex );
}
}
EXPOSE_INTERFACE( CShadowProxy, IMaterialProxy, "Shadow" IMATERIAL_PROXY_INTERFACE_VERSION );
//-----------------------------------------------------------------------------
// A material proxy that resets the base texture to use the rendered shadow
//-----------------------------------------------------------------------------
class CShadowModelProxy : public IMaterialProxy
{
public:
CShadowModelProxy();
virtual ~CShadowModelProxy();
virtual bool Init( IMaterial *pMaterial, KeyValues *pKeyValues );
virtual void OnBind( void *pProxyData );
virtual void Release( void ) { delete this; }
private:
IMaterialVar* m_BaseTextureVar;
IMaterialVar* m_BaseTextureOffsetVar;
IMaterialVar* m_BaseTextureScaleVar;
IMaterialVar* m_BaseTextureMatrixVar;
IMaterialVar* m_FalloffOffsetVar;
IMaterialVar* m_FalloffDistanceVar;
IMaterialVar* m_FalloffAmountVar;
};
CShadowModelProxy::CShadowModelProxy()
{
m_BaseTextureVar = NULL;
m_BaseTextureOffsetVar = NULL;
m_BaseTextureScaleVar = NULL;
m_BaseTextureMatrixVar = NULL;
m_FalloffOffsetVar = NULL;
m_FalloffDistanceVar = NULL;
m_FalloffAmountVar = NULL;
}
CShadowModelProxy::~CShadowModelProxy()
{
}
bool CShadowModelProxy::Init( IMaterial *pMaterial, KeyValues *pKeyValues )
{
bool foundVar;
m_BaseTextureVar = pMaterial->FindVar( "$basetexture", &foundVar, false );
if (!foundVar)
return false;
m_BaseTextureOffsetVar = pMaterial->FindVar( "$basetextureoffset", &foundVar, false );
if (!foundVar)
return false;
m_BaseTextureScaleVar = pMaterial->FindVar( "$basetexturescale", &foundVar, false );
if (!foundVar)
return false;
m_BaseTextureMatrixVar = pMaterial->FindVar( "$basetexturetransform", &foundVar, false );
if (!foundVar)
return false;
m_FalloffOffsetVar = pMaterial->FindVar( "$falloffoffset", &foundVar, false );
if (!foundVar)
return false;
m_FalloffDistanceVar = pMaterial->FindVar( "$falloffdistance", &foundVar, false );
if (!foundVar)
return false;
m_FalloffAmountVar = pMaterial->FindVar( "$falloffamount", &foundVar, false );
return foundVar;
}
void CShadowModelProxy::OnBind( void *pProxyData )
{
unsigned short clientShadowHandle = ( unsigned short )pProxyData;
ITexture* pTex = s_ClientShadowMgr.GetShadowTexture( clientShadowHandle );
m_BaseTextureVar->SetTextureValue( pTex );
const ShadowInfo_t& info = s_ClientShadowMgr.GetShadowInfo( clientShadowHandle );
m_BaseTextureMatrixVar->SetMatrixValue( info.m_WorldToShadow );
m_BaseTextureOffsetVar->SetVecValue( info.m_TexOrigin.Base(), 2 );
m_BaseTextureScaleVar->SetVecValue( info.m_TexSize.Base(), 2 );
m_FalloffOffsetVar->SetFloatValue( info.m_FalloffOffset );
m_FalloffDistanceVar->SetFloatValue( info.m_MaxDist );
m_FalloffAmountVar->SetFloatValue( info.m_FalloffAmount );
}
EXPOSE_INTERFACE( CShadowModelProxy, IMaterialProxy, "ShadowModel" IMATERIAL_PROXY_INTERFACE_VERSION );
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