void SetSpriteCommonShadowState( unsigned int shaderFlags )
{
IShaderShadow *pShaderShadow = s_pShaderShadow;
s_pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
bool bSRGB = s_ppParams[NOSRGB]->GetIntValue() == 0;
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, bSRGB );
// Only enabling this on OSX() - it causes GL mode's light glow sprites to be much darker vs. D3D9 under Linux/Win GL.
bool bSRGBOutputAdapter = ( IsOSX() && !g_pHardwareConfig->FakeSRGBWrite() ) && !bSRGB;
unsigned int flags = VERTEX_POSITION;
if( shaderFlags & SHADER_USE_VERTEX_COLOR )
{
flags |= VERTEX_COLOR;
}
int numTexCoords = 1;
s_pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, 0 );
DECLARE_STATIC_VERTEX_SHADER( jl_sprite_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, ( shaderFlags & SHADER_USE_VERTEX_COLOR ) ? true : false );
SET_STATIC_VERTEX_SHADER_COMBO( SRGB, bSRGB );
SET_STATIC_VERTEX_SHADER( jl_sprite_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() || g_pHardwareConfig->ShouldAlwaysUseShaderModel2bShaders() ) // Always send GL down this path
{
DECLARE_STATIC_PIXEL_SHADER( jl_sprite_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, ( shaderFlags & SHADER_USE_VERTEX_COLOR ) ? true : false );
SET_STATIC_PIXEL_SHADER_COMBO( CONSTANTCOLOR, ( shaderFlags & SHADER_USE_CONSTANT_COLOR ) ? true : false );
SET_STATIC_PIXEL_SHADER_COMBO( HDRTYPE, g_pHardwareConfig->GetHDRType() );
SET_STATIC_PIXEL_SHADER_COMBO( SRGB, bSRGB );
SET_STATIC_PIXEL_SHADER_COMBO( SRGB_OUTPUT_ADAPTER, bSRGBOutputAdapter );
SET_STATIC_PIXEL_SHADER( jl_sprite_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( jl_sprite_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, ( shaderFlags & SHADER_USE_VERTEX_COLOR ) ? true : false );
SET_STATIC_PIXEL_SHADER_COMBO( CONSTANTCOLOR, ( shaderFlags & SHADER_USE_CONSTANT_COLOR ) ? true : false );
SET_STATIC_PIXEL_SHADER_COMBO( HDRTYPE, g_pHardwareConfig->GetHDRType() );
SET_STATIC_PIXEL_SHADER_COMBO( SRGB, bSRGB );
SET_STATIC_PIXEL_SHADER( jl_sprite_ps20 );
}
// OSX always has to sRGB write (don't do this on Linux/Win GL - it causes glow sprites to be way too dark)
s_pShaderShadow->EnableSRGBWrite( bSRGB || ( IsOSX() && !g_pHardwareConfig->FakeSRGBWrite() ) );
}
void DrawMultiblend_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, Multiblend_DX9_Vars_t &info, VertexCompressionType_t vertexCompression,
CBasePerMaterialContextData **pContextDataPtr )
{
CMultiblend_DX9_Context *pContextData = reinterpret_cast< CMultiblend_DX9_Context * > ( *pContextDataPtr );//TODO: DISABLE?
bool bIsModel = IS_FLAG_SET( MATERIAL_VAR_MODEL );
bool bHasFoW = ( ( info.m_nFoW != -1 ) && ( params[ info.m_nFoW ]->IsTexture() != 0 ) );
if ( bHasFoW == true )
{
ITexture *pTexture = params[ info.m_nFoW ]->GetTextureValue();
if ( ( pTexture->GetFlags() & TEXTUREFLAGS_RENDERTARGET ) == 0 )
{
bHasFoW = false;
}
}
int nLightingPreviewMode = IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 );
bool bHasSpec1 = ( info.m_nSpecTexture != -1 && params[ info.m_nSpecTexture ]->IsDefined() );
bool bHasSpec2 = ( info.m_nSpecTexture2 != -1 && params[ info.m_nSpecTexture2 ]->IsDefined() );
bool bHasSpec3 = ( info.m_nSpecTexture3 != -1 && params[ info.m_nSpecTexture3 ]->IsDefined() );
bool bHasSpec4 = ( info.m_nSpecTexture4 != -1 && params[ info.m_nSpecTexture4 ]->IsDefined() );
bool bUsingEditor = pShader->CanUseEditorMaterials(); // pShader->UsingEditor( params );
bool bSinglePassFlashlight = true; //TODO: DISABLE?
bool bHasFlashlight = pShader->UsingFlashlight( params );
//TODO: DISABLE?
#if 1
if ( pShader->IsSnapshotting() || ( !pContextData ) || ( pContextData->m_bMaterialVarsChanged ) )
{
if ( !pContextData ) // make sure allocated
{
pContextData = new CMultiblend_DX9_Context;
*pContextDataPtr = pContextData;
}
// need to regenerate the semistatic cmds
pContextData->m_SemiStaticCmdsOut.Reset();
if ( bHasFlashlight )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderFlashlightState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6 );
CBCmdSetPixelShaderFlashlightState_t state;
state.m_LightSampler = SHADER_SAMPLER13;
state.m_DepthSampler = SHADER_SAMPLER14;
state.m_ShadowNoiseSampler = SHADER_SAMPLER15;
state.m_nColorConstant = 28;
state.m_nAttenConstant = 13;
state.m_nOriginConstant = 14;
state.m_nDepthTweakConstant = 19;
state.m_nScreenScaleConstant = 31;
state.m_nWorldToTextureConstant = -1;
state.m_bFlashlightNoLambert = false;
state.m_bSinglePassFlashlight = bSinglePassFlashlight;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderFlashlightState( state );
}
pContextData->m_SemiStaticCmdsOut.End();
}
#endif
SHADOW_STATE
{
pShader->SetInitialShadowState( );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true ); // Always SRGB read on base map 1
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true ); // Always SRGB read on base map 2
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, true ); // Always SRGB read on base map 3
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true ); // Always SRGB read on base map 4
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, true ); // Always SRGB read on spec map 1
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER7, true ); // Always SRGB read on spec map 1
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, true ); // Always SRGB read on spec map 1
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER9, true ); // Always SRGB read on spec map 1
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true );
}
else
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, false );
}
if ( bHasFoW )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true );
}
if( bHasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER14 );
pShaderShadow->EnableTexture( SHADER_SAMPLER15, true );
}
pShaderShadow->EnableSRGBWrite( true );
pShaderShadow->EnableAlphaWrites( true ); // writing water fog alpha always.
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int nTexCoordCount = 8;
static int s_TexCoordSize[]={ 2, //
2, //
0, //
4, // alpha blend
4, // vertex / blend color 0
4, // vertex / blend color 1
4, // vertex / blend color 2
4 // vertex / blend color 3
};
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, s_TexCoordSize, 0 );
int nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode();
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( multiblend_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( SPECULAR, !bUsingEditor );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_VERTEX_SHADER( multiblend_vs20 );
DECLARE_STATIC_PIXEL_SHADER( multiblend_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_PIXEL_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( multiblend_ps20b );
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( multiblend_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( SPECULAR, !bUsingEditor );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_VERTEX_SHADER( multiblend_vs30 );
// Bind ps_2_b shader so we can get Phong terms
DECLARE_STATIC_PIXEL_SHADER( multiblend_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_PIXEL_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( multiblend_ps30 );
}
#endif
pShader->DefaultFog();
float flLScale = pShaderShadow->GetLightMapScaleFactor();
// Lighting constants
pShader->PI_BeginCommandBuffer();
pShader->PI_SetPixelShaderAmbientLightCube( PSREG_AMBIENT_CUBE );
// pShader->PI_SetPixelShaderLocalLighting( PSREG_LIGHT_INFO_ARRAY );
pShader->PI_SetModulationPixelShaderDynamicState_LinearScale_ScaleInW( PSREG_CONSTANT_43, flLScale );
pShader->PI_EndCommandBuffer();
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
// Bind textures
pShader->BindTexture( SHADER_SAMPLER1, info.m_nBaseTexture ); // Base Map 1
pShader->BindTexture( SHADER_SAMPLER2, info.m_nBaseTexture2 ); // Base Map 2
pShader->BindTexture( SHADER_SAMPLER3, info.m_nBaseTexture3 ); // Base Map 3
pShader->BindTexture( SHADER_SAMPLER4, info.m_nBaseTexture4 ); // Base Map 4
if ( bHasSpec1 == true )
{
pShader->BindTexture( SHADER_SAMPLER6, info.m_nSpecTexture ); // Spec Map 1
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER6, TEXTURE_BLACK );
}
if ( bHasSpec2 == true )
{
pShader->BindTexture( SHADER_SAMPLER7, info.m_nSpecTexture2 ); // Spec Map 2
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER7, TEXTURE_BLACK );
}
if ( bHasSpec3 == true )
{
pShader->BindTexture( SHADER_SAMPLER8, info.m_nSpecTexture3 ); // Spec Map 3
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER8, TEXTURE_BLACK );
}
if ( bHasSpec4 == true )
{
pShader->BindTexture( SHADER_SAMPLER9, info.m_nSpecTexture4 ); // Spec Map 4
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER9, TEXTURE_BLACK );
}
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_LIGHTMAP );
bool bFlashlightShadows = false;
#if 1
if( bHasFlashlight )
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
pShader->BindTexture( SHADER_SAMPLER13, state.m_pSpotlightTexture, state.m_nSpotlightTextureFrame );
bFlashlightShadows = state.m_bEnableShadows;
SetFlashLightColorFromState( state, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && state.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER14, pFlashlightDepthTexture );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER15, TEXTURE_SHADOW_NOISE_2D );
}
float atten[4], pos[4], tweaks[4];
atten[0] = state.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = state.m_fLinearAtten;
atten[2] = state.m_fQuadraticAtten;
atten[3] = state.m_FarZAtten;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, atten, 1 );
pos[0] = state.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = state.m_vecLightOrigin[1];
pos[2] = state.m_vecLightOrigin[2];
pos[3] = state.m_FarZ;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, pos, 1 ); // steps on rim boost
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, worldToTexture.Base(), 4 );
// Tweaks associated with a given flashlight
tweaks[0] = ShadowFilterFromState( state );
tweaks[1] = ShadowAttenFromState( state );
pShader->HashShadow2DJitter( state.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
int nTexWidth, nTexHeight;
pShaderAPI->GetStandardTextureDimensions( &nTexWidth, &nTexHeight, TEXTURE_SHADOW_NOISE_2D );
vScreenScale[0] = (float) nWidth / nTexWidth;
vScreenScale[1] = (float) nHeight / nTexHeight;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
if ( IsX360() )
{
pShaderAPI->SetBooleanPixelShaderConstant( 0, &state.m_nShadowQuality, 1 );
}
QAngle angles;
QuaternionAngles( state.m_quatOrientation, angles );
#if 0
// World to Light's View matrix
matrix3x4_t viewMatrix, viewMatrixInverse;
AngleMatrix( angles, state.m_vecLightOrigin, viewMatrixInverse );
MatrixInvert( viewMatrixInverse, viewMatrix );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, worldToTexture.Base(), 4 );
#endif
}
#endif
if ( bHasFoW )
{
pShader->BindTexture( SHADER_SAMPLER10, info.m_nFoW, -1 );
float vFoWSize[ 4 ];
Vector vMins = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MINS );
Vector vMaxs = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MAXS );
vFoWSize[ 0 ] = vMins.x;
vFoWSize[ 1 ] = vMins.y;
vFoWSize[ 2 ] = vMaxs.x - vMins.x;
vFoWSize[ 3 ] = vMaxs.y - vMins.y;
pShaderAPI->SetVertexShaderConstant( 26, vFoWSize );
}
Vector4D vRotations( DEG2RAD( params[ info.m_nRotation ]->GetFloatValue() ), DEG2RAD( params[ info.m_nRotation2 ]->GetFloatValue() ),
DEG2RAD( params[ info.m_nRotation3 ]->GetFloatValue() ), DEG2RAD( params[ info.m_nRotation4 ]->GetFloatValue() ) );
pShaderAPI->SetVertexShaderConstant( 27, vRotations.Base() );
Vector4D vScales( params[ info.m_nScale ]->GetFloatValue() > 0.0f ? params[ info.m_nScale ]->GetFloatValue() : 1.0f,
params[ info.m_nScale2 ]->GetFloatValue() > 0.0f ? params[ info.m_nScale2 ]->GetFloatValue() : 1.0f,
params[ info.m_nScale3 ]->GetFloatValue() > 0.0f ? params[ info.m_nScale3 ]->GetFloatValue() : 1.0f,
params[ info.m_nScale4 ]->GetFloatValue() > 0.0f ? params[ info.m_nScale4 ]->GetFloatValue() : 1.0f );
pShaderAPI->SetVertexShaderConstant( 28, vScales.Base() );
Vector4D vLightDir;
vLightDir.AsVector3D() = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_LIGHT_DIRECTION );
vLightDir.w = pShaderAPI->GetFloatRenderingParameter( FLOAT_RENDERPARM_SPECULAR_POWER );
pShaderAPI->SetVertexShaderConstant( 29, vLightDir.Base() );
LightState_t lightState;
pShaderAPI->GetDX9LightState( &lightState );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( multiblend_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER( multiblend_vs20 );
DECLARE_DYNAMIC_PIXEL_SHADER( multiblend_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( multiblend_ps20b );
}
#ifndef _X360
else
{
DECLARE_DYNAMIC_VERTEX_SHADER( multiblend_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER( multiblend_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( multiblend_ps30 );
SET_DYNAMIC_PIXEL_SHADER( multiblend_ps30 );
}
#endif
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, info.m_nBaseTextureTransform );
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
// Pack phong exponent in with the eye position
float vEyePos_SpecExponent[4];
float vSpecularTint[4] = {1, 1, 1, 1};
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
// if ( (info.m_nPhongExponent != -1) && params[info.m_nPhongExponent]->IsDefined() )
// vEyePos_SpecExponent[3] = params[info.m_nPhongExponent]->GetFloatValue(); // This overrides the channel in the map
// else
vEyePos_SpecExponent[3] = 0; // Use the alpha channel of the normal map for the exponent
// If it's all zeros, there was no constant tint in the vmt
if ( (vSpecularTint[0] == 0.0f) && (vSpecularTint[1] == 0.0f) && (vSpecularTint[2] == 0.0f) )
{
vSpecularTint[0] = 1.0f;
vSpecularTint[1] = 1.0f;
vSpecularTint[2] = 1.0f;
}
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
// Set c0 and c1 to contain first two rows of ViewProj matrix
VMatrix matView, matProj, matViewProj;
pShaderAPI->GetMatrix( MATERIAL_VIEW, matView.m[0] );
pShaderAPI->GetMatrix( MATERIAL_PROJECTION, matProj.m[0] );
matViewProj = matView * matProj;
pShaderAPI->SetPixelShaderConstant( 0, matViewProj.m[0], 2 );
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
}
pShader->Draw();
}
void Draw_Eyes_Refract_Internal( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, bool bDrawFlashlightAdditivePass, Eye_Refract_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool bDiffuseWarp = IS_PARAM_DEFINED( info.m_nDiffuseWarpTexture );
bool bIntro = IS_PARAM_DEFINED( info.m_nIntro ) ? ( params[info.m_nIntro]->GetIntValue() ? true : false ) : false;
SHADOW_STATE
{
SET_FLAGS2( MATERIAL_VAR2_LIGHTING_VERTEX_LIT );
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Cornea normal
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Iris
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Cube reflection
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Ambient occlusion
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
if ( bDiffuseWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Light warp
}
#if !defined( PLATFORM_X360 )
bool bWorldNormal = ( ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH == ( IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 )));
#endif
int nShadowFilterMode = 0;
if ( bDrawFlashlightAdditivePass == true )
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
pShaderShadow->EnableDepthWrites( false );
pShaderShadow->EnableAlphaWrites( false );
pShader->EnableAlphaBlending( SHADER_BLEND_ONE, SHADER_BLEND_ONE ); // Additive blending
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Flashlight cookie
}
else
{
pShaderShadow->EnableAlphaWrites( true );
}
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( eye_refract_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT ) );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, bIntro ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( WORLD_NORMAL, 0 );
SET_STATIC_VERTEX_SHADER( eye_refract_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
bool bSphereTexKillCombo = IS_PARAM_DEFINED( info.m_nSphereTexKillCombo ) ? ( params[info.m_nSphereTexKillCombo]->GetIntValue() ? true : false ) : ( kDefaultSphereTexKillCombo ? true : false );
bool bRayTraceSphere = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? ( params[info.m_nRaytraceSphere]->GetIntValue() ? true : false ) : ( kDefaultRaytraceSphere ? true : false );
DECLARE_STATIC_PIXEL_SHADER( eye_refract_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( SPHERETEXKILLCOMBO, bSphereTexKillCombo ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( RAYTRACESPHERE, bRayTraceSphere ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( WORLD_NORMAL, 0 );
SET_STATIC_PIXEL_SHADER( eye_refract_ps20b );
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER6 );
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Noise map
}
}
else
{
DECLARE_STATIC_PIXEL_SHADER( eye_refract_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( WORLD_NORMAL, 0 );
SET_STATIC_PIXEL_SHADER( eye_refract_ps20 );
}
}
#ifndef _X360
else
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true ); // Screen space ambient occlusion
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
SET_FLAGS2( MATERIAL_VAR2_SUPPORTS_TESSELLATION );
DECLARE_STATIC_VERTEX_SHADER( eye_refract_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT ) );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, bIntro ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( WORLD_NORMAL, bWorldNormal );
SET_STATIC_VERTEX_SHADER( eye_refract_vs30 );
bool bSphereTexKillCombo = IS_PARAM_DEFINED( info.m_nSphereTexKillCombo ) ? ( params[info.m_nSphereTexKillCombo]->GetIntValue() ? true : false ) : ( kDefaultSphereTexKillCombo ? true : false );
bool bRayTraceSphere = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? ( params[info.m_nRaytraceSphere]->GetIntValue() ? true : false ) : ( kDefaultRaytraceSphere ? true : false );
DECLARE_STATIC_PIXEL_SHADER( eye_refract_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( SPHERETEXKILLCOMBO, bSphereTexKillCombo ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( RAYTRACESPHERE, bRayTraceSphere ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( WORLD_NORMAL, bWorldNormal );
SET_STATIC_PIXEL_SHADER( eye_refract_ps30 );
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Shadow depth map
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Noise map
}
}
#endif
// On DX9, get the gamma read and write correct
//pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, false ); // Cornea normal
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true ); // Iris
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true ); // Cube map reflection
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, true ); // Ambient occlusion
pShaderShadow->EnableSRGBWrite( true );
if ( bDiffuseWarp )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true ); // Light Warp
}
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true ); // Flashlight cookie
}
// Fog
if ( bDrawFlashlightAdditivePass == true )
{
pShader->FogToBlack();
}
else
{
pShader->FogToFogColor();
}
// Per-instance state
pShader->PI_BeginCommandBuffer();
if ( !bDrawFlashlightAdditivePass )
{
pShader->PI_SetPixelShaderLocalLighting( PSREG_LIGHT_INFO_ARRAY );
}
pShader->PI_SetVertexShaderAmbientLightCube();
pShader->PI_SetPixelShaderAmbientLightCubeLuminance( 10 );
pShader->PI_EndCommandBuffer();
}
DYNAMIC_STATE
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture = NULL;
FlashlightState_t flashlightState;
bool bFlashlightShadows = false;
if ( bDrawFlashlightAdditivePass == true )
{
flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
bFlashlightShadows = flashlightState.m_bEnableShadows;
}
bool bSinglePassFlashlight = false;
pShader->BindTexture( SHADER_SAMPLER0, info.m_nCorneaTexture );
pShader->BindTexture( SHADER_SAMPLER1, info.m_nIris, info.m_nIrisFrame );
pShader->BindTexture( SHADER_SAMPLER2, info.m_nEnvmap );
pShader->BindTexture( SHADER_SAMPLER3, info.m_nAmbientOcclTexture );
if ( bDiffuseWarp )
{
if ( r_lightwarpidentity.GetBool() )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER4, TEXTURE_IDENTITY_LIGHTWARP );
}
else
{
pShader->BindTexture( SHADER_SAMPLER4, info.m_nDiffuseWarpTexture );
}
}
// On PC, we sample from ambient occlusion texture
if ( IsPC() && g_pHardwareConfig->HasFastVertexTextures() )
{
ITexture *pAOTexture = pShaderAPI->GetTextureRenderingParameter( TEXTURE_RENDERPARM_AMBIENT_OCCLUSION );
if ( pAOTexture )
{
pShader->BindTexture( SHADER_SAMPLER8, pAOTexture );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER8, TEXTURE_WHITE );
}
}
if ( bDrawFlashlightAdditivePass == true )
pShader->BindTexture( SHADER_SAMPLER5, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nEyeOrigin );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nIrisU );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.m_nIrisV );
if ( bDrawFlashlightAdditivePass == true )
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, flashlightState.m_vecLightOrigin.Base(), 1 );
LightState_t lightState = { 0, false, false };
if ( bDrawFlashlightAdditivePass == false )
{
pShaderAPI->GetDX9LightState( &lightState );
}
int nFixedLightingMode = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_ENABLE_FIXED_LIGHTING );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( eye_refract_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER_COMBO( TESSELLATION, 0 );
SET_DYNAMIC_VERTEX_SHADER( eye_refract_vs20 );
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
if ( nFixedLightingMode == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH )
{
float vEyeDir[4];
pShaderAPI->GetWorldSpaceCameraDirection( vEyeDir );
float flFarZ = pShaderAPI->GetFarZ();
vEyeDir[0] /= flFarZ; // Divide by farZ for SSAO algorithm
vEyeDir[1] /= flFarZ;
vEyeDir[2] /= flFarZ;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, vEyeDir );
}
TessellationMode_t nTessellationMode = pShaderAPI->GetTessellationMode();
if ( nTessellationMode != TESSELLATION_MODE_DISABLED )
{
pShaderAPI->BindStandardVertexTexture( SHADER_VERTEXTEXTURE_SAMPLER1, TEXTURE_SUBDIVISION_PATCHES );
bool bHasDisplacement = false; // TODO
float vSubDDimensions[4] = { 1.0f/pShaderAPI->GetSubDHeight(), bHasDisplacement && mat_displacementmap.GetBool() ? 1.0f : 0.0f, 0.0f, 0.0f };
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, vSubDDimensions );
}
DECLARE_DYNAMIC_VERTEX_SHADER( eye_refract_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER_COMBO( TESSELLATION, nTessellationMode );
SET_DYNAMIC_VERTEX_SHADER( eye_refract_vs30 );
}
#endif
// Special constant for DX9 eyes: { Dilation, Glossiness, x, x };
float vPSConst[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPSConst[0] = IS_PARAM_DEFINED( info.m_nDilation ) ? params[info.m_nDilation]->GetFloatValue() : kDefaultDilation;
vPSConst[1] = IS_PARAM_DEFINED( info.m_nGlossiness ) ? params[info.m_nGlossiness]->GetFloatValue() : kDefaultGlossiness;
vPSConst[2] = 0.0f; // NOT USED
vPSConst[3] = IS_PARAM_DEFINED( info.m_nCorneaBumpStrength ) ? params[info.m_nCorneaBumpStrength]->GetFloatValue() : kDefaultCorneaBumpStrength;
pShaderAPI->SetPixelShaderConstant( 0, vPSConst, 1 );
pShaderAPI->SetPixelShaderConstant( 1, IS_PARAM_DEFINED( info.m_nEyeOrigin ) ? params[info.m_nEyeOrigin]->GetVecValue() : kDefaultEyeOrigin, 1 );
pShaderAPI->SetPixelShaderConstant( 2, IS_PARAM_DEFINED( info.m_nIrisU ) ? params[info.m_nIrisU]->GetVecValue() : kDefaultIrisU, 1 );
pShaderAPI->SetPixelShaderConstant( 3, IS_PARAM_DEFINED( info.m_nIrisV ) ? params[info.m_nIrisV]->GetVecValue() : kDefaultIrisV, 1 );
float vEyePos[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos );
pShaderAPI->SetPixelShaderConstant( 4, vEyePos, 1 );
float vAmbientOcclusion[4] = { 0.33f, 0.33f, 0.33f, 0.0f };
if ( IS_PARAM_DEFINED( info.m_nAmbientOcclColor ) )
{
params[info.m_nAmbientOcclColor]->GetVecValue( vAmbientOcclusion, 3 );
}
vAmbientOcclusion[3] = IS_PARAM_DEFINED( info.m_nAmbientOcclusion ) ? params[info.m_nAmbientOcclusion]->GetFloatValue() : 0.0f;
float vPackedConst6[4] = { 1.0f, 1.0f, 1.0f, 1.0f };
//vPackedConst6[0] Unused
vPackedConst6[1] = IS_PARAM_DEFINED( info.m_nEyeballRadius ) ? params[info.m_nEyeballRadius]->GetFloatValue() : kDefaultEyeballRadius;
//vPackedConst6[2] = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? params[info.m_nRaytraceSphere]->GetFloatValue() : kDefaultRaytraceSphere;
vPackedConst6[3] = IS_PARAM_DEFINED( info.m_nParallaxStrength ) ? params[info.m_nParallaxStrength]->GetFloatValue() : kDefaultParallaxStrength;
pShaderAPI->SetPixelShaderConstant( 6, vPackedConst6, 1 );
if ( bDrawFlashlightAdditivePass == true )
{
SetFlashLightColorFromState( flashlightState, pShaderAPI, bSinglePassFlashlight );
if ( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && flashlightState.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER6, pFlashlightDepthTexture, 0 );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER7, TEXTURE_SHADOW_NOISE_2D );
}
}
if ( nFixedLightingMode == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH )
{
float vEyeDir[4];
pShaderAPI->GetWorldSpaceCameraDirection( vEyeDir );
float flFarZ = pShaderAPI->GetFarZ();
vEyeDir[0] /= flFarZ; // Divide by farZ for SSAO algorithm
vEyeDir[1] /= flFarZ;
vEyeDir[2] /= flFarZ;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, vEyeDir );
}
// Flashlight tax
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( eye_refract_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( eye_refract_ps20b );
}
else // ps.2.0
{
DECLARE_DYNAMIC_PIXEL_SHADER( eye_refract_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER( eye_refract_ps20 );
}
}
#ifndef _X360
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( eye_refract_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, nFixedLightingMode ? 0 : lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, nFixedLightingMode ? false : bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER_COMBO( UBERLIGHT, flashlightState.m_bUberlight );
SET_DYNAMIC_PIXEL_SHADER( eye_refract_ps30 );
// Set constant to enable translation of VPOS to render target coordinates in ps_3_0
pShaderAPI->SetScreenSizeForVPOS();
SetupUberlightFromState( pShaderAPI, flashlightState );
}
#endif
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
if ( bDrawFlashlightAdditivePass == true )
{
float atten[4], pos[4], tweaks[4];
atten[0] = flashlightState.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZAtten;
pShaderAPI->SetPixelShaderConstant( 7, atten, 1 );
pos[0] = flashlightState.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pShaderAPI->SetPixelShaderConstant( 8, pos, 1 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, worldToTexture.Base(), 4 );
// Tweaks associated with a given flashlight
tweaks[0] = ShadowFilterFromState( flashlightState );
tweaks[1] = ShadowAttenFromState( flashlightState );
pShader->HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( 9, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
int nTexWidth, nTexHeight;
pShaderAPI->GetStandardTextureDimensions( &nTexWidth, &nTexHeight, TEXTURE_SHADOW_NOISE_2D );
vScreenScale[0] = (float) nWidth / nTexWidth;
vScreenScale[1] = (float) nHeight / nTexHeight;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
vAmbientOcclusion[3] *= flashlightState.m_flAmbientOcclusion;
}
vAmbientOcclusion[3] = MIN( MAX( vAmbientOcclusion[3], 0.0f ), 1.0f );
pShaderAPI->SetPixelShaderConstant( 5, vAmbientOcclusion, 1 );
// Intro tax
if ( bIntro )
{
float curTime = params[info.m_nWarpParam]->GetFloatValue();
float timeVec[4] = { 0.0f, 0.0f, 0.0f, curTime };
if ( IS_PARAM_DEFINED( info.m_nEntityOrigin ) )
{
params[info.m_nEntityOrigin]->GetVecValue( timeVec, 3 );
}
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, timeVec, 1 );
}
}
pShader->Draw();
}
//-----------------------------------------------------------------------------
// Draws the shader
//-----------------------------------------------------------------------------
void DrawVortWarp_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, bool bVertexLitGeneric, bool hasFlashlight, VortWarp_DX9_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool hasBaseTexture = params[info.m_nBaseTexture]->IsTexture();
bool hasBump = (info.m_nBumpmap != -1) && params[info.m_nBumpmap]->IsTexture();
bool hasDetailTexture = !hasBump && params[info.m_nDetail]->IsTexture();
bool hasNormalMapAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
bool hasVertexColor = bVertexLitGeneric ? false : IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool hasVertexAlpha = bVertexLitGeneric ? false : IS_FLAG_SET( MATERIAL_VAR_VERTEXALPHA );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
bool hasSelfIllumInEnvMapMask =
( info.m_nSelfIllumEnvMapMask_Alpha != -1 ) &&
( params[info.m_nSelfIllumEnvMapMask_Alpha]->GetFloatValue() != 0.0 ) ;
bool bHasFlowMap = ( info.m_nFlowMap != -1 ) && params[info.m_nFlowMap]->IsTexture();
bool bHasSelfIllumMap = ( info.m_nSelfIllumMap != -1 ) && params[info.m_nSelfIllumMap]->IsTexture();
BlendType_t blendType;
if ( params[info.m_nBaseTexture]->IsTexture() )
{
blendType = pShader->EvaluateBlendRequirements( info.m_nBaseTexture, true );
}
else
{
blendType = pShader->EvaluateBlendRequirements( info.m_nEnvmapMask, false );
}
if( pShader->IsSnapshotting() )
{
// look at color and alphamod stuff.
// Unlit generic never uses the flashlight
bool hasEnvmap = !hasFlashlight && params[info.m_nEnvmap]->IsTexture();
bool hasEnvmapMask = (hasSelfIllumInEnvMapMask || !hasFlashlight) &&
params[info.m_nEnvmapMask]->IsTexture();
bool bHasNormal = bVertexLitGeneric || hasEnvmap;
if( hasFlashlight )
{
hasEnvmapMask = false;
}
bool bHalfLambert = IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT );
// Alpha test: FIXME: shouldn't this be handled in CBaseVSShader::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
if( hasFlashlight )
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetAdditiveBlendingShadowState( info.m_nBaseTexture, true );
}
else
{
pShader->SetAdditiveBlendingShadowState( info.m_nEnvmapMask, false );
}
if( bIsAlphaTested )
{
// disable alpha test and use the zfunc zequals since alpha isn't guaranteed to
// be the same on both the regular pass and the flashlight pass.
pShaderShadow->EnableAlphaTest( false );
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
}
pShaderShadow->EnableBlending( true );
pShaderShadow->EnableDepthWrites( false );
}
else
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetDefaultBlendingShadowState( info.m_nBaseTexture, true );
}
else
{
pShader->SetDefaultBlendingShadowState( info.m_nEnvmapMask, false );
}
}
unsigned int flags = VERTEX_POSITION;
int nTexCoordCount = 1; // texcoord0 : base texcoord
int userDataSize = 0;
if( bHasNormal )
{
flags |= VERTEX_NORMAL;
}
if( hasBaseTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
}
if( hasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
}
}
if( hasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
userDataSize = 4; // tangent S
}
if( hasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
}
if( hasBump )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
userDataSize = 4; // tangent S
// Normalizing cube map
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
}
if( hasEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
}
if( hasVertexColor || hasVertexAlpha )
{
flags |= VERTEX_COLOR;
}
pShaderShadow->EnableSRGBWrite( true );
if( bHasSelfIllumMap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
}
if( bHasFlowMap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
Assert( hasBump );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( vortwarp_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_VERTEX_SHADER( vortwarp_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( vortwarp_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, hasBaseTexture );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSELIGHTING, !params[info.m_nUnlit]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( TRANSLUCENT, blendType == BT_BLEND );
SET_STATIC_PIXEL_SHADER( vortwarp_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( vortwarp_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, hasBaseTexture );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSELIGHTING, !params[info.m_nUnlit]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( TRANSLUCENT, blendType == BT_BLEND );
SET_STATIC_PIXEL_SHADER( vortwarp_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( vortwarp_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_VERTEX_SHADER( vortwarp_vs30 );
DECLARE_STATIC_PIXEL_SHADER( vortwarp_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, hasBaseTexture );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSELIGHTING, !params[info.m_nUnlit]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( TRANSLUCENT, blendType == BT_BLEND );
SET_STATIC_PIXEL_SHADER( vortwarp_ps30 );
}
#endif
if( hasFlashlight )
{
pShader->FogToBlack();
}
else
{
pShader->DefaultFog();
}
if( blendType == BT_BLEND )
{
pShaderShadow->EnableBlending( true );
pShaderShadow->BlendFunc( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaWrites( false );
}
else
{
pShaderShadow->EnableAlphaWrites( true );
}
}
else
{
bool hasEnvmap = !hasFlashlight && params[info.m_nEnvmap]->IsTexture();
bool hasEnvmapMask = !hasFlashlight && params[info.m_nEnvmapMask]->IsTexture();
if( hasBaseTexture )
{
pShader->BindTexture( SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
if( hasEnvmap )
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nEnvmap, info.m_nEnvmapFrame );
}
if( hasDetailTexture )
{
pShader->BindTexture( SHADER_SAMPLER2, info.m_nDetail, info.m_nDetailFrame );
}
if( !g_pConfig->m_bFastNoBump )
{
if( hasBump )
{
pShader->BindTexture( SHADER_SAMPLER3, info.m_nBumpmap, info.m_nBumpFrame );
}
}
else
{
if( hasBump )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
}
}
if( hasEnvmapMask )
{
pShader->BindTexture( SHADER_SAMPLER4, info.m_nEnvmapMask, info.m_nEnvmapMaskFrame );
}
if( hasFlashlight )
{
Assert( info.m_nFlashlightTexture >= 0 && info.m_nFlashlightTextureFrame >= 0 );
pShader->BindTexture( SHADER_SAMPLER7, info.m_nFlashlightTexture, info.m_nFlashlightTextureFrame );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
SetFlashLightColorFromState( state, pShaderAPI );
}
// Set up light combo state
LightState_t lightState = {0, false, false};
if ( bVertexLitGeneric && !hasFlashlight )
{
pShaderAPI->GetDX9LightState( &lightState );
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int fogIndex = ( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z ) ? 1 : 0;
int numBones = pShaderAPI->GetCurrentNumBones();
Assert( hasBump );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( vortwarp_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, numBones > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( vortwarp_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( vortwarp_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z &&
blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
float warpParam = params[info.m_nWarpParam]->GetFloatValue();
// float selfIllumTint = params[info.m_nSelfIllumTint]->GetFloatValue();
// DevMsg( 1, "warpParam: %f %f\n", warpParam, selfIllumTint );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WARPINGIN, warpParam > 0.0f && warpParam < 1.0f );
SET_DYNAMIC_PIXEL_SHADER( vortwarp_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( vortwarp_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z &&
blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
float warpParam = params[info.m_nWarpParam]->GetFloatValue();
// float selfIllumTint = params[info.m_nSelfIllumTint]->GetFloatValue();
// DevMsg( 1, "warpParam: %f %f\n", warpParam, selfIllumTint );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WARPINGIN, warpParam > 0.0f && warpParam < 1.0f );
SET_DYNAMIC_PIXEL_SHADER( vortwarp_ps20 );
}
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( vortwarp_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, numBones > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( vortwarp_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( vortwarp_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z &&
blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
float warpParam = params[info.m_nWarpParam]->GetFloatValue();
// float selfIllumTint = params[info.m_nSelfIllumTint]->GetFloatValue();
// DevMsg( 1, "warpParam: %f %f\n", warpParam, selfIllumTint );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WARPINGIN, warpParam > 0.0f && warpParam < 1.0f );
SET_DYNAMIC_PIXEL_SHADER( vortwarp_ps30 );
}
#endif
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
if( hasDetailTexture )
{
pShader->SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBaseTextureTransform, info.m_nDetailScale );
Assert( !hasBump );
}
if( hasBump )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
Assert( !hasDetailTexture );
}
if( hasEnvmapMask )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nEnvmapMaskTransform );
}
if( hasEnvmap )
{
pShader->SetEnvMapTintPixelShaderDynamicState( 0, info.m_nEnvmapTint, -1, true );
}
if( ( info.m_nHDRColorScale != -1 ) && pShader->IsHDREnabled() )
{
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace_LinearScale( 1, params[info.m_nHDRColorScale]->GetFloatValue() );
}
else
{
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
}
pShader->SetPixelShaderConstant( 2, info.m_nEnvmapContrast );
pShader->SetPixelShaderConstant( 3, info.m_nEnvmapSaturation );
pShader->SetPixelShaderConstant( 4, info.m_nSelfIllumTint );
pShader->SetAmbientCubeDynamicStateVertexShader();
if( hasBump )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
pShaderAPI->SetPixelShaderStateAmbientLightCube( 5 );
pShaderAPI->CommitPixelShaderLighting( 13 );
}
if( bHasSelfIllumMap )
{
pShader->BindTexture( SHADER_SAMPLER6, info.m_nSelfIllumMap, -1 );
}
if( bHasFlowMap )
{
pShader->BindTexture( SHADER_SAMPLER2, info.m_nFlowMap, -1 );
}
float eyePos[4];
pShaderAPI->GetWorldSpaceCameraPosition( eyePos );
pShaderAPI->SetPixelShaderConstant( 20, eyePos, 1 );
pShaderAPI->SetPixelShaderFogParams( 21 );
// dynamic drawing code that extends vertexlitgeneric
float curTime = params[info.m_nWarpParam]->GetFloatValue();
float timeVec[4] = { 0.0f, 0.0f, 0.0f, curTime };
Assert( params[info.m_nEntityOrigin]->IsDefined() );
params[info.m_nEntityOrigin]->GetVecValue( timeVec, 3 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, timeVec, 1 );
curTime = pShaderAPI->CurrentTime();
timeVec[0] = curTime;
timeVec[1] = curTime;
timeVec[2] = curTime;
timeVec[3] = curTime;
pShaderAPI->SetPixelShaderConstant( 22, timeVec, 1 );
// flashlightfixme: put this in common code.
if( hasFlashlight )
{
VMatrix worldToTexture;
const FlashlightState_t &flashlightState = pShaderAPI->GetFlashlightState( worldToTexture );
// Set the flashlight attenuation factors
float atten[4];
atten[0] = flashlightState.m_fConstantAtten;
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( 22, atten, 1 );
// Set the flashlight origin
float pos[4];
pos[0] = flashlightState.m_vecLightOrigin[0];
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pos[3] = 1.0f;
pShaderAPI->SetPixelShaderConstant( 23, pos, 1 );
pShaderAPI->SetPixelShaderConstant( 24, worldToTexture.Base(), 4 );
}
}
pShader->Draw();
}
void DrawPassShadowPass( const defParms_shadow &info, CBaseVSShader *pShader, IMaterialVar **params,
IShaderShadow* pShaderShadow, IShaderDynamicAPI* pShaderAPI,
VertexCompressionType_t vertexCompression, CDeferredPerMaterialContextData *pDeferredContext )
{
const bool bModel = info.bModel;
const bool bIsDecal = IS_FLAG_SET( MATERIAL_VAR_DECAL );
const bool bFastVTex = g_pHardwareConfig->HasFastVertexTextures();
const bool bNoCull = IS_FLAG_SET( MATERIAL_VAR_NOCULL );
const bool bAlbedo = PARM_TEX( info.iAlbedo );
const bool bAlbedo2 = PARM_TEX( info.iAlbedo2 );
const bool bAlbedo3 = PARM_TEX( info.iAlbedo3 );
const bool bAlbedo4 = PARM_TEX( info.iAlbedo4 );
const bool bAlphatest = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) && bAlbedo;
const bool bMultiBlend = PARM_SET( info.iMultiblend ) && bAlbedo && bAlbedo2 && bAlbedo3;
const bool bBaseTexture2 = !bMultiBlend && bAlbedo2;
SHADOW_STATE
{
pShaderShadow->SetDefaultState();
pShaderShadow->EnableSRGBWrite( false );
if ( bNoCull )
{
pShaderShadow->EnableCulling( false );
}
int iVFmtFlags = VERTEX_POSITION | VERTEX_NORMAL;
int iUserDataSize = 0;
int *pTexCoordDim;
int iTexCoordNum;
GetTexcoordSettings( ( bModel && bIsDecal && bFastVTex ), bMultiBlend,
iTexCoordNum, &pTexCoordDim );
if ( bModel )
{
iVFmtFlags |= VERTEX_FORMAT_COMPRESSED;
}
#ifndef DEFCFG_ENABLE_RADIOSITY
if ( bAlphatest )
#endif
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
if ( bBaseTexture2 || bMultiBlend )
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if ( bMultiBlend )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
}
}
pShaderShadow->VertexShaderVertexFormat( iVFmtFlags, iTexCoordNum, pTexCoordDim, iUserDataSize );
DECLARE_STATIC_VERTEX_SHADER( shadowpass_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bModel );
SET_STATIC_VERTEX_SHADER_COMBO( MORPHING_VTEX, bModel && bFastVTex );
SET_STATIC_VERTEX_SHADER_COMBO( MULTITEXTURE, bMultiBlend ? 2 : bBaseTexture2 ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( shadowpass_vs30 );
DECLARE_STATIC_PIXEL_SHADER( shadowpass_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( ALPHATEST, bAlphatest );
SET_STATIC_PIXEL_SHADER_COMBO( MULTITEXTURE, bMultiBlend ? 2 : bBaseTexture2 ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( shadowpass_ps30 );
}
DYNAMIC_STATE
{
Assert( pDeferredContext != NULL );
const int shadowMode = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_DEFERRED_SHADOW_MODE );
const int radiosityOutput = DEFCFG_ENABLE_RADIOSITY != 0
&& pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_DEFERRED_SHADOW_RADIOSITY );
if ( pDeferredContext->m_bMaterialVarsChanged || !pDeferredContext->HasCommands( CDeferredPerMaterialContextData::DEFSTAGE_SHADOW ) )
{
tmpBuf.Reset();
if ( bAlphatest )
{
PARM_VALIDATE( info.iAlphatestRef );
tmpBuf.SetPixelShaderConstant1( 0, PARM_FLOAT( info.iAlphatestRef ) );
#ifndef DEFCFG_ENABLE_RADIOSITY
tmpBuf.BindTexture( pShader, SHADER_SAMPLER0, info.iAlbedo );
#endif
}
#if DEFCFG_ENABLE_RADIOSITY
if ( bAlbedo )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER0, info.iAlbedo );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
if ( bBaseTexture2 || bMultiBlend )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER1, info.iAlbedo2 );
if ( bMultiBlend )
{
tmpBuf.BindTexture( pShader, SHADER_SAMPLER2, info.iAlbedo3 );
if ( bAlbedo4 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER3, info.iAlbedo4 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_WHITE );
}
#endif
tmpBuf.End();
pDeferredContext->SetCommands( CDeferredPerMaterialContextData::DEFSTAGE_SHADOW, tmpBuf.Copy() );
}
pShaderAPI->SetDefaultState();
if ( bModel && bFastVTex )
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( shadowpass_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (bModel && (int)vertexCompression) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, (bModel && pShaderAPI->GetCurrentNumBones() > 0) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, (bModel && pShaderAPI->IsHWMorphingEnabled()) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SHADOW_MODE, shadowMode );
SET_DYNAMIC_VERTEX_SHADER_COMBO( RADIOSITY, radiosityOutput );
SET_DYNAMIC_VERTEX_SHADER( shadowpass_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( shadowpass_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( SHADOW_MODE, shadowMode );
SET_DYNAMIC_PIXEL_SHADER_COMBO( RADIOSITY, radiosityOutput );
SET_DYNAMIC_PIXEL_SHADER( shadowpass_ps30 );
if ( bModel && bFastVTex )
{
bool bUnusedTexCoords[3] = { false, true, !pShaderAPI->IsHWMorphingEnabled() || !bIsDecal };
pShaderAPI->MarkUnusedVertexFields( 0, 3, bUnusedTexCoords );
}
pShaderAPI->ExecuteCommandBuffer( pDeferredContext->GetCommands( CDeferredPerMaterialContextData::DEFSTAGE_SHADOW ) );
switch ( shadowMode )
{
case DEFERRED_SHADOW_MODE_ORTHO:
{
CommitShadowcastingConstants_Ortho( pShaderAPI,
pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_DEFERRED_SHADOW_INDEX ),
VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, VERTEX_SHADER_SHADER_SPECIFIC_CONST_1,
VERTEX_SHADER_SHADER_SPECIFIC_CONST_2
);
}
break;
case DEFERRED_SHADOW_MODE_PROJECTED:
{
CommitShadowcastingConstants_Proj( pShaderAPI,
pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_DEFERRED_SHADOW_INDEX ),
VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, VERTEX_SHADER_SHADER_SPECIFIC_CONST_1,
VERTEX_SHADER_SHADER_SPECIFIC_CONST_2
);
}
break;
}
#ifdef SHADOWMAPPING_USE_COLOR
CommitViewVertexShader( pShaderAPI, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7 );
#endif
}
pShader->Draw();
}
void DrawRefract_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, Refract_DX9_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool bIsModel = IS_FLAG_SET( MATERIAL_VAR_MODEL );
bool bHasEnvmap = params[info.m_nEnvmap]->IsTexture();
bool bRefractTintTexture = params[info.m_nRefractTintTexture]->IsTexture();
bool bFadeOutOnSilhouette = params[info.m_nFadeOutOnSilhouette]->GetIntValue() != 0;
int blurAmount = params[info.m_nBlurAmount]->GetIntValue();
bool bMasked = (params[info.m_nMasked]->GetIntValue() != 0);
bool bSecondaryNormal = ( ( info.m_nNormalMap2 != -1 ) && ( params[info.m_nNormalMap2]->IsTexture() ) );
bool bColorModulate = ( ( info.m_nVertexColorModulate != -1 ) && ( params[info.m_nVertexColorModulate]->GetIntValue() ) );
bool bWriteZ = params[info.m_nNoWriteZ]->GetIntValue() == 0;
if( blurAmount < 0 )
{
blurAmount = 0;
}
else if( blurAmount > MAXBLUR )
{
blurAmount = MAXBLUR;
}
BlendType_t nBlendType = pShader->EvaluateBlendRequirements( BASETEXTURE, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !IS_FLAG_SET(MATERIAL_VAR_ALPHATEST); //dest alpha is free for special use
bFullyOpaque &= !bMasked;
bool bTranslucentNormal = pShader->TextureIsTranslucent( info.m_nNormalMap, false );
bFullyOpaque &= (! bTranslucentNormal );
NormalDecodeMode_t nNormalDecodeMode = NORMAL_DECODE_NONE;
if ( g_pHardwareConfig->SupportsNormalMapCompression() )
{
ITexture *pBumpTex = params[info.m_nNormalMap]->GetTextureValue();
if ( pBumpTex )
{
nNormalDecodeMode = pBumpTex->GetNormalDecodeMode();
if ( bSecondaryNormal ) // Check encoding of secondary normal if there is one
{
ITexture *pBumpTex2 = params[info.m_nNormalMap2]->GetTextureValue();
if ( pBumpTex2 && ( pBumpTex2->GetNormalDecodeMode() != nNormalDecodeMode ) )
{
DevMsg("Refract: Primary and Secondary normal map compression formats don't match. This is unsupported!\n");
Assert(0);
}
}
}
}
SHADOW_STATE
{
pShader->SetInitialShadowState( );
pShaderShadow->EnableDepthWrites( bWriteZ );
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( IS_FLAG_SET(MATERIAL_VAR_ALPHATEST) );
// If envmap is not specified, the alpha channel is the translucency
// (If envmap *is* specified, alpha channel is the reflection amount)
if ( params[info.m_nNormalMap]->IsTexture() && !bHasEnvmap )
{
pShader->SetDefaultBlendingShadowState( info.m_nNormalMap, false );
}
// source render target that contains the image that we are warping.
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
// normal map
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Normal map alpha, in the compressed normal case
}
if ( bSecondaryNormal )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Secondary normal map alpha, in the compressed normal case
}
}
if( bHasEnvmap )
{
// envmap
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true );
}
if( bRefractTintTexture )
{
// refract tint texture
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true );
}
pShaderShadow->EnableSRGBWrite( true );
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int userDataSize = 0;
int nTexCoordCount = 1;
if( bIsModel )
{
userDataSize = 4;
}
else
{
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T;
}
if ( bColorModulate )
{
flags |= VERTEX_COLOR;
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
DECLARE_STATIC_VERTEX_SHADER( jl_refract_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_VERTEX_SHADER( jl_refract_vs20 );
// We have to do this in the shader on R500 or Leopard
bool bShaderSRGBConvert = IsOSX() && ( g_pHardwareConfig->FakeSRGBWrite() || !g_pHardwareConfig->CanDoSRGBReadFromRTs() );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() || g_pHardwareConfig->ShouldAlwaysUseShaderModel2bShaders() ) // always send OpenGL down the ps2b path
{
DECLARE_STATIC_PIXEL_SHADER( jl_refract_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( BLUR, blurAmount );
SET_STATIC_PIXEL_SHADER_COMBO( FADEOUTONSILHOUETTE, bFadeOutOnSilhouette );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACTTINTTEXTURE, bRefractTintTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKED, bMasked );
SET_STATIC_PIXEL_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_PIXEL_SHADER_COMBO( SECONDARY_NORMAL, bSecondaryNormal );
SET_STATIC_PIXEL_SHADER_COMBO( NORMAL_DECODE_MODE, (int) nNormalDecodeMode );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSRGBConvert );
SET_STATIC_PIXEL_SHADER( jl_refract_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( jl_refract_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( BLUR, blurAmount );
SET_STATIC_PIXEL_SHADER_COMBO( FADEOUTONSILHOUETTE, bFadeOutOnSilhouette );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACTTINTTEXTURE, bRefractTintTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKED, bMasked );
SET_STATIC_PIXEL_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_PIXEL_SHADER_COMBO( SECONDARY_NORMAL, bSecondaryNormal );
SET_STATIC_PIXEL_SHADER_COMBO( NORMAL_DECODE_MODE, (int) nNormalDecodeMode );
SET_STATIC_PIXEL_SHADER( jl_refract_ps20 );
}
pShader->DefaultFog();
if( bMasked )
{
pShader->EnableAlphaBlending( SHADER_BLEND_ONE_MINUS_SRC_ALPHA, SHADER_BLEND_SRC_ALPHA );
}
bool bAlphaWrites = bFullyOpaque || ( params[ info.m_nForceAlphaWrite ]->GetIntValue() != 0 );
pShaderShadow->EnableAlphaWrites( bAlphaWrites );
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
if ( params[info.m_nBaseTexture]->IsTexture() )
{
pShader->BindTexture( SHADER_SAMPLER2, info.m_nBaseTexture, info.m_nFrame );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 );
}
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShader->BindTexture( SHADER_SAMPLER3, SHADER_SAMPLER6, info.m_nNormalMap, info.m_nBumpFrame );
}
else
{
pShader->BindTexture( SHADER_SAMPLER3, info.m_nNormalMap, info.m_nBumpFrame );
}
if ( bSecondaryNormal )
{
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShader->BindTexture( SHADER_SAMPLER1, SHADER_SAMPLER7, info.m_nNormalMap2, info.m_nBumpFrame2 );
}
else
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nNormalMap2, info.m_nBumpFrame2 );
}
}
if( bHasEnvmap )
{
pShader->BindTexture( SHADER_SAMPLER4, info.m_nEnvmap, info.m_nEnvmapFrame );
}
if( bRefractTintTexture )
{
pShader->BindTexture( SHADER_SAMPLER5, info.m_nRefractTintTexture, info.m_nRefractTintTextureFrame );
}
DECLARE_DYNAMIC_VERTEX_SHADER( jl_refract_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( jl_refract_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() || g_pHardwareConfig->ShouldAlwaysUseShaderModel2bShaders() ) // always send Posix down the ps2b path
{
DECLARE_DYNAMIC_PIXEL_SHADER( jl_refract_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteZ && bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( jl_refract_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( jl_refract_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( jl_refract_ps20 );
}
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, info.m_nBumpTransform ); // 1 & 2
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.m_nBumpTransform2 ); // 3 & 4
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
float vEyePos_SpecExponent[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
vEyePos_SpecExponent[3] = 0.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
pShader->SetPixelShaderConstantGammaToLinear( 0, info.m_nEnvmapTint );
pShader->SetPixelShaderConstantGammaToLinear( 1, info.m_nRefractTint );
pShader->SetPixelShaderConstant( 2, info.m_nEnvmapContrast );
pShader->SetPixelShaderConstant( 3, info.m_nEnvmapSaturation );
float c5[4] = { params[info.m_nRefractAmount]->GetFloatValue(),
params[info.m_nRefractAmount]->GetFloatValue(), 0.0f, 0.0f };
// Time % 1000
c5[3] = pShaderAPI->CurrentTime();
c5[3] -= (float)( (int)( c5[3] / 1000.0f ) ) * 1000.0f;
pShaderAPI->SetPixelShaderConstant( 5, c5, 1 );
float cVs3[4] = { c5[3], 0.0f, 0.0f, 0.0f };
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, cVs3, 1 );
}
pShader->Draw();
}
inline void DrawPass( IMaterialVar **params, IShaderShadow* pShaderShadow,
IShaderDynamicAPI* pShaderAPI, int nPass, VertexCompressionType_t vertexCompression )
{
bool bIsModel = IS_FLAG_SET( MATERIAL_VAR_MODEL );
bool bHasEnvmap = params[ENVMAP]->IsTexture();
bool bHasFlowmap = params[FLOWMAP]->IsTexture();
bool bHasCoreColorTexture = params[CORECOLORTEXTURE]->IsTexture();
SHADOW_STATE
{
SetInitialShadowState( );
if( nPass == 0 )
{
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( IS_FLAG_SET(MATERIAL_VAR_ALPHATEST) );
}
else
{
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
EnableAlphaBlending( SHADER_BLEND_ONE, SHADER_BLEND_ONE );
}
// If envmap is not specified, the alpha channel is the translucency
// (If envmap *is* specified, alpha channel is the reflection amount)
if ( params[NORMALMAP]->IsTexture() && !bHasEnvmap )
{
SetDefaultBlendingShadowState( NORMALMAP, false );
}
// source render target that contains the image that we are warping.
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_INTEGER )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
}
// normal map
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if( bHasEnvmap )
{
// envmap
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_INTEGER )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true );
}
}
if( bHasFlowmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
}
if( bHasCoreColorTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
}
if( g_pHardwareConfig->GetHDRType() != HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBWrite( true );
}
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int userDataSize = 0;
int nTexCoordCount = 1;
if( bIsModel )
{
userDataSize = 4;
}
else
{
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T;
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
DECLARE_STATIC_VERTEX_SHADER( sdk_core_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER( sdk_core_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( sdk_core_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap && ( nPass == 1 ) );
SET_STATIC_PIXEL_SHADER_COMBO( FLOWMAP, bHasFlowmap );
SET_STATIC_PIXEL_SHADER_COMBO( CORECOLORTEXTURE, bHasCoreColorTexture && ( nPass == 0 ) );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACT, nPass == 0 );
SET_STATIC_PIXEL_SHADER( sdk_core_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_core_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap && ( nPass == 1 ) );
SET_STATIC_PIXEL_SHADER_COMBO( FLOWMAP, bHasFlowmap );
SET_STATIC_PIXEL_SHADER_COMBO( CORECOLORTEXTURE, bHasCoreColorTexture && ( nPass == 0 ) );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACT, nPass == 0 );
SET_STATIC_PIXEL_SHADER( sdk_core_ps20 );
}
DefaultFog();
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
if ( params[BASETEXTURE]->IsTexture() )
{
BindTexture( SHADER_SAMPLER2, BASETEXTURE, FRAME );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 );
}
BindTexture( SHADER_SAMPLER3, NORMALMAP, BUMPFRAME );
if( bHasEnvmap )
{
BindTexture( SHADER_SAMPLER4, ENVMAP, ENVMAPFRAME );
}
if( bHasFlowmap )
{
BindTexture( SHADER_SAMPLER6, FLOWMAP, FLOWMAPFRAME );
}
if( bHasCoreColorTexture )
{
BindTexture( SHADER_SAMPLER7, CORECOLORTEXTURE, CORECOLORTEXTUREFRAME );
}
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_core_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_core_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_core_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_core_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_core_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_core_ps20 );
}
SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, BUMPTRANSFORM );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
SetPixelShaderConstant( 0, ENVMAPTINT );
SetPixelShaderConstant( 1, REFRACTTINT );
}
else
{
SetPixelShaderConstantGammaToLinear( 0, ENVMAPTINT );
SetPixelShaderConstantGammaToLinear( 1, REFRACTTINT );
}
SetPixelShaderConstant( 2, ENVMAPCONTRAST );
SetPixelShaderConstant( 3, ENVMAPSATURATION );
float c5[4] = { params[REFRACTAMOUNT]->GetFloatValue(),
params[REFRACTAMOUNT]->GetFloatValue(), 0.0f, 0.0f };
pShaderAPI->SetPixelShaderConstant( 5, c5, 1 );
float eyePos[4];
s_pShaderAPI->GetWorldSpaceCameraPosition( eyePos );
s_pShaderAPI->SetPixelShaderConstant( 8, eyePos, 1 );
pShaderAPI->SetPixelShaderFogParams( 11 );
if( bHasFlowmap )
{
float curTime = pShaderAPI->CurrentTime();
float timeVec[4] = { curTime, curTime, curTime, curTime };
pShaderAPI->SetPixelShaderConstant( 6, timeVec, 1 );
SetPixelShaderConstant( 7, FLOWMAPSCROLLRATE );
SetPixelShaderConstant( 9, FLOWMAPTEXCOORDOFFSET );
}
}
Draw();
}
//-----------------------------------------------------------------------------
// Draws the shader
//-----------------------------------------------------------------------------
void DrawSkin_DX9_Internal( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow,
bool bHasFlashlight, VertexLitGeneric_DX9_Vars_t &info, VertexCompressionType_t vertexCompression,
CBasePerMaterialContextData **pContextDataPtr )
{
bool bHasBaseTexture = (info.m_nBaseTexture != -1) && params[info.m_nBaseTexture]->IsTexture();
bool bHasBump = (info.m_nBumpmap != -1) && params[info.m_nBumpmap]->IsTexture();
bool bHasBaseTextureWrinkle = bHasBaseTexture &&
(info.m_nWrinkle != -1) && params[info.m_nWrinkle]->IsTexture() &&
(info.m_nStretch != -1) && params[info.m_nStretch]->IsTexture();
bool bHasBumpWrinkle = bHasBump &&
(info.m_nNormalWrinkle != -1) && params[info.m_nNormalWrinkle]->IsTexture() &&
(info.m_nNormalStretch != -1) && params[info.m_nNormalStretch]->IsTexture();
bool bHasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool bHasVertexAlpha = IS_FLAG_SET( MATERIAL_VAR_VERTEXALPHA );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
bool bHasSelfIllum = IS_FLAG_SET( MATERIAL_VAR_SELFILLUM ) != 0;
bool bHasSelfIllumFresnel = ( bHasSelfIllum ) && ( info.m_nSelfIllumFresnel != -1 ) && ( params[info.m_nSelfIllumFresnel]->GetIntValue() != 0 );
bool bHasSelfIllumMask = ( bHasSelfIllum ) && (info.m_nSelfIllumMask != -1) && params[info.m_nSelfIllumMask]->IsTexture();
// Tie these to specular
bool bHasPhong = (info.m_nPhong != -1) && ( params[info.m_nPhong]->GetIntValue() != 0 );
bool bHasSpecularExponentTexture = (info.m_nPhongExponentTexture != -1) && params[info.m_nPhongExponentTexture]->IsTexture();
bool bHasPhongTintMap = bHasSpecularExponentTexture && (info.m_nPhongAlbedoTint != -1) && ( params[info.m_nPhongAlbedoTint]->GetIntValue() != 0 );
bool bHasDiffuseWarp = (info.m_nDiffuseWarpTexture != -1) && params[info.m_nDiffuseWarpTexture]->IsTexture();
bool bHasPhongWarp = (info.m_nPhongWarpTexture != -1) && params[info.m_nPhongWarpTexture]->IsTexture();
bool bHasNormalMapAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
#if !defined( _X360 )
bool bIsDecal = IS_FLAG_SET( MATERIAL_VAR_DECAL );
#endif
// Rimlight must be set to non-zero to trigger rim light combo (also requires Phong)
bool bHasRimLight = r_rimlight.GetBool() && bHasPhong && (info.m_nRimLight != -1) && ( params[info.m_nRimLight]->GetIntValue() != 0 );
bool bHasRimMaskMap = bHasSpecularExponentTexture && bHasRimLight && (info.m_nRimMask != -1) && ( params[info.m_nRimMask]->GetIntValue() != 0 );
float fBlendFactor=( info.m_nDetailTextureBlendFactor == -1 )? 1 : params[info.m_nDetailTextureBlendFactor]->GetFloatValue();
bool hasDetailTexture = ( info.m_nDetail != -1 ) && params[info.m_nDetail]->IsTexture();
int nDetailBlendMode = ( hasDetailTexture && info.m_nDetailTextureCombineMode != -1 ) ? params[info.m_nDetailTextureCombineMode]->GetIntValue() : 0;
bool bBlendTintByBaseAlpha = IsBoolSet( info.m_nBlendTintByBaseAlpha, params ) && !bHasSelfIllum; // Pixel shader can't do both BLENDTINTBYBASEALPHA and SELFILLUM, so let selfillum win
float flTintReplacementAmount = GetFloatParam( info.m_nTintReplacesBaseColor, params );
BlendType_t nBlendType= pShader->EvaluateBlendRequirements( bBlendTintByBaseAlpha ? -1 : info.m_nBaseTexture, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !bIsAlphaTested && !bHasFlashlight; //dest alpha is free for special use
CSkin_DX9_Context *pContextData = reinterpret_cast< CSkin_DX9_Context *> ( *pContextDataPtr );
if ( ! pContextData )
{
pContextData = new CSkin_DX9_Context;
*pContextDataPtr = pContextData;
}
if( pShader->IsSnapshotting() )
{
// look at color and alphamod stuff.
// Unlit generic never uses the flashlight
bool bHasEnvmap = !bHasFlashlight && params[info.m_nEnvmap]->IsTexture();
bool bHasNormal = params[info.m_nBumpmap]->IsTexture();
bool bCanUseBaseAlphaPhongMaskFastPath = (info.m_nBaseMapAlphaPhongMask != -1) && ( params[info.m_nBaseMapAlphaPhongMask]->GetIntValue() != 0 );
if ( ! ( params[info.m_nBaseTexture]->GetTextureValue()->IsTranslucent() ) )
bCanUseBaseAlphaPhongMaskFastPath = true;
pContextData->m_bFastPath =
(! bHasBump ) &&
(! bHasSpecularExponentTexture ) &&
(! bHasPhongTintMap ) &&
(! bHasPhongWarp ) &&
(! bHasRimLight ) &&
(! hasDetailTexture ) &&
bCanUseBaseAlphaPhongMaskFastPath &&
(! bHasSelfIllum ) &&
(! bBlendTintByBaseAlpha );
// Alpha test: FIXME: shouldn't this be handled in CBaseVSShader::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
int nShadowFilterMode = 0;
if( bHasFlashlight )
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetAdditiveBlendingShadowState( info.m_nBaseTexture, true );
}
if( bIsAlphaTested )
{
// disable alpha test and use the zfunc zequals since alpha isn't guaranteed to
// be the same on both the regular pass and the flashlight pass.
pShaderShadow->EnableAlphaTest( false );
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
}
pShaderShadow->EnableBlending( true );
pShaderShadow->EnableDepthWrites( false );
// Be sure not to write to dest alpha
pShaderShadow->EnableAlphaWrites( false );
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
else // not flashlight pass
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetDefaultBlendingShadowState( info.m_nBaseTexture, true );
}
if ( bHasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true ); // Cubic environment map
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, true );
}
}
}
unsigned int flags = VERTEX_POSITION;
if( bHasNormal )
{
flags |= VERTEX_NORMAL;
}
int userDataSize = 0;
// Always enable...will bind white if nothing specified...
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Base (albedo) map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
if ( bHasBaseTextureWrinkle || bHasBumpWrinkle )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true ); // Base (albedo) compression map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER9, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true ); // Base (albedo) expansion map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER10, true );
}
if( bHasDiffuseWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Diffuse warp texture
}
if( bHasPhongWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Specular warp texture
}
// Specular exponent map or dummy
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Specular exponent map
if( bHasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER4 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Noise map
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Flashlight cookie
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, true );
userDataSize = 4; // tangent S
}
// Always enable, since flat normal will be bound
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Normal map
userDataSize = 4; // tangent S
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Normalizing cube map
if ( bHasBaseTextureWrinkle || bHasBumpWrinkle )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true ); // Normal compression map
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true ); // Normal expansion map
}
if ( hasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
if ( nDetailBlendMode != 0 ) //Not Mod2X
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER13, true );
}
if ( bHasSelfIllum )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
}
if( bHasVertexColor || bHasVertexAlpha )
{
flags |= VERTEX_COLOR;
}
pShaderShadow->EnableSRGBWrite( true );
// texcoord0 : base texcoord, texcoord2 : decal hw morph delta
int pTexCoordDim[3] = { 2, 0, 3 };
int nTexCoordCount = 1;
#ifndef _X360
// Special morphed decal information
if ( bIsDecal && g_pHardwareConfig->HasFastVertexTextures() )
{
nTexCoordCount = 3;
}
#endif
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, pTexCoordDim, userDataSize );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
bool bUseStaticControlFlow = g_pHardwareConfig->SupportsStaticControlFlow();
DECLARE_STATIC_VERTEX_SHADER( skin_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( USE_STATIC_CONTROL_FLOW, bUseStaticControlFlow );
SET_STATIC_VERTEX_SHADER( skin_vs20 );
// Assume we're only going to get in here if we support 2b
DECLARE_STATIC_PIXEL_SHADER( skin_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, bHasSelfIllum && !bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUMFRESNEL, bHasSelfIllumFresnel && !bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bHasDiffuseWarp && bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGWARPTEXTURE, bHasPhongWarp && bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( WRINKLEMAP, bHasBaseTextureWrinkle || bHasBumpWrinkle );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHT, bHasRimLight );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( CONVERT_TO_SRGB, 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FASTPATH_NOBUMP, pContextData->m_bFastPath );
SET_STATIC_PIXEL_SHADER_COMBO( BLENDTINTBYBASEALPHA, bBlendTintByBaseAlpha );
SET_STATIC_PIXEL_SHADER( skin_ps20b );
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( skin_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( DECAL, bIsDecal );
SET_STATIC_VERTEX_SHADER( skin_vs30 );
DECLARE_STATIC_PIXEL_SHADER( skin_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, bHasSelfIllum && !bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUMFRESNEL, bHasSelfIllumFresnel && !bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bHasDiffuseWarp && bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGWARPTEXTURE, bHasPhongWarp && bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( WRINKLEMAP, bHasBaseTextureWrinkle || bHasBumpWrinkle );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHT, bHasRimLight );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( CONVERT_TO_SRGB, 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FASTPATH_NOBUMP, pContextData->m_bFastPath );
SET_STATIC_PIXEL_SHADER_COMBO( BLENDTINTBYBASEALPHA, bBlendTintByBaseAlpha );
SET_STATIC_PIXEL_SHADER( skin_ps30 );
}
#endif
if( bHasFlashlight )
{
pShader->FogToBlack();
}
else
{
pShader->DefaultFog();
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for underwater stuff
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
}
else // not snapshotting -- begin dynamic state
{
bool bLightingOnly = mat_fullbright.GetInt() == 2 && !IS_FLAG_SET( MATERIAL_VAR_NO_DEBUG_OVERRIDE );
bool bHasEnvmap = !bHasFlashlight && params[info.m_nEnvmap]->IsTexture();
if( bHasBaseTexture )
{
pShader->BindTexture( SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
if ( bHasBaseTextureWrinkle )
{
pShader->BindTexture( SHADER_SAMPLER9, info.m_nWrinkle, info.m_nBaseTextureFrame );
pShader->BindTexture( SHADER_SAMPLER10, info.m_nStretch, info.m_nBaseTextureFrame );
}
else if ( bHasBumpWrinkle )
{
pShader->BindTexture( SHADER_SAMPLER9, info.m_nBaseTexture, info.m_nBaseTextureFrame );
pShader->BindTexture( SHADER_SAMPLER10, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
if( bHasDiffuseWarp && bHasPhong )
{
if ( r_lightwarpidentity.GetBool() )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_IDENTITY_LIGHTWARP );
}
else
{
pShader->BindTexture( SHADER_SAMPLER2, info.m_nDiffuseWarpTexture );
}
}
if( bHasPhongWarp )
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nPhongWarpTexture );
}
if( bHasSpecularExponentTexture && bHasPhong )
{
pShader->BindTexture( SHADER_SAMPLER7, info.m_nPhongExponentTexture );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER7, TEXTURE_WHITE );
}
if( !g_pConfig->m_bFastNoBump )
{
if( bHasBump )
pShader->BindTexture( SHADER_SAMPLER3, info.m_nBumpmap, info.m_nBumpFrame );
else
pShaderAPI->BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
if ( bHasBumpWrinkle )
{
pShader->BindTexture( SHADER_SAMPLER11, info.m_nNormalWrinkle, info.m_nBumpFrame );
pShader->BindTexture( SHADER_SAMPLER12, info.m_nNormalStretch, info.m_nBumpFrame );
}
else if ( bHasBaseTextureWrinkle )
{
pShader->BindTexture( SHADER_SAMPLER11, info.m_nBumpmap, info.m_nBumpFrame );
pShader->BindTexture( SHADER_SAMPLER12, info.m_nBumpmap, info.m_nBumpFrame );
}
}
else
{
if( bHasBump )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
}
if ( bHasBaseTextureWrinkle || bHasBumpWrinkle )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER11, TEXTURE_NORMALMAP_FLAT );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER12, TEXTURE_NORMALMAP_FLAT );
}
}
if ( hasDetailTexture )
{
pShader->BindTexture( SHADER_SAMPLER13, info.m_nDetail, info.m_nDetailFrame );
}
if ( bHasSelfIllum )
{
if ( bHasSelfIllumMask ) // Separate texture for self illum?
{
pShader->BindTexture( SHADER_SAMPLER14, info.m_nSelfIllumMask ); // Bind it
}
else // else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER14, TEXTURE_BLACK ); // Bind dummy
}
}
LightState_t lightState = { 0, false, false };
bool bFlashlightShadows = false;
if( bHasFlashlight )
{
Assert( info.m_nFlashlightTexture >= 0 && info.m_nFlashlightTextureFrame >= 0 );
pShader->BindTexture( SHADER_SAMPLER6, info.m_nFlashlightTexture, info.m_nFlashlightTextureFrame );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
bFlashlightShadows = state.m_bEnableShadows && ( pFlashlightDepthTexture != NULL );
SetFlashLightColorFromState( state, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && state.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER4, pFlashlightDepthTexture, 0 );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_SHADOW_NOISE_2D );
}
}
else // no flashlight
{
if ( bHasEnvmap )
{
pShader->BindTexture( SHADER_SAMPLER8, info.m_nEnvmap, info.m_nEnvmapFrame );
}
pShaderAPI->GetDX9LightState( &lightState );
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int fogIndex = ( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z ) ? 1 : 0;
int numBones = pShaderAPI->GetCurrentNumBones();
// don't have an easy way to get this through to GLM, so just print it old school
//printf("\n-D- DrawSkin_DX9_Internal numBones is %d", numBones );
bool bWriteDepthToAlpha = false;
bool bWriteWaterFogToAlpha = false;
if( bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
bool bUseStaticControlFlow = g_pHardwareConfig->SupportsStaticControlFlow();
DECLARE_DYNAMIC_VERTEX_SHADER( skin_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, numBones > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING)!=0);
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, bUseStaticControlFlow ? 0 : lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER( skin_vs20 );
DECLARE_DYNAMIC_PIXEL_SHADER( skin_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( skin_ps20b );
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( skin_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, numBones > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING)!=0);
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( skin_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( skin_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( skin_ps30 );
bool bUnusedTexCoords[3] = { false, false, !pShaderAPI->IsHWMorphingEnabled() || !bIsDecal };
pShaderAPI->MarkUnusedVertexFields( 0, 3, bUnusedTexCoords );
}
#endif
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
if( bHasBump )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
}
if ( hasDetailTexture )
{
if ( IS_PARAM_DEFINED( info.m_nDetailTextureTransform ) )
pShader->SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4,
info.m_nDetailTextureTransform,
info.m_nDetailScale );
else
pShader->SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4,
info.m_nBaseTextureTransform,
info.m_nDetailScale );
}
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
pShader->SetPixelShaderConstant_W( PSREG_SELFILLUMTINT, info.m_nSelfIllumTint, fBlendFactor );
bool bInvertPhongMask = ( info.m_nInvertPhongMask != -1 ) && ( params[info.m_nInvertPhongMask]->GetIntValue() != 0 );
float fInvertPhongMask = bInvertPhongMask ? 1 : 0;
bool bHasBaseAlphaPhongMask = (info.m_nBaseMapAlphaPhongMask != -1) && ( params[info.m_nBaseMapAlphaPhongMask]->GetIntValue() != 0 );
float fHasBaseAlphaPhongMask = bHasBaseAlphaPhongMask ? 1 : 0;
// Controls for lerp-style paths through shader code
float vShaderControls[4] = { fHasBaseAlphaPhongMask, 0.0f/*unused*/, flTintReplacementAmount, fInvertPhongMask };
pShaderAPI->SetPixelShaderConstant( PSREG_CONSTANT_27, vShaderControls, 1 );
if ( hasDetailTexture )
{
#if 0 // needs constant change
if ( info.m_nDetailTint != -1 )
pShader->SetPixelShaderConstantGammaToLinear( 10, info.m_nDetailTint );
else
{
float boring_tint[4]={1,1,1,1};
pShaderAPI->SetPixelShaderConstant( 10, boring_tint, 1 );
}
#endif
}
if ( bHasSelfIllumFresnel && !bHasFlashlight )
{
float vConstScaleBiasExp[4] = { 1.0f, 0.0f, 1.0f, 0.0f };
float flMin = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[0] : 0.0f;
float flMax = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[1] : 1.0f;
float flExp = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[2] : 1.0f;
vConstScaleBiasExp[1] = ( flMax != 0.0f ) ? ( flMin / flMax ) : 0.0f; // Bias
vConstScaleBiasExp[0] = 1.0f - vConstScaleBiasExp[1]; // Scale
vConstScaleBiasExp[2] = flExp; // Exp
vConstScaleBiasExp[3] = flMax; // Brightness
pShaderAPI->SetPixelShaderConstant( PSREG_SELFILLUM_SCALE_BIAS_EXP, vConstScaleBiasExp, 1 );
}
pShader->SetAmbientCubeDynamicStateVertexShader();
if( !bHasFlashlight )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
// Setting .x to 1 means to apply Fresnel to env map. Setting w to 1 means use separate selfillummask
float vEnvMapFresnel_SelfIllumMask[4] = {0.0f, 0.0f, 0.0f, 0.0f};
vEnvMapFresnel_SelfIllumMask[3] = bHasSelfIllumMask ? 1.0f : 0.0f;
if( bHasEnvmap )
{
float vEnvMapTint_MaskControl[4] = {1.0f, 1.0f, 1.0f, 0.0f};
// If we have a tint, grab it
if ( (info.m_nEnvmapTint != -1) && params[info.m_nEnvmapTint]->IsDefined() )
params[info.m_nEnvmapTint]->GetVecValue(vEnvMapTint_MaskControl, 3);
// Set control for source of env map mask (normal alpha or base alpha)
vEnvMapTint_MaskControl[3] = bHasNormalMapAlphaEnvmapMask ? 1.0f : 0.0f;
if ( (info.m_nEnvmapFresnel != -1) && params[info.m_nEnvmapFresnel]->IsDefined() )
vEnvMapFresnel_SelfIllumMask[0] = params[info.m_nEnvmapFresnel]->GetFloatValue();
// Handle mat_fullbright 2 (diffuse lighting only with 50% gamma space basetexture)
if( bLightingOnly )
{
vEnvMapTint_MaskControl[0] = vEnvMapTint_MaskControl[1] = vEnvMapTint_MaskControl[2] = 0.0f;
}
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, vEnvMapTint_MaskControl, 1 );
}
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_FRESNEL__SELFILLUMMASK, vEnvMapFresnel_SelfIllumMask, 1 );
}
pShaderAPI->SetPixelShaderStateAmbientLightCube( PSREG_AMBIENT_CUBE, !lightState.m_bAmbientLight ); // Force to black if not bAmbientLight
pShaderAPI->CommitPixelShaderLighting( PSREG_LIGHT_INFO_ARRAY );
// Pack Phong exponent in with the eye position
float vEyePos_SpecExponent[4], vFresnelRanges_SpecBoost[4] = {1, 0.5, 1, 1}, vRimBoost[4] = {1, 1, 1, 1};
float vSpecularTint[4] = {1, 1, 1, 4};
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
// Use the alpha channel of the normal map for the exponent by default
vEyePos_SpecExponent[3] = -1.f;
if ( (info.m_nPhongExponent != -1) && params[info.m_nPhongExponent]->IsDefined() )
{
float fValue = params[info.m_nPhongExponent]->GetFloatValue();
if ( fValue > 0.f )
{
// Nonzero value in material overrides map channel
vEyePos_SpecExponent[3] = fValue;
}
}
// Get the tint parameter
if ( (info.m_nPhongTint != -1) && params[info.m_nPhongTint]->IsDefined() )
{
params[info.m_nPhongTint]->GetVecValue(vSpecularTint, 3);
}
// Get the rim light power (goes in w of Phong tint)
if ( bHasRimLight && (info.m_nRimLightPower != -1) && params[info.m_nRimLightPower]->IsDefined() )
{
vSpecularTint[3] = params[info.m_nRimLightPower]->GetFloatValue();
vSpecularTint[3] = max(vSpecularTint[3], 1.0f); // Make sure this is at least 1
}
// Get the rim boost (goes in w of flashlight position)
if ( bHasRimLight && (info.m_nRimLightBoost != -1) && params[info.m_nRimLightBoost]->IsDefined() )
{
vRimBoost[3] = params[info.m_nRimLightBoost]->GetFloatValue();
}
if ( !bHasFlashlight )
{
float vRimMaskControl[4] = {0, 0, 0, 0}; // Only x is relevant in shader code
vRimMaskControl[0] = bHasRimMaskMap ? params[info.m_nRimMask]->GetFloatValue() : 0.0f;
// Rim mask...if this is true, use alpha channel of spec exponent texture to mask the rim term
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, vRimMaskControl, 1 );
}
// If it's all zeros, there was no constant tint in the vmt
if ( (vSpecularTint[0] == 0.0f) && (vSpecularTint[1] == 0.0f) && (vSpecularTint[2] == 0.0f) )
{
if ( bHasPhongTintMap ) // If we have a map to use, tell the shader
{
vSpecularTint[0] = -1;
}
else // Otherwise, just tint with white
{
vSpecularTint[0] = 1.0f;
vSpecularTint[1] = 1.0f;
vSpecularTint[2] = 1.0f;
}
}
// handle mat_fullbright 2 (diffuse lighting only)
if( bLightingOnly )
{
// BASETEXTURE
if( bHasSelfIllum && !bHasFlashlight )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY_ALPHA_ZERO );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
}
// DETAILTEXTURE
if ( hasDetailTexture )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER13, TEXTURE_GREY );
}
// turn off specularity
vSpecularTint[0] = vSpecularTint[1] = vSpecularTint[2] = 0.0f;
}
if ( (info.m_nPhongFresnelRanges != -1) && params[info.m_nPhongFresnelRanges]->IsDefined() )
{
params[info.m_nPhongFresnelRanges]->GetVecValue( vFresnelRanges_SpecBoost, 3 ); // Grab optional Fresnel range parameters
// Change fresnel range encoding from (min, mid, max) to ((mid-min)*2, mid, (max-mid)*2)
vFresnelRanges_SpecBoost[0] = (vFresnelRanges_SpecBoost[1] - vFresnelRanges_SpecBoost[0]) * 2;
vFresnelRanges_SpecBoost[2] = (vFresnelRanges_SpecBoost[2] - vFresnelRanges_SpecBoost[1]) * 2;
}
if ( (info.m_nPhongBoost != -1 ) && params[info.m_nPhongBoost]->IsDefined()) // Grab optional Phong boost param
vFresnelRanges_SpecBoost[3] = params[info.m_nPhongBoost]->GetFloatValue();
else
vFresnelRanges_SpecBoost[3] = 1.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_FRESNEL_SPEC_PARAMS, vFresnelRanges_SpecBoost, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, vRimBoost, 1 ); // Rim boost in w on non-flashlight pass
pShaderAPI->SetPixelShaderConstant( PSREG_SPEC_RIM_PARAMS, vSpecularTint, 1 );
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
// flashlightfixme: put this in common code.
if( bHasFlashlight )
{
VMatrix worldToTexture;
float atten[4], pos[4], tweaks[4];
const FlashlightState_t &flashlightState = pShaderAPI->GetFlashlightState( worldToTexture );
SetFlashLightColorFromState( flashlightState, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
pShader->BindTexture( SHADER_SAMPLER6, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
atten[0] = flashlightState.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, atten, 1 );
pos[0] = flashlightState.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, pos, 1 ); // steps on rim boost
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_TO_WORLD_TEXTURE, worldToTexture.Base(), 4 );
// Tweaks associated with a given flashlight
tweaks[0] = ShadowFilterFromState( flashlightState );
tweaks[1] = ShadowAttenFromState( flashlightState );
pShader->HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
vScreenScale[0] = (float) nWidth / 32.0f;
vScreenScale[1] = (float) nHeight / 32.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
if ( IsX360() )
{
pShaderAPI->SetBooleanPixelShaderConstant( 0, &flashlightState.m_nShadowQuality, 1 );
}
}
}
pShader->Draw();
}
inline void DrawReflectionRefraction( IMaterialVar **params, IShaderShadow* pShaderShadow,
IShaderDynamicAPI* pShaderAPI, bool bReflection, bool bRefraction )
{
BlendType_t nBlendType = EvaluateBlendRequirements( BASETEXTURE, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !IS_FLAG_SET(MATERIAL_VAR_ALPHATEST); //dest alpha is free for special use
SHADOW_STATE
{
SetInitialShadowState( );
if( bRefraction )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_INTEGER )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
}
}
if( bReflection )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_INTEGER )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
}
}
if( params[BASETEXTURE]->IsTexture() )
{
// BASETEXTURE
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
// LIGHTMAP
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if ( params[ENVMAPMASK]->IsTexture() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
}
}
// normal map
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
int fmt = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_TANGENT_S | VERTEX_TANGENT_T;
// texcoord0 : base texcoord
// texcoord1 : lightmap texcoord
// texcoord2 : lightmap texcoord offset
int numTexCoords = 1;
if( params[BASETEXTURE]->IsTexture() )
{
numTexCoords = 3;
}
pShaderShadow->VertexShaderVertexFormat( fmt, numTexCoords, 0, 0 );
if ( IS_FLAG_SET(MATERIAL_VAR_TRANSLUCENT ) )
{
EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
}
DECLARE_STATIC_VERTEX_SHADER( sdk_lightmappedreflective_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( BASETEXTURE, params[BASETEXTURE]->IsTexture() );
SET_STATIC_VERTEX_SHADER( sdk_lightmappedreflective_vs20 );
// "REFLECT" "0..1"
// "REFRACT" "0..1"
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( REFLECT, bReflection );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACT, bRefraction );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, params[BASETEXTURE]->IsTexture() );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, params[ENVMAPMASK]->IsTexture() && params[BASETEXTURE]->IsTexture() );
SET_STATIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( REFLECT, bReflection );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACT, bRefraction );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, params[BASETEXTURE]->IsTexture() );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, params[ENVMAPMASK]->IsTexture() && params[BASETEXTURE]->IsTexture() );
SET_STATIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20 );
}
FogToFogColor();
if( g_pHardwareConfig->GetHDRType() != HDR_TYPE_NONE )
{
// we are writing linear values from this shader.
pShaderShadow->EnableSRGBWrite( true );
}
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
}
DYNAMIC_STATE
{
if( bRefraction )
{
// HDRFIXME: add comment about binding.. Specify the number of MRTs in the enable
BindTexture( SHADER_SAMPLER0, REFRACTTEXTURE, -1 );
}
if( bReflection )
{
BindTexture( SHADER_SAMPLER2, REFLECTTEXTURE, -1 );
}
BindTexture( SHADER_SAMPLER4, NORMALMAP, BUMPFRAME );
if( params[BASETEXTURE]->IsTexture() )
{
BindTexture( SHADER_SAMPLER1, BASETEXTURE, FRAME );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER3, TEXTURE_LIGHTMAP );
SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, BASETEXTURETRANSFORM );
if ( params[ENVMAPMASK]->IsTexture() )
{
BindTexture( SHADER_SAMPLER6, ENVMAPMASK, ENVMAPMASKFRAME );
}
}
// Refraction tint
if( bRefraction )
{
SetPixelShaderConstantGammaToLinear( 1, REFRACTTINT );
}
// Reflection tint
if( bReflection )
{
SetPixelShaderConstantGammaToLinear( 4, REFLECTTINT );
}
SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, BUMPTRANSFORM );
float c0[4] = { 1.0f / 3.0f, 1.0f / 3.0f, 1.0f / 3.0f, 0.0f };
pShaderAPI->SetPixelShaderConstant( 0, c0, 1 );
float c2[4] = { 0.5f, 0.5f, 0.5f, 0.5f };
pShaderAPI->SetPixelShaderConstant( 2, c2, 1 );
// fresnel constants
float flFresnelFactor = params[MAXREFLECTIVITY]->GetFloatValue() - params[MINREFLECTIVITY]->GetFloatValue();
float c3[4] = { flFresnelFactor, params[FRESNELPOWER]->GetFloatValue(), params[MINREFLECTIVITY]->GetFloatValue(), 0.0f };
pShaderAPI->SetPixelShaderConstant( 3, c3, 1 );
float c5[4] = { params[REFLECTAMOUNT]->GetFloatValue(), params[REFLECTAMOUNT]->GetFloatValue(),
params[REFRACTAMOUNT]->GetFloatValue(), params[REFRACTAMOUNT]->GetFloatValue() };
pShaderAPI->SetPixelShaderConstant( 5, c5, 1 );
pShaderAPI->SetPixelShaderFogParams( 8 );
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_lightmappedreflective_vs20 );
SET_DYNAMIC_VERTEX_SHADER( sdk_lightmappedreflective_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_lightmappedreflective_ps20 );
}
}
Draw();
}
void DrawPassGBuffer( const defParms_gBuffer &info, CBaseVSShader *pShader, IMaterialVar **params,
IShaderShadow* pShaderShadow, IShaderDynamicAPI* pShaderAPI,
VertexCompressionType_t vertexCompression, CDeferredPerMaterialContextData *pDeferredContext )
{
const bool bDeferredShading = DEFCFG_DEFERRED_SHADING == 1;
const bool bModel = info.bModel;
const bool bIsDecal = IS_FLAG_SET( MATERIAL_VAR_DECAL );
const bool bFastVTex = g_pHardwareConfig->HasFastVertexTextures();
const bool bNoCull = IS_FLAG_SET( MATERIAL_VAR_NOCULL );
const bool bAlbedo = PARM_TEX( info.iAlbedo );
const bool bAlbedo2 = bDeferredShading && PARM_TEX( info.iAlbedo2 );
const bool bAlbedo3 = bDeferredShading && PARM_TEX( info.iAlbedo3 );
const bool bAlbedo4 = bDeferredShading && PARM_TEX( info.iAlbedo4 );
const bool bBumpmap = PARM_TEX( info.iBumpmap );
const bool bBumpmap2 = bBumpmap && PARM_TEX( info.iBumpmap2 );
const bool bBumpmap3 = bBumpmap && PARM_TEX( info.iBumpmap3 );
const bool bBumpmap4 = bBumpmap && PARM_TEX( info.iBumpmap4 );
const bool bPhongmap = PARM_TEX( info.iPhongmap );
const bool bMultiBlend = PARM_SET( info.iMultiblend );
const bool bMultiBlendBump = bMultiBlend && bBumpmap;
const bool bBlendmodulate = ( bAlbedo2 || bBumpmap2 || bMultiBlendBump ) && PARM_TEX( info.iBlendmodulate );
const bool bBlendmodulate2 = bBlendmodulate && PARM_TEX( info.iBlendmodulate2 );
const bool bBlendmodulate3 = bBlendmodulate && PARM_TEX( info.iBlendmodulate3 );
const bool bAlphatest = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) && bAlbedo;
const bool bTranslucent = IS_FLAG_SET( MATERIAL_VAR_TRANSLUCENT ) && bAlbedo && bIsDecal;
const bool bSSBump = bBumpmap && PARM_SET( info.iSSBump );
Assert( !bIsDecal || bDeferredShading );
Assert( !bTranslucent || bDeferredShading );
SHADOW_STATE
{
pShaderShadow->SetDefaultState();
pShaderShadow->EnableSRGBWrite( false );
if ( bNoCull )
{
pShaderShadow->EnableCulling( false );
}
int iVFmtFlags = VERTEX_POSITION | VERTEX_NORMAL;
int iUserDataSize = 0;
int *pTexCoordDim;
int iTexCoordNum;
GetTexcoordSettings( ( bModel && bIsDecal && bFastVTex ), bMultiBlend,
iTexCoordNum, &pTexCoordDim );
if ( bModel )
{
iVFmtFlags |= VERTEX_FORMAT_COMPRESSED;
}
else
{
if ( bBumpmap2 || bAlbedo2 )
iVFmtFlags |= VERTEX_COLOR;
}
if ( bAlphatest || bDeferredShading )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, false );
}
if ( bBumpmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false );
if ( bModel )
iUserDataSize = 4;
else
{
iVFmtFlags |= VERTEX_TANGENT_SPACE;
}
}
if ( bPhongmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, false );
}
if ( bAlbedo2 || bBumpmap2 || bMultiBlendBump )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if ( bAlbedo2 )
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true );
if ( bBlendmodulate )
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
}
if ( bMultiBlendBump )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
if ( bDeferredShading )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true );
}
if ( bBlendmodulate )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true );
}
}
pShaderShadow->EnableAlphaWrites( true );
pShaderShadow->VertexShaderVertexFormat( iVFmtFlags, iTexCoordNum, pTexCoordDim, iUserDataSize );
if ( bTranslucent )
{
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
}
DECLARE_STATIC_VERTEX_SHADER( gbuffer_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bModel );
SET_STATIC_VERTEX_SHADER_COMBO( MORPHING_VTEX, bModel && bFastVTex );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, bBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP2, bBumpmap2 && !bMultiBlend );
SET_STATIC_VERTEX_SHADER_COMBO( BLENDMODULATE, bBlendmodulate );
SET_STATIC_VERTEX_SHADER_COMBO( MULTIBLEND, bMultiBlendBump );
SET_STATIC_VERTEX_SHADER( gbuffer_vs30 );
#if DEFCFG_DEFERRED_SHADING == 1
DECLARE_STATIC_PIXEL_SHADER( gbuffer_defshading_ps30 );
#else
DECLARE_STATIC_PIXEL_SHADER( gbuffer_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP2, bBumpmap2 && !bMultiBlend );
#endif
SET_STATIC_PIXEL_SHADER_COMBO( ALPHATEST, bAlphatest );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bBumpmap ? bSSBump ? 2 : 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( NOCULL, bNoCull );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGMAP, bPhongmap );
SET_STATIC_PIXEL_SHADER_COMBO( BLENDMODULATE, bBlendmodulate );
SET_STATIC_PIXEL_SHADER_COMBO( MULTIBLEND, bMultiBlendBump );
#if DEFCFG_DEFERRED_SHADING == 1
SET_STATIC_PIXEL_SHADER_COMBO( TWOTEXTURE, (bAlbedo2 || bBumpmap2) && !bMultiBlend );
SET_STATIC_PIXEL_SHADER_COMBO( DECAL, bIsDecal );
SET_STATIC_PIXEL_SHADER( gbuffer_defshading_ps30 );
#else
SET_STATIC_PIXEL_SHADER( gbuffer_ps30 );
#endif
}
DYNAMIC_STATE
{
Assert( pDeferredContext != NULL );
if ( pDeferredContext->m_bMaterialVarsChanged || !pDeferredContext->HasCommands( CDeferredPerMaterialContextData::DEFSTAGE_GBUFFER ) )
{
tmpBuf.Reset();
if ( bAlphatest )
{
PARM_VALIDATE( info.iAlphatestRef );
tmpBuf.SetPixelShaderConstant1( 0, PARM_FLOAT( info.iAlphatestRef ) );
}
if ( bAlphatest || bDeferredShading )
{
if ( bAlbedo )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER0, info.iAlbedo );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
}
if ( bBumpmap )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER1, info.iBumpmap );
if ( bPhongmap )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER2, info.iPhongmap );
else
{
float flPhongExp[2] = { 0 };
flPhongExp[0] = clamp( PARM_FLOAT( info.iPhongExp ), 0, 1 ) * 63.0f;
if ( bBumpmap2 || bAlbedo2 )
{
PARM_VALIDATE( info.iPhongExp2 );
flPhongExp[1] = clamp( PARM_FLOAT( info.iPhongExp2 ), 0, 1 ) * 63.0f;
tmpBuf.SetPixelShaderConstant2( 2, flPhongExp[0], flPhongExp[1] );
}
else
tmpBuf.SetPixelShaderConstant1( 2, flPhongExp[0] );
}
if ( bAlbedo2 || bBumpmap2 || bMultiBlendBump )
{
if ( bBumpmap2 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER3, info.iBumpmap2 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
if ( bAlbedo2 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER9, info.iAlbedo2 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER9, TEXTURE_GREY );
if ( bBlendmodulate )
{
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.iBlendmodulateTransform );
tmpBuf.BindTexture( pShader, SHADER_SAMPLER4, info.iBlendmodulate );
}
}
if ( bMultiBlendBump )
{
if ( bBumpmap3 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER5, info.iBumpmap3 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALMAP_FLAT );
if ( bBumpmap4 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER6, info.iBumpmap4 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER6, TEXTURE_NORMALMAP_FLAT );
if ( bAlbedo3 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER10, info.iAlbedo3 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER10, TEXTURE_GREY );
if ( bAlbedo4 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER11, info.iAlbedo4 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER11, TEXTURE_GREY );
if ( bBlendmodulate )
{
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, info.iBlendmodulateTransform2 );
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, info.iBlendmodulateTransform3 );
if ( bBlendmodulate2 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER7, info.iBlendmodulate2 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER7, TEXTURE_BLACK );
if ( bBlendmodulate3 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER8, info.iBlendmodulate3 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER8, TEXTURE_BLACK );
}
}
tmpBuf.SetPixelShaderConstant2( 1,
IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT ) ? 1.0f : 0.0f,
PARM_SET( info.iLitface ) ? 1.0f : 0.0f );
tmpBuf.End();
pDeferredContext->SetCommands( CDeferredPerMaterialContextData::DEFSTAGE_GBUFFER, tmpBuf.Copy() );
}
pShaderAPI->SetDefaultState();
if ( bModel && bFastVTex )
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( gbuffer_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (bModel && (int)vertexCompression) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, (bModel && pShaderAPI->GetCurrentNumBones() > 0) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, (bModel && pShaderAPI->IsHWMorphingEnabled()) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER( gbuffer_vs30 );
#if DEFCFG_DEFERRED_SHADING == 1
DECLARE_DYNAMIC_PIXEL_SHADER( gbuffer_defshading_ps30 );
SET_DYNAMIC_PIXEL_SHADER( gbuffer_defshading_ps30 );
#else
DECLARE_DYNAMIC_PIXEL_SHADER( gbuffer_ps30 );
SET_DYNAMIC_PIXEL_SHADER( gbuffer_ps30 );
#endif
if ( bModel && bFastVTex )
{
bool bUnusedTexCoords[3] = { false, true, !pShaderAPI->IsHWMorphingEnabled() || !bIsDecal };
pShaderAPI->MarkUnusedVertexFields( 0, 3, bUnusedTexCoords );
}
float vPos[4] = {0,0,0,0};
pShaderAPI->GetWorldSpaceCameraPosition( vPos );
float zScale[4] = {GetDeferredExt()->GetZScale(),0,0,0};
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, vPos );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, GetDeferredExt()->GetForwardBase() );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, zScale );
pShader->LoadViewMatrixIntoVertexShaderConstant( VERTEX_SHADER_AMBIENT_LIGHT );
pShaderAPI->ExecuteCommandBuffer( pDeferredContext->GetCommands( CDeferredPerMaterialContextData::DEFSTAGE_GBUFFER ) );
}
pShader->Draw();
}
void DrawRefract_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, Refract_DX9_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool bIsModel = IS_FLAG_SET( MATERIAL_VAR_MODEL );
bool bHasEnvmap = params[info.m_nEnvmap]->IsTexture();
bool bRefractTintTexture = params[info.m_nRefractTintTexture]->IsTexture();
bool bFadeOutOnSilhouette = params[info.m_nFadeOutOnSilhouette]->GetIntValue() != 0;
int blurAmount = params[info.m_nBlurAmount]->GetIntValue();
bool bMasked = (params[info.m_nMasked]->GetIntValue() != 0);
bool bSecondaryNormal = ( ( info.m_nNormalMap2 != -1 ) && ( params[info.m_nNormalMap2]->IsTexture() ) );
bool bColorModulate = ( ( info.m_nVertexColorModulate != -1 ) && ( params[info.m_nVertexColorModulate]->GetIntValue() ) );
bool bWriteZ = params[info.m_nNoWriteZ]->GetIntValue() == 0;
bool bMirrorAboutViewportEdges = IsX360() && ( info.m_nMirrorAboutViewportEdges != -1 ) && ( params[info.m_nMirrorAboutViewportEdges]->GetIntValue() != 0 );
bool bUseMagnification = params[info.m_nMagnifyEnable]->GetIntValue() != 0;
if( blurAmount < 0 )
{
blurAmount = 0;
}
else if( blurAmount > MAXBLUR )
{
blurAmount = MAXBLUR;
}
BlendType_t nBlendType = pShader->EvaluateBlendRequirements( BASETEXTURE, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !IS_FLAG_SET(MATERIAL_VAR_ALPHATEST); //dest alpha is free for special use
bFullyOpaque &= !bMasked;
bool bTranslucentNormal = pShader->TextureIsTranslucent( info.m_nNormalMap, false );
bFullyOpaque &= (! bTranslucentNormal );
SHADOW_STATE
{
pShader->SetInitialShadowState( );
pShaderShadow->EnableDepthWrites( bWriteZ );
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( IS_FLAG_SET(MATERIAL_VAR_ALPHATEST) );
// If envmap is not specified, the alpha channel is the translucency
// (If envmap *is* specified, alpha channel is the reflection amount)
if ( params[info.m_nNormalMap]->IsTexture() && !bHasEnvmap )
{
pShader->SetDefaultBlendingShadowState( info.m_nNormalMap, false );
}
// source render target that contains the image that we are warping.
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, !IsX360() );
// normal map
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if ( bSecondaryNormal )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
}
if( bHasEnvmap )
{
// envmap
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true );
}
if( bRefractTintTexture )
{
// refract tint texture
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true );
}
pShaderShadow->EnableSRGBWrite( true );
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int userDataSize = 0;
int nTexCoordCount = 1;
if( bIsModel )
{
userDataSize = 4;
}
else
{
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T;
}
if ( bColorModulate )
{
flags |= VERTEX_COLOR;
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
DECLARE_STATIC_VERTEX_SHADER( refract_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_VERTEX_SHADER( refract_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( refract_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( BLUR, blurAmount );
SET_STATIC_PIXEL_SHADER_COMBO( FADEOUTONSILHOUETTE, bFadeOutOnSilhouette );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACTTINTTEXTURE, bRefractTintTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKED, bMasked );
SET_STATIC_PIXEL_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_PIXEL_SHADER_COMBO( SECONDARY_NORMAL, bSecondaryNormal );
SET_STATIC_PIXEL_SHADER_COMBO( MIRRORABOUTVIEWPORTEDGES, bMirrorAboutViewportEdges );
SET_STATIC_PIXEL_SHADER_COMBO( MAGNIFY, bUseMagnification );
SET_STATIC_PIXEL_SHADER( refract_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( refract_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( BLUR, blurAmount );
SET_STATIC_PIXEL_SHADER_COMBO( FADEOUTONSILHOUETTE, bFadeOutOnSilhouette );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( REFRACTTINTTEXTURE, bRefractTintTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKED, bMasked );
SET_STATIC_PIXEL_SHADER_COMBO( COLORMODULATE, bColorModulate );
SET_STATIC_PIXEL_SHADER_COMBO( SECONDARY_NORMAL, bSecondaryNormal );
SET_STATIC_PIXEL_SHADER_COMBO( MIRRORABOUTVIEWPORTEDGES, bMirrorAboutViewportEdges );
SET_STATIC_PIXEL_SHADER_COMBO( MAGNIFY, bUseMagnification );
SET_STATIC_PIXEL_SHADER( refract_ps20 );
}
pShader->DefaultFog();
if( bMasked )
{
pShader->EnableAlphaBlending( SHADER_BLEND_ONE_MINUS_SRC_ALPHA, SHADER_BLEND_SRC_ALPHA );
}
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
if ( params[info.m_nBaseTexture]->IsTexture() )
{
pShader->BindTexture( SHADER_SAMPLER2, info.m_nBaseTexture, info.m_nFrame );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 );
}
pShader->BindTexture( SHADER_SAMPLER3, info.m_nNormalMap, info.m_nBumpFrame );
if ( bSecondaryNormal )
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nNormalMap2, info.m_nBumpFrame2 );
}
if( bHasEnvmap )
{
pShader->BindTexture( SHADER_SAMPLER4, info.m_nEnvmap, info.m_nEnvmapFrame );
}
if( bRefractTintTexture )
{
pShader->BindTexture( SHADER_SAMPLER5, info.m_nRefractTintTexture, info.m_nRefractTintTextureFrame );
}
DECLARE_DYNAMIC_VERTEX_SHADER( refract_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( refract_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( refract_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteZ && bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( refract_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( refract_ps20 );
SET_DYNAMIC_PIXEL_SHADER( refract_ps20 );
}
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, info.m_nBumpTransform ); // 1 & 2
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.m_nBumpTransform2 ); // 3 & 4
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
float vEyePos_SpecExponent[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
vEyePos_SpecExponent[3] = 0.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
pShader->SetPixelShaderConstantGammaToLinear( 0, info.m_nEnvmapTint );
pShader->SetPixelShaderConstantGammaToLinear( 1, info.m_nRefractTint );
pShader->SetPixelShaderConstant( 2, info.m_nEnvmapContrast );
pShader->SetPixelShaderConstant( 3, info.m_nEnvmapSaturation );
float c5[4] = { params[info.m_nRefractAmount]->GetFloatValue(),
params[info.m_nRefractAmount]->GetFloatValue(), 0.0f, 0.0f };
// Time % 1000
c5[3] = pShaderAPI->CurrentTime();
c5[3] -= (float)( (int)( c5[3] / 1000.0f ) ) * 1000.0f;
pShaderAPI->SetPixelShaderConstant( 5, c5, 1 );
float c6[4];
params[info.m_nMagnifyCenter]->GetVecValue( c6, 2 );
c6[2] = params[info.m_nMagnifyScale]->GetFloatValue();
if ( c6[2] != 0 )
{
c6[2] = 1.0f / c6[2]; // Shader uses the inverse scale value
}
pShaderAPI->SetPixelShaderConstant( 6, c6, 1 );
float cVs3[4] = { c5[3], 0.0f, 0.0f, 0.0f };
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, cVs3, 1 );
// Get viewport and render target dimensions and set shader constant to do a 2D mad and also deal with mirror on viewport edges.
int nViewportX, nViewportY, nViewportWidth, nViewportHeight;
pShaderAPI->GetCurrentViewport( nViewportX, nViewportY, nViewportWidth, nViewportHeight );
int nRtWidth, nRtHeight;
pShaderAPI->GetCurrentRenderTargetDimensions( nRtWidth, nRtHeight );
float vViewportMad[4] = { 1.0f, 1.0f, 0.0f, 0.0f };
if ( params[ info.m_nNoViewportFixup ]->GetIntValue() == 0 )
{
vViewportMad[0] = ( float )nViewportWidth / ( float )nRtWidth;
vViewportMad[1] = ( float )nViewportHeight / ( float )nRtHeight;
vViewportMad[2] = ( float )nViewportX / ( float )nRtWidth;
vViewportMad[3] = ( float )nViewportY / ( float )nRtHeight;
}
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, vViewportMad, 1 );
if ( bMirrorAboutViewportEdges )
{
// Need the extents that we are allowed to sample from the refract texture to clamp by for splitscreen, etc.
float vNormalizedViewportMinXYMaxWZ[4];
vNormalizedViewportMinXYMaxWZ[0] = ( float )( nViewportX + REFRACT_VIEWPORT_SHRINK_PIXELS ) / ( float )nRtWidth;
vNormalizedViewportMinXYMaxWZ[1] = ( float )( nViewportY + REFRACT_VIEWPORT_SHRINK_PIXELS ) / ( float )nRtHeight;
vNormalizedViewportMinXYMaxWZ[3] = ( float )( nViewportX + nViewportWidth - REFRACT_VIEWPORT_SHRINK_PIXELS - 1 ) / ( float )nRtWidth;
vNormalizedViewportMinXYMaxWZ[2] = ( float )( nViewportY + nViewportHeight - REFRACT_VIEWPORT_SHRINK_PIXELS - 1 ) / ( float )nRtHeight;
pShaderAPI->SetPixelShaderConstant( 4, vNormalizedViewportMinXYMaxWZ, 1 );
}
}
pShader->Draw();
}
void DrawLightmappedGeneric_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow,
LightmappedGeneric_DX9_Vars_t &info, CBasePerMaterialContextData **pContextDataPtr, bool bDeferredActive )
{
//bool bDeferredActive = GetDeferredExt()->IsDeferredLightingEnabled();
bool bSinglePassFlashlight = true;
bool hasFlashlight = !bDeferredActive && pShader->UsingFlashlight( params );
CLightmappedGeneric_DX9_Context *pContextData = reinterpret_cast< CLightmappedGeneric_DX9_Context *> ( *pContextDataPtr );
bool bShaderSrgbRead = ( IsX360() && IS_PARAM_DEFINED( info.m_nShaderSrgbRead360 ) && params[info.m_nShaderSrgbRead360]->GetIntValue() );
const bool bHasFoW = true; //( ( info.m_nFoW != -1 ) && ( params[ info.m_nFoW ]->IsTexture() != 0 ) );
if ( pShaderShadow || ( ! pContextData )|| pContextData->m_bMaterialVarsChanged || pContextData->m_bNeedsCmdRegen || ( hasFlashlight && !IsX360() ) )
{
bool hasBaseTexture = params[info.m_nBaseTexture]->IsTexture();
int nAlphaChannelTextureVar = hasBaseTexture ? (int)info.m_nBaseTexture : (int)info.m_nEnvmapMask;
BlendType_t nBlendType = pShader->EvaluateBlendRequirements( nAlphaChannelTextureVar, hasBaseTexture );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
bool bFullyOpaqueWithoutAlphaTest = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && (!hasFlashlight || IsX360()); //dest alpha is free for special use
bool bFullyOpaque = bFullyOpaqueWithoutAlphaTest && !bIsAlphaTested;
bool bNeedRegenStaticCmds = (! pContextData ) || pShaderShadow || pContextData->m_bNeedsCmdRegen;
if ( ! pContextData ) // make sure allocated
{
pContextData = new CLightmappedGeneric_DX9_Context;
*pContextDataPtr = pContextData;
}
bool hasBump = ( params[info.m_nBumpmap]->IsTexture() ) && g_pConfig->UseBumpmapping();
bool hasSSBump = hasBump && (info.m_nSelfShadowedBumpFlag != -1) && ( params[info.m_nSelfShadowedBumpFlag]->GetIntValue() );
bool hasBaseTexture2 = hasBaseTexture && params[info.m_nBaseTexture2]->IsTexture();
bool hasLightWarpTexture = params[info.m_nLightWarpTexture]->IsTexture();
bool hasBump2 = hasBump && params[info.m_nBumpmap2]->IsTexture();
bool hasDetailTexture = params[info.m_nDetail]->IsTexture();
bool hasSelfIllum = IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
bool hasBumpMask = hasBump && hasBump2 && params[info.m_nBumpMask]->IsTexture() && !hasSelfIllum &&
!hasDetailTexture && !hasBaseTexture2 && (params[info.m_nBaseTextureNoEnvmap]->GetIntValue() == 0);
bool bHasBlendModulateTexture =
(info.m_nBlendModulateTexture != -1) &&
(params[info.m_nBlendModulateTexture]->IsTexture() );
bool hasNormalMapAlphaEnvmapMask = g_pConfig->UseSpecular() && IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
if( g_pConfig->bEditMode )
{
hasBump = false;
hasBump2 = false;
}
bool bParallaxMapping = false;
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
bParallaxMapping = ( info.m_nParallaxMap != -1 ) && ( params[info.m_nParallaxMap]->GetIntValue() != 0 );
if ( hasFlashlight && !IsX360() )
{
// !!speed!! do this in the caller so we don't build struct every time
CBaseVSShader::DrawFlashlight_dx90_Vars_t vars;
vars.m_bBump = hasBump;
vars.m_nBumpmapVar = info.m_nBumpmap;
vars.m_nBumpmapFrame = info.m_nBumpFrame;
vars.m_nBumpTransform = info.m_nBumpTransform;
vars.m_nFlashlightTextureVar = info.m_nFlashlightTexture;
vars.m_nFlashlightTextureFrameVar = info.m_nFlashlightTextureFrame;
vars.m_bLightmappedGeneric = true;
vars.m_bWorldVertexTransition = hasBaseTexture2;
vars.m_nBaseTexture2Var = info.m_nBaseTexture2;
vars.m_nBaseTexture2FrameVar = info.m_nBaseTexture2Frame;
vars.m_nBumpmap2Var = info.m_nBumpmap2;
vars.m_nBumpmap2Frame = info.m_nBumpFrame2;
vars.m_nBump2Transform = info.m_nBumpTransform2;
vars.m_nAlphaTestReference = info.m_nAlphaTestReference;
vars.m_bSSBump = hasSSBump;
vars.m_nDetailVar = info.m_nDetail;
vars.m_nDetailScale = info.m_nDetailScale;
vars.m_nDetailTextureCombineMode = info.m_nDetailTextureCombineMode;
vars.m_nDetailTextureBlendFactor = info.m_nDetailTextureBlendFactor;
vars.m_nDetailTint = info.m_nDetailTint;
if ( ( info.m_nSeamlessMappingScale != -1 ) )
vars.m_fSeamlessScale = params[info.m_nSeamlessMappingScale]->GetFloatValue();
else
vars.m_fSeamlessScale = 0.0;
pShader->DrawFlashlight_dx90( params, pShaderAPI, pShaderShadow, vars );
return;
}
pContextData->m_bFullyOpaque = bFullyOpaque;
pContextData->m_bFullyOpaqueWithoutAlphaTest = bFullyOpaqueWithoutAlphaTest;
bool bHasOutline = IsBoolSet( info.m_nOutline, params );
pContextData->m_bPixelShaderForceFastPathBecauseOutline = bHasOutline;
bool bHasSoftEdges = IsBoolSet( info.m_nSoftEdges, params );
bool hasEnvmapMask = params[info.m_nEnvmapMask]->IsTexture() && !bHasFoW;
float fDetailBlendFactor = GetFloatParam( info.m_nDetailTextureBlendFactor, params, 1.0 );
if ( pShaderShadow || bNeedRegenStaticCmds )
{
bool hasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool hasDiffuseBumpmap = hasBump && (params[info.m_nNoDiffuseBumpLighting]->GetIntValue() == 0);
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
int envmap_variant; //0 = no envmap, 1 = regular, 2 = darken in shadow mode
if( hasEnvmap )
{
//only enabled darkened cubemap mode when the scale calls for it. And not supported in ps20 when also using a 2nd bumpmap
envmap_variant = ((GetFloatParam( info.m_nEnvMapLightScale, params ) > 0.0f) && (g_pHardwareConfig->SupportsPixelShaders_2_b() || !hasBump2)) ? 2 : 1;
}
else
{
envmap_variant = 0;
}
bool bSeamlessMapping = ( ( info.m_nSeamlessMappingScale != -1 ) &&
( params[info.m_nSeamlessMappingScale]->GetFloatValue() != 0.0 ) );
if ( bNeedRegenStaticCmds )
{
pContextData->m_bNeedsCmdRegen = false;
pContextData->ResetStaticCmds();
CCommandBufferBuilder< CFixedCommandStorageBuffer< 5000 > > staticCmdsBuf;
int nLightingPreviewMode = !bHasFoW ? IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 ) : 0;
if ( ( nLightingPreviewMode == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH ) && IsPC() )
{
staticCmdsBuf.SetVertexShaderNearAndFarZ( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6 ); // Needed for SSAO
}
if( !hasBaseTexture )
{
if( hasEnvmap )
{
// if we only have an envmap (no basetexture), then we want the albedo to be black.
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_BLACK );
}
else
{
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
}
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER1, TEXTURE_LIGHTMAP );
if ( g_pConfig->m_bPaintInGame && !r_twopasspaint.GetBool() )
{
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER9, TEXTURE_PAINT );
}
if ( bSeamlessMapping )
{
staticCmdsBuf.SetVertexShaderConstant4(
VERTEX_SHADER_SHADER_SPECIFIC_CONST_0,
params[info.m_nSeamlessMappingScale]->GetFloatValue(),0,0,0 );
}
staticCmdsBuf.StoreEyePosInPixelShaderConstant( 10 );
staticCmdsBuf.SetPixelShaderFogParams( 11 );
staticCmdsBuf.End();
// now, copy buf
pContextData->m_pStaticCmds = new uint8[staticCmdsBuf.Size()];
memcpy( pContextData->m_pStaticCmds, staticCmdsBuf.Base(), staticCmdsBuf.Size() );
}
if ( pShaderShadow )
{
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if ( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
pShader->SetDefaultBlendingShadowState( nAlphaChannelTextureVar, hasBaseTexture );
unsigned int flags = VERTEX_POSITION;
// base texture
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, !bShaderSrgbRead );
if ( g_pConfig->m_bPaintInGame && !r_twopasspaint.GetBool() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER9, !bShaderSrgbRead );
}
if ( hasLightWarpTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, false );
}
if ( bHasBlendModulateTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, false );
}
if ( hasBaseTexture2 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER7, !bShaderSrgbRead );
}
// if( hasLightmap )
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
}
else
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false );
}
if( hasEnvmap || ( IsX360() && hasFlashlight ) )
{
if( hasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
}
}
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T | VERTEX_NORMAL;
}
#define TCOMBINE_NONE 12 // there is no detail texture
int nDetailBlendMode = TCOMBINE_NONE;
if ( hasDetailTexture )
{
nDetailBlendMode = GetIntParam( info.m_nDetailTextureCombineMode, params );
ITexture *pDetailTexture = params[info.m_nDetail]->GetTextureValue();
if ( pDetailTexture->GetFlags() & TEXTUREFLAGS_SSBUMP )
{
if ( hasBump )
nDetailBlendMode = 10; // ssbump
else
nDetailBlendMode = 11; // ssbump_nobump
}
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true );
bool bSRGBState = ( nDetailBlendMode == 1 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER12, bSRGBState );
}
// Hijack detail blend mode 9 for paint (this blend mode was previously skipped/unused in lightmappedgeneric)
if ( g_pConfig->m_bPaintInGame && !r_twopasspaint.GetBool() )
{
nDetailBlendMode = 9;
}
if( hasBump || hasNormalMapAlphaEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
}
if( hasBump2 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
}
if( hasBumpMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true );
}
if( hasEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
}
if( bHasFoW )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
}
if( bDeferredActive )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER15, true );
}
if( hasFlashlight && IsX360() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER14 );
pShaderShadow->EnableTexture( SHADER_SAMPLER15, true );
}
if( hasVertexColor || hasBaseTexture2 || hasBump2 )
{
flags |= VERTEX_COLOR;
}
// texcoord0 : base texcoord
// texcoord1 : lightmap texcoord
// texcoord2 : lightmap texcoord offset
int numTexCoords;
// if ( pShaderAPI->InEditorMode() )
// if ( pShader->CanUseEditorMaterials() )
// {
// numTexCoords = 1;
// }
// else
{
numTexCoords = 2;
if( hasBump )
{
numTexCoords = 3;
}
}
int nLightingPreviewMode = !bHasFoW ? IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 ) : 0;
pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, 0 );
// Pre-cache pixel shaders
bool hasBaseAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_BASEALPHAENVMAPMASK );
int bumpmap_variant=(hasSSBump) ? 2 : hasBump;
bool bMaskedBlending=( (info.m_nMaskedBlending != -1) &&
(params[info.m_nMaskedBlending]->GetIntValue() != 0) );
if( bDeferredActive )
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_deferred_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( ENVMAP_MASK, hasEnvmapMask );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, params[info.m_nEnvmap]->IsTexture() );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_VERTEX_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR ) );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXALPHATEXBLENDFACTOR, hasBaseTexture2 || hasBump2 );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_VERTEX_SHADER_COMBO( PARALLAX_MAPPING, bParallaxMapping );
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_VERTEX_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_VERTEX_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_VERTEX_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_deferred_vs30 );
DECLARE_STATIC_PIXEL_SHADER( lightmappedgeneric_deferred_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2, hasBaseTexture2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bumpmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP2, hasBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, envmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, hasEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURENOENVMAP, params[info.m_nBaseTextureNoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2NOENVMAP, params[info.m_nBaseTexture2NoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( WARPLIGHTING, hasLightWarpTexture );
SET_STATIC_PIXEL_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKEDBLENDING, bMaskedBlending);
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( OUTLINE, bHasOutline );
SET_STATIC_PIXEL_SHADER_COMBO( SOFTEDGES, bHasSoftEdges );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( PARALLAX_MAPPING, bParallaxMapping );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_PIXEL_SHADER( lightmappedgeneric_deferred_ps30 );
}
else
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( ENVMAP_MASK, hasEnvmapMask );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, params[info.m_nEnvmap]->IsTexture() );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_VERTEX_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR ) );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXALPHATEXBLENDFACTOR, hasBaseTexture2 || hasBump2 );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_VERTEX_SHADER_COMBO( PARALLAX_MAPPING, bParallaxMapping );
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_VERTEX_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_VERTEX_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_VERTEX_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
DECLARE_STATIC_PIXEL_SHADER( lightmappedgeneric_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2, hasBaseTexture2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bumpmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP2, hasBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, envmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, hasEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURENOENVMAP, params[info.m_nBaseTextureNoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2NOENVMAP, params[info.m_nBaseTexture2NoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( WARPLIGHTING, hasLightWarpTexture );
SET_STATIC_PIXEL_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKEDBLENDING, bMaskedBlending);
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( OUTLINE, bHasOutline );
SET_STATIC_PIXEL_SHADER_COMBO( SOFTEDGES, bHasSoftEdges );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( PARALLAX_MAPPING, bParallaxMapping );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode );
SET_STATIC_PIXEL_SHADER( lightmappedgeneric_ps30 );
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for
// underwater stuff and writing depth to dest alpha
// But only do it if we're not using the alpha already for translucency
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
pShaderShadow->EnableSRGBWrite( true );
pShader->DefaultFog();
// NOTE: This isn't optimal. If $color2 is ever changed by a material
// proxy, this code won't get re-run, but too bad. No time to make this work
// Also note that if the lightmap scale factor changes
// all shadow state blocks will be re-run, so that's ok
float flLScale = pShaderShadow->GetLightMapScaleFactor();
pShader->PI_BeginCommandBuffer();
pShader->PI_SetModulationPixelShaderDynamicState( 21 );
// MAINTOL4DMERGEFIXME
// Need to reflect this change which is from this rel changelist since this constant set was moved from the dynamic block to here:
// Change 578692 by Alex@alexv_rel on 2008/06/04 18:07:31
//
// Fix for portalareawindows in ep2 being rendered black. The color variable was being multipurposed for both the vs and ps differently where the ps doesn't care about alpha, but the vs does. Only applying the alpha2 DoD hack to the pixel shader constant where the alpha was never used in the first place and leaving alpha as is for the vs.
// color[3] *= ( IS_PARAM_DEFINED( info.m_nAlpha2 ) && params[ info.m_nAlpha2 ]->GetFloatValue() > 0.0f ) ? params[ info.m_nAlpha2 ]->GetFloatValue() : 1.0f;
// pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 12, color );
pShader->PI_SetModulationPixelShaderDynamicState_LinearScale_ScaleInW( 12, flLScale );
pShader->PI_SetModulationVertexShaderDynamicState_LinearScale( flLScale );
pShader->PI_EndCommandBuffer();
} // end shadow state
} // end shadow || regen display list
if ( pShaderAPI && ( pContextData->m_bMaterialVarsChanged ) )
{
// need to regenerate the semistatic cmds
pContextData->m_SemiStaticCmdsOut.Reset();
pContextData->m_bMaterialVarsChanged = false;
bool bHasBlendMaskTransform= (
(info.m_nBlendMaskTransform != -1) &&
(info.m_nMaskedBlending != -1) &&
(params[info.m_nMaskedBlending]->GetIntValue() ) &&
( ! (params[info.m_nBumpTransform]->MatrixIsIdentity() ) ) );
// If we don't have a texture transform, we don't have
// to set vertex shader constants or run vertex shader instructions
// for the texture transform.
bool bHasTextureTransform =
!( params[info.m_nBaseTextureTransform]->MatrixIsIdentity() &&
params[info.m_nBumpTransform]->MatrixIsIdentity() &&
params[info.m_nBumpTransform2]->MatrixIsIdentity() &&
params[info.m_nEnvmapMaskTransform]->MatrixIsIdentity() );
bHasTextureTransform |= bHasBlendMaskTransform;
pContextData->m_bVertexShaderFastPath = !bHasTextureTransform;
if( params[info.m_nDetail]->IsTexture() )
{
pContextData->m_bVertexShaderFastPath = false;
}
int nTransformToLoad = info.m_nBlendMaskTransform;
if( ( hasBump || hasSSBump ) && hasDetailTexture && !hasSelfIllum && !bHasBlendModulateTexture )
{
nTransformToLoad = info.m_nBumpTransform;
}
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform(
VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, nTransformToLoad );
if ( ! pContextData->m_bVertexShaderFastPath )
{
bool bSeamlessMapping = ( ( info.m_nSeamlessMappingScale != -1 ) &&
( params[info.m_nSeamlessMappingScale]->GetFloatValue() != 0.0 ) );
bool hasEnvmapMask = params[info.m_nEnvmapMask]->IsTexture() && !bHasFoW;
if (!bSeamlessMapping )
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
// If we have a detail texture, then the bump texcoords are the same as the base texcoords.
if( hasBump && !hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
}
if( hasEnvmapMask )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nEnvmapMaskTransform );
}
else if ( hasBump2 )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nBumpTransform2 );
}
}
pContextData->m_SemiStaticCmdsOut.SetEnvMapTintPixelShaderDynamicState( 0, info.m_nEnvmapTint );
if ( hasDetailTexture )
{
float detailTintAndBlend[4] = {1, 1, 1, 1};
if ( info.m_nDetailTint != -1 )
{
params[info.m_nDetailTint]->GetVecValue( detailTintAndBlend, 3 );
}
detailTintAndBlend[3] = fDetailBlendFactor;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 8, detailTintAndBlend );
}
float envmapTintVal[4];
float selfIllumTintVal[4];
params[info.m_nEnvmapTint]->GetVecValue( envmapTintVal, 3 );
params[info.m_nSelfIllumTint]->GetVecValue( selfIllumTintVal, 3 );
float envmapContrast = params[info.m_nEnvmapContrast]->GetFloatValue();
float envmapSaturation = params[info.m_nEnvmapSaturation]->GetFloatValue();
float fresnelReflection = params[info.m_nFresnelReflection]->GetFloatValue();
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
int envmap_variant; //0 = no envmap, 1 = regular, 2 = darken in shadow mode
if( hasEnvmap )
{
//only enabled darkened cubemap mode when the scale calls for it. And not supported in ps20 when also using a 2nd bumpmap
envmap_variant = ((GetFloatParam( info.m_nEnvMapLightScale, params ) > 0.0f) && (g_pHardwareConfig->SupportsPixelShaders_2_b() || !hasBump2)) ? 2 : 1;
}
else
{
envmap_variant = 0;
}
pContextData->m_bPixelShaderFastPath = true;
bool bUsingContrastOrSaturation = hasEnvmap && ( ( (envmapContrast != 0.0f) && (envmapContrast != 1.0f) ) || (envmapSaturation != 1.0f) );
bool bUsingFresnel = hasEnvmap && (fresnelReflection != 1.0f);
bool bUsingSelfIllumTint = IS_FLAG_SET(MATERIAL_VAR_SELFILLUM) && (selfIllumTintVal[0] != 1.0f || selfIllumTintVal[1] != 1.0f || selfIllumTintVal[2] != 1.0f);
if ( bUsingContrastOrSaturation || bUsingFresnel || bUsingSelfIllumTint || !g_pConfig->bShowSpecular )
{
pContextData->m_bPixelShaderFastPath = false;
}
if( !pContextData->m_bPixelShaderFastPath )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstants( 2, 3 );
pContextData->m_SemiStaticCmdsOut.OutputConstantData( params[info.m_nEnvmapContrast]->GetVecValue() );
pContextData->m_SemiStaticCmdsOut.OutputConstantData( params[info.m_nEnvmapSaturation]->GetVecValue() );
float flFresnel = params[info.m_nFresnelReflection]->GetFloatValue();
// [ 0, 0, 1-R(0), R(0) ]
pContextData->m_SemiStaticCmdsOut.OutputConstantData4( 0., 0., 1.0 - flFresnel, flFresnel );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 7, params[info.m_nSelfIllumTint]->GetVecValue() );
}
else
{
if ( bHasOutline )
{
float flOutlineParms[8] = { GetFloatParam( info.m_nOutlineStart0, params ),
GetFloatParam( info.m_nOutlineStart1, params ),
GetFloatParam( info.m_nOutlineEnd0, params ),
GetFloatParam( info.m_nOutlineEnd1, params ),
0,0,0,
GetFloatParam( info.m_nOutlineAlpha, params ) };
if ( info.m_nOutlineColor != -1 )
{
params[info.m_nOutlineColor]->GetVecValue( flOutlineParms + 4, 3 );
}
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 2, flOutlineParms, 2 );
}
if ( bHasSoftEdges )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant4(
4, GetFloatParam( info.m_nEdgeSoftnessStart, params ),
GetFloatParam( info.m_nEdgeSoftnessEnd, params ),
0,0 );
}
}
// parallax and cubemap light scale mapping parms (c20)
if ( bParallaxMapping || (envmap_variant == 2) )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant4( 20, GetFloatParam( info.m_nHeightScale, params), GetFloatParam( info.m_nEnvMapLightScale, params), 0, 0 );
}
// texture binds
if( hasBaseTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
// handle mat_fullbright 2
bool bLightingOnly = mat_fullbright.GetInt() == 2 && !IS_FLAG_SET( MATERIAL_VAR_NO_DEBUG_OVERRIDE );
if( bLightingOnly )
{
// BASE TEXTURE
if( hasSelfIllum )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY_ALPHA_ZERO );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
}
// BASE TEXTURE 2
if( hasBaseTexture2 )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER7, TEXTURE_GREY );
}
// DETAIL TEXTURE
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER12, TEXTURE_GREY );
}
// disable color modulation
float color[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pContextData->m_SemiStaticCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_MODULATION_COLOR, color );
// turn off environment mapping
envmapTintVal[0] = 0.0f;
envmapTintVal[1] = 0.0f;
envmapTintVal[2] = 0.0f;
}
// always set the transform for detail textures since I'm assuming that you'll
// always have a detailscale.
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBaseTextureTransform, info.m_nDetailScale );
}
if( hasBaseTexture2 )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER7, info.m_nBaseTexture2, info.m_nBaseTexture2Frame );
}
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nDetail, info.m_nDetailFrame );
}
if( hasBump || hasNormalMapAlphaEnvmapMask )
{
if( !g_pConfig->m_bFastNoBump )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER4, info.m_nBumpmap, info.m_nBumpFrame );
}
else
{
if( hasSSBump )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER4, TEXTURE_SSBUMP_FLAT );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER4, TEXTURE_NORMALMAP_FLAT );
}
}
}
if( hasBump2 )
{
if( !g_pConfig->m_bFastNoBump )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER5, info.m_nBumpmap2, info.m_nBumpFrame2 );
}
else
{
if( hasSSBump )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALMAP_FLAT );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER5, TEXTURE_SSBUMP_FLAT );
}
}
}
if( hasBumpMask )
{
if( !g_pConfig->m_bFastNoBump )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER8, info.m_nBumpMask, -1 );
}
else
{
// this doesn't make sense
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER8, TEXTURE_NORMALMAP_FLAT );
}
}
if( hasEnvmapMask )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER5, info.m_nEnvmapMask, info.m_nEnvmapMaskFrame );
}
if ( hasLightWarpTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER6, info.m_nLightWarpTexture, -1 );
}
if ( bHasBlendModulateTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER3, info.m_nBlendModulateTexture, -1 );
}
if ( hasFlashlight && IsX360() )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderFlashlightState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6 );
CBCmdSetPixelShaderFlashlightState_t state;
state.m_LightSampler = SHADER_SAMPLER13;
state.m_DepthSampler = SHADER_SAMPLER14;
state.m_ShadowNoiseSampler = SHADER_SAMPLER15;
state.m_nColorConstant = 28;
state.m_nAttenConstant = 13;
state.m_nOriginConstant = 14;
state.m_nDepthTweakConstant = 19;
state.m_nScreenScaleConstant = 31;
state.m_nWorldToTextureConstant = -1;
state.m_bFlashlightNoLambert = false;
state.m_bSinglePassFlashlight = bSinglePassFlashlight;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderFlashlightState( state );
}
pContextData->m_SemiStaticCmdsOut.End();
}
}
DYNAMIC_STATE
{
CCommandBufferBuilder< CFixedCommandStorageBuffer< 1000 > > DynamicCmdsOut;
DynamicCmdsOut.Call( pContextData->m_pStaticCmds );
DynamicCmdsOut.Call( pContextData->m_SemiStaticCmdsOut.Base() );
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
if( hasEnvmap )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER2, info.m_nEnvmap, info.m_nEnvmapFrame );
}
bool bVertexShaderFastPath = pContextData->m_bVertexShaderFastPath;
int nFixedLightingMode = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_ENABLE_FIXED_LIGHTING );
if( nFixedLightingMode != ENABLE_FIXED_LIGHTING_NONE )
{
if ( pContextData->m_bPixelShaderForceFastPathBecauseOutline )
{
nFixedLightingMode = ENABLE_FIXED_LIGHTING_NONE;
}
else
{
bVertexShaderFastPath = false;
}
}
bool bWorldNormal = ( nFixedLightingMode == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH );
if ( bWorldNormal && IsPC() )
{
float vEyeDir[4];
pShaderAPI->GetWorldSpaceCameraDirection( vEyeDir );
float flFarZ = pShaderAPI->GetFarZ();
vEyeDir[0] /= flFarZ; // Divide by farZ for SSAO algorithm
vEyeDir[1] /= flFarZ;
vEyeDir[2] /= flFarZ;
DynamicCmdsOut.SetVertexShaderConstant4( 12, vEyeDir[0], vEyeDir[1], vEyeDir[2], 1.0f );
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
if( bDeferredActive )
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_deferred_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( FASTPATH, bVertexShaderFastPath );
SET_DYNAMIC_VERTEX_SHADER_CMD( DynamicCmdsOut, lightmappedgeneric_deferred_vs30 );
}
else
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( FASTPATH, bVertexShaderFastPath );
SET_DYNAMIC_VERTEX_SHADER_CMD( DynamicCmdsOut, lightmappedgeneric_vs30 );
}
bool bPixelShaderFastPath = pContextData->m_bPixelShaderFastPath;
if ( nFixedLightingMode != ENABLE_FIXED_LIGHTING_NONE )
{
bPixelShaderFastPath = false;
}
bool bWriteDepthToAlpha;
bool bWriteWaterFogToAlpha;
if( pContextData->m_bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
else
{
//can't write a special value to dest alpha if we're actually using as-intended alpha
bWriteDepthToAlpha = false;
bWriteWaterFogToAlpha = false;
}
if( bHasFoW )
{
if( ( info.m_nFoW != -1 ) && ( params[ info.m_nFoW ]->IsTexture() != 0 ) )
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER13, info.m_nFoW, -1 );
else
DynamicCmdsOut.BindStandardTexture( SHADER_SAMPLER13, TEXTURE_WHITE );
float vFoWSize[ 4 ];
Vector vMins = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MINS );
Vector vMaxs = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MAXS );
vFoWSize[ 0 ] = vMins.x;
vFoWSize[ 1 ] = vMins.y;
vFoWSize[ 2 ] = vMaxs.x - vMins.x;
vFoWSize[ 3 ] = vMaxs.y - vMins.y;
DynamicCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_12, vFoWSize );
}
if( bDeferredActive )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER14, GetDeferredExt()->GetTexture_LightAccum(), 0 );
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER15, GetDeferredExt()->GetTexture_LightAccum2(), 0 );
//DynamicCmdsOut.BindStandardTexture( SHADER_SAMPLER14, TEXTURE_WHITE );
int x, y, w, t;
pShaderAPI->GetCurrentViewport( x, y, w, t );
float fl1[4] = { 1.0f / w, 1.0f / t, 0, 0 };
DynamicCmdsOut.SetPixelShaderConstant( PSREG_UBERLIGHT_SMOOTH_EDGE_0, fl1 );
}
bool bFlashlightShadows = false;
bool bUberlight = false;
if( hasFlashlight && IsX360() )
{
pShaderAPI->GetFlashlightShaderInfo( &bFlashlightShadows, &bUberlight );
}
else
{
// only do ambient light when not using flashlight
static ConVarRef mat_ambient_light_r_forced( "mat_ambient_light_r_forced" );
static ConVarRef mat_ambient_light_g_forced( "mat_ambient_light_g_forced" );
static ConVarRef mat_ambient_light_b_forced( "mat_ambient_light_b_forced" );
float vAmbientColor[4] = { mat_ambient_light_r_forced.GetFloat() != -1.0f ? mat_ambient_light_r_forced.GetFloat() : mat_ambient_light_r.GetFloat(),
mat_ambient_light_g_forced.GetFloat() != -1.0f ? mat_ambient_light_g_forced.GetFloat() : mat_ambient_light_g.GetFloat(),
mat_ambient_light_b_forced.GetFloat() != -1.0f ? mat_ambient_light_b_forced.GetFloat() : mat_ambient_light_b.GetFloat(),
0.0f };
if ( mat_fullbright.GetInt() == 1 )
{
vAmbientColor[0] = vAmbientColor[1] = vAmbientColor[2] = 0.0f;
}
DynamicCmdsOut.SetPixelShaderConstant( 31, vAmbientColor, 1 );
}
float envmapContrast = params[info.m_nEnvmapContrast]->GetFloatValue();
if( bDeferredActive )
{
DECLARE_DYNAMIC_PIXEL_SHADER( lightmappedgeneric_deferred_ps30);
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATH, bPixelShaderFastPath || pContextData->m_bPixelShaderForceFastPathBecauseOutline );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATHENVMAPCONTRAST, bPixelShaderFastPath && envmapContrast == 1.0f );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, /*bFlashlightShadows*/ 0 );
SET_DYNAMIC_PIXEL_SHADER_CMD( DynamicCmdsOut, lightmappedgeneric_deferred_ps30 );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( lightmappedgeneric_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATH, bPixelShaderFastPath || pContextData->m_bPixelShaderForceFastPathBecauseOutline );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATHENVMAPCONTRAST, bPixelShaderFastPath && envmapContrast == 1.0f );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER_CMD( DynamicCmdsOut, lightmappedgeneric_ps30 );
}
DynamicCmdsOut.End();
pShaderAPI->ExecuteCommandBuffer( DynamicCmdsOut.Base() );
}
pShader->Draw();
if( !bDeferredActive && IsPC() && (IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0) && pContextData->m_bFullyOpaqueWithoutAlphaTest )
{
//Alpha testing makes it so we can't write to dest alpha
//Writing to depth makes it so later polygons can't write to dest alpha either
//This leads to situations with garbage in dest alpha.
//Fix it now by converting depth to dest alpha for any pixels that just wrote.
pShader->DrawEqualDepthToDestAlpha();
}
}
void DrawPassLightPassVolum( const lightPassParms &info, CBaseVSShader *pShader, IMaterialVar **params,
IShaderShadow* pShaderShadow, IShaderDynamicAPI* pShaderAPI,
VertexCompressionType_t vertexCompression )
{
const bool bWorldProjection = PARM_SET( info.iWorldProjection );
const int iLightType = PARM_INT( info.iLightTypeVar );
const bool bPoint = iLightType == DEFLIGHTTYPE_POINT;
SHADOW_STATE
{
pShaderShadow->SetDefaultState();
pShaderShadow->EnableDepthTest( false );
pShaderShadow->EnableDepthWrites( false );
pShaderShadow->EnableAlphaWrites( false );
pShaderShadow->EnableCulling( true );
pShader->EnableAlphaBlending( SHADER_BLEND_ONE, SHADER_BLEND_ONE );
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
for ( int i = 0; i < FREE_LIGHT_SAMPLERS; i++ )
{
pShaderShadow->EnableTexture( (Sampler_t)( FIRST_LIGHT_SAMPLER + i ), true );
}
pShaderShadow->VertexShaderVertexFormat( VERTEX_POSITION, 1, NULL, 0 );
DECLARE_STATIC_VERTEX_SHADER( defconstruct_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( USEWORLDTRANSFORM, bWorldProjection ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( SENDWORLDPOS, bWorldProjection ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( defconstruct_vs30 );
switch ( iLightType )
{
case DEFLIGHTTYPE_POINT:
{
DECLARE_STATIC_PIXEL_SHADER( volumpass_point_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( USEWORLDTRANSFORM, bWorldProjection ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( volumpass_point_ps30 );
}
break;
case DEFLIGHTTYPE_SPOT:
{
DECLARE_STATIC_PIXEL_SHADER( volumpass_spot_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( USEWORLDTRANSFORM, bWorldProjection ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( volumpass_spot_ps30 );
}
break;
}
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
CDeferredExtension *pExt = GetDeferredExt();
const volumeData_t &vData = GetDeferredExt()->GetVolumeData();
Assert( pExt->GetActiveLightData() != NULL );
Assert( pExt->GetActiveLights_NumRows() != NULL );
const int iNumShadowedCookied = vData.bHasCookie ? 1:0;
const int iNumShadowed = vData.bHasCookie ? 0:1;
Assert( (iNumShadowedCookied + iNumShadowed) == 1 );
Assert( iNumShadowedCookied <= pExt->GetNumActiveLights_ShadowedCookied() );
Assert( iNumShadowed <= pExt->GetNumActiveLights_Shadowed() );
DECLARE_DYNAMIC_VERTEX_SHADER( defconstruct_vs30 );
SET_DYNAMIC_VERTEX_SHADER( defconstruct_vs30 );
switch ( iLightType )
{
case DEFLIGHTTYPE_POINT:
{
DECLARE_DYNAMIC_PIXEL_SHADER( volumpass_point_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_SHADOWED_COOKIE, iNumShadowedCookied );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_SHADOWED, iNumShadowed );
SET_DYNAMIC_PIXEL_SHADER( volumpass_point_ps30 );
}
break;
case DEFLIGHTTYPE_SPOT:
{
DECLARE_DYNAMIC_PIXEL_SHADER( volumpass_spot_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_SHADOWED_COOKIE, iNumShadowedCookied );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_SHADOWED, iNumShadowed );
SET_DYNAMIC_PIXEL_SHADER( volumpass_spot_ps30 );
}
break;
}
pShader->BindTexture( SHADER_SAMPLER0, GetDeferredExt()->GetTexture_VolumePrePass() );
pShader->BindTexture( SHADER_SAMPLER1, GetDeferredExt()->GetTexture_Depth() );
int iSampler = 0;
int iShadow = vData.iSamplerOffset;
int iCookie = vData.iSamplerOffset;
for ( ; iSampler < (iNumShadowedCookied*2);)
{
ITexture *pDepth = bPoint ? GetDeferredExt()->GetTexture_ShadowDepth_DP(iShadow) :
GetDeferredExt()->GetTexture_ShadowDepth_Proj(iShadow);
pShader->BindTexture( (Sampler_t)( FIRST_LIGHT_SAMPLER + iSampler ), pDepth );
pShader->BindTexture( (Sampler_t)( FIRST_LIGHT_SAMPLER + iSampler + 1 ), GetDeferredExt()->GetTexture_Cookie(iCookie) );
iSampler += 2;
iShadow++;
iCookie++;
}
for ( ; iSampler < (iNumShadowedCookied*2+iNumShadowed); )
{
ITexture *pDepth = bPoint ? GetDeferredExt()->GetTexture_ShadowDepth_DP(iShadow) :
GetDeferredExt()->GetTexture_ShadowDepth_Proj(iShadow);
pShader->BindTexture( (Sampler_t)( FIRST_LIGHT_SAMPLER + iSampler ), pDepth );
iSampler++;
iShadow++;
}
const int frustumReg = bWorldProjection ? 3 : VERTEX_SHADER_SHADER_SPECIFIC_CONST_0;
CommitBaseDeferredConstants_Frustum( pShaderAPI, frustumReg, !bWorldProjection );
CommitBaseDeferredConstants_Origin( pShaderAPI, 0 );
pShaderAPI->SetPixelShaderConstant( FIRST_SHARED_LIGHTDATA_CONSTANT,
pExt->GetActiveLightData() + vData.iDataOffset,
vData.iNumRows );
if ( bWorldProjection )
{
CommitHalfScreenTexel( pShaderAPI, 6 );
}
}
pShader->Draw();
}
//-----------------------------------------------------------------------------
// Draws the shader
//-----------------------------------------------------------------------------
void DrawVertexLitGeneric_DX9( CBaseVSShader *pShader, IMaterialVar** params,
IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow, bool bVertexLitGeneric, VertexLitGeneric_DX9_Vars_t &info )
{
Assert( info.m_nPhong >= 0 );
if( params[info.m_nPhong]->GetIntValue() )
{
DrawSkin_DX9( pShader, params, pShaderAPI, pShaderShadow, true, info );
return;
}
bool hasBaseTexture = params[info.m_nBaseTexture]->IsTexture();
bool hasBump = (info.m_nBumpmap != -1) && params[info.m_nBumpmap]->IsTexture();
bool hasDetailTexture = !hasBump && params[info.m_nDetail]->IsTexture();
bool hasDiffuseLighting = bVertexLitGeneric;
bool hasBaseAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_BASEALPHAENVMAPMASK );
bool hasNormalMapAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
bool hasVertexColor = bVertexLitGeneric ? false : IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool hasVertexAlpha = bVertexLitGeneric ? false : IS_FLAG_SET( MATERIAL_VAR_VERTEXALPHA );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
bool hasSelfIllumInEnvMapMask =
( info.m_nSelfIllumEnvMapMask_Alpha != -1 ) &&
( params[info.m_nSelfIllumEnvMapMask_Alpha]->GetFloatValue() != 0.0 ) ;
bool bAmbientOnly = (info.m_nAmbientOnly != -1) && (params[info.m_nAmbientOnly]->GetIntValue() == 1);
BlendType_t blendType;
if ( params[info.m_nBaseTexture]->IsTexture() )
{
blendType = pShader->EvaluateBlendRequirements( info.m_nBaseTexture, true );
}
else
{
blendType = pShader->EvaluateBlendRequirements( info.m_nEnvmapMask, false );
}
if( pShader->IsSnapshotting() )
{
// look at color and alphamod stuff.
// Unlit generic never uses the flashlight
bool hasFlashlight = hasDiffuseLighting && CShader_IsFlag2Set( params, MATERIAL_VAR2_USE_FLASHLIGHT );
bool hasEnvmap = !hasFlashlight && params[info.m_nEnvmap]->IsTexture();
bool hasEnvmapMask = (hasSelfIllumInEnvMapMask || !hasFlashlight) &&
params[info.m_nEnvmapMask]->IsTexture();
bool bHasNormal = bVertexLitGeneric || hasEnvmap;
bool hasSelfIllum = !hasFlashlight && IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
if( hasFlashlight ) hasEnvmapMask = false;
bool bHalfLambert = IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT );
// Alpha test: FIXME: shouldn't this be handled in CBaseVSShader::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
if( hasFlashlight )
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetAdditiveBlendingShadowState( info.m_nBaseTexture, true );
}
else
{
pShader->SetAdditiveBlendingShadowState( info.m_nEnvmapMask, false );
}
if( bIsAlphaTested )
{
// disable alpha test and use the zfunc zequals since alpha isn't guaranteed to
// be the same on both the regular pass and the flashlight pass.
pShaderShadow->EnableAlphaTest( false );
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
}
pShaderShadow->EnableBlending( true );
pShaderShadow->EnableDepthWrites( false );
}
else
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetDefaultBlendingShadowState( info.m_nBaseTexture, true );
}
else
{
pShader->SetDefaultBlendingShadowState( info.m_nEnvmapMask, false );
}
}
unsigned int flags = VERTEX_POSITION;
if( bHasNormal )
{
flags |= VERTEX_NORMAL;
}
int userDataSize = 0;
if( hasBaseTexture )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE0, true );
pShaderShadow->EnableSRGBRead( SHADER_TEXTURE_STAGE0, true );
}
if( hasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE1, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_TEXTURE_STAGE1, true );
}
}
if( hasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE7, true );
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE4, true );
userDataSize = 4; // tangent S
}
if( hasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE2, true );
}
if( hasBump )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE3, true );
userDataSize = 4; // tangent S
// Normalizing cube map
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE5, true );
}
if( hasEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_TEXTURE_STAGE4, true );
}
if( hasVertexColor || hasVertexAlpha )
{
flags |= VERTEX_COLOR;
}
pShaderShadow->EnableSRGBWrite( true );
// texcoord0 : base texcoord
const int numTexCoords = 1;
int numBoneWeights = 0;
if( IS_FLAG_SET( MATERIAL_VAR_MODEL ) )
{
numBoneWeights = 3;
flags |= VERTEX_BONE_INDEX;
}
pShaderShadow->VertexShaderVertexFormat(
flags, numTexCoords, NULL, numBoneWeights, userDataSize );
if ( hasBump )
{
DECLARE_STATIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_bump_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_bump_vs20 );
DECLARE_STATIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_bump_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, hasBaseTexture );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSELIGHTING, hasDiffuseLighting );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( HALFLAMBERT, bHalfLambert);
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_bump_ps20 );
}
else
{
DECLARE_STATIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, hasVertexColor || hasVertexAlpha );
SET_STATIC_VERTEX_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, bHalfLambert );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_vs20 );
DECLARE_STATIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM_ENVMAPMASK_ALPHA,
( hasSelfIllumInEnvMapMask && ( hasEnvmapMask ) ) );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE, hasBaseTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSELIGHTING, hasDiffuseLighting );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, hasEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXALPHA, hasVertexAlpha );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_ps20 );
}
if( hasFlashlight )
{
pShader->FogToBlack();
}
else
{
pShader->DefaultFog();
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for
// underwater stuff
if( blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested )
{
pShaderShadow->EnableAlphaWrites( true );
}
}
else
{
bool hasFlashlight = hasDiffuseLighting && pShaderAPI->InFlashlightMode();
bool hasEnvmap = !hasFlashlight && params[info.m_nEnvmap]->IsTexture();
bool hasEnvmapMask = !hasFlashlight && params[info.m_nEnvmapMask]->IsTexture();
if( hasBaseTexture )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
if( hasEnvmap )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE1, info.m_nEnvmap, info.m_nEnvmapFrame );
}
if( hasDetailTexture )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE2, info.m_nDetail, info.m_nDetailFrame );
}
if( !g_pConfig->m_bFastNoBump )
{
if( hasBump )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE3, info.m_nBumpmap, info.m_nBumpFrame );
}
}
else
{
if( hasBump )
{
pShaderAPI->BindFlatNormalMap( SHADER_TEXTURE_STAGE3 );
}
}
if( hasEnvmapMask )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE4, info.m_nEnvmapMask, info.m_nEnvmapMaskFrame );
}
bool bHasFlashlightDepth = false;
if( hasFlashlight )
{
Assert( info.m_nFlashlightTexture >= 0 && info.m_nFlashlightTextureFrame >= 0 );
pShader->BindTexture( SHADER_TEXTURE_STAGE7, info.m_nFlashlightTexture, info.m_nFlashlightTextureFrame );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
SetFlashLightColorFromState( state, pShaderAPI );
if( pFlashlightDepthTexture )
{
pShader->BindTexture( SHADER_TEXTURE_STAGE4, pFlashlightDepthTexture, 0 );
bHasFlashlightDepth = true;
}
}
int lightCombo = 0;
if( bVertexLitGeneric && !hasFlashlight )
{
lightCombo = pShaderAPI->GetCurrentLightCombo();
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int fogIndex = ( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z ) ? 1 : 0;
int numBones = pShaderAPI->GetCurrentNumBones();
if ( hasBump )
{
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_bump_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( LIGHT_COMBO, lightCombo );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_BONES, numBones );
SET_DYNAMIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_bump_vs20 );
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_bump_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( LIGHT_COMBO, lightCombo );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z &&
blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FOGTYPE, pShaderAPI->GetSceneFogMode() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTH, bHasFlashlightDepth );
SET_DYNAMIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_bump_ps20 );
}
else
{
if ( bAmbientOnly ) // Override selected light combo to be ambient only
lightCombo = 2;
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( LIGHT_COMBO, lightCombo );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_BONES, numBones );
SET_DYNAMIC_VERTEX_SHADER_COMBO(
LIGHTING_PREVIEW, hasDiffuseLighting && pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING)!=0);
SET_DYNAMIC_VERTEX_SHADER( sdk_vertexlit_and_unlit_generic_vs20 );
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z &&
blendType != BT_BLENDADD && blendType != BT_BLEND && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FOGTYPE, pShaderAPI->GetSceneFogMode() );
SET_DYNAMIC_PIXEL_SHADER_COMBO(
LIGHTING_PREVIEW, hasDiffuseLighting && pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING));
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTH, bHasFlashlightDepth );
SET_DYNAMIC_PIXEL_SHADER( sdk_vertexlit_and_unlit_generic_ps20 );
}
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
if( hasDetailTexture )
{
pShader->SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBaseTextureTransform, info.m_nDetailScale );
Assert( !hasBump );
}
if( hasBump )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
Assert( !hasDetailTexture );
}
if( hasEnvmapMask )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nEnvmapMaskTransform );
}
if( hasEnvmap )
{
pShader->SetEnvMapTintPixelShaderDynamicState( 0, info.m_nEnvmapTint, -1, true );
}
if( ( info.m_nHDRColorScale != -1 ) && pShader->IsHDREnabled() )
{
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace_LinearScale( 1, params[info.m_nHDRColorScale]->GetFloatValue() );
}
else
{
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
}
pShader->SetPixelShaderConstant( 2, info.m_nEnvmapContrast );
pShader->SetPixelShaderConstant( 3, info.m_nEnvmapSaturation );
pShader->SetPixelShaderConstant( 4, info.m_nSelfIllumTint );
pShader->SetAmbientCubeDynamicStateVertexShader();
if( hasBump )
{
pShaderAPI->BindSignedNormalizationCubeMap( SHADER_TEXTURE_STAGE5 );
pShaderAPI->SetPixelShaderStateAmbientLightCube( 5 );
pShaderAPI->CommitPixelShaderLighting( 13 );
}
if( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z )
{
pShader->SetWaterFogColorPixelShaderConstantLinear( 19 );
}
float eyePos[4];
pShaderAPI->GetWorldSpaceCameraPosition( eyePos );
pShaderAPI->SetPixelShaderConstant( 20, eyePos, 1 );
pShaderAPI->SetPixelShaderFogParams( 21 );
// flashlightfixme: put this in common code.
if( hasFlashlight )
{
VMatrix worldToTexture;
const FlashlightState_t &flashlightState = pShaderAPI->GetFlashlightState( worldToTexture );
// Set the flashlight attenuation factors
float atten[4];
atten[0] = flashlightState.m_fConstantAtten;
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( 22, atten, 1 );
// Set the flashlight origin
float pos[4];
pos[0] = flashlightState.m_vecLightOrigin[0];
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pos[3] = 1.0f;
pShaderAPI->SetPixelShaderConstant( 23, pos, 1 );
pShaderAPI->SetPixelShaderConstant( 24, worldToTexture.Base(), 4 );
}
}
}
void DrawAftershock( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, AftershockVars_t &info, VertexCompressionType_t vertexCompression )
{
bool bBumpMapping = ( info.m_nBumpmap == -1 ) || !params[info.m_nBumpmap]->IsTexture() ? 0 : 1;
SHADOW_STATE
{
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
// Vertex Shader
DECLARE_STATIC_VERTEX_SHADER( aftershock_vs20 );
SET_STATIC_VERTEX_SHADER( aftershock_vs20 );
// Pixel Shader
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( aftershock_ps20b );
SET_STATIC_PIXEL_SHADER( aftershock_ps20b );
}
/*else
{
DECLARE_STATIC_PIXEL_SHADER( aftershock_ps20 );
SET_STATIC_PIXEL_SHADER( aftershock_ps20 );
}*/
// Textures
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Refraction texture
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Bump
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false ); // Not sRGB
pShaderShadow->EnableSRGBWrite( true );
// Blending
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaWrites( false );
// !!! We need to turn this back on because EnableAlphaBlending() above disables it!
//pShaderShadow->EnableDepthWrites( true );
}
DYNAMIC_STATE
{
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( aftershock_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( aftershock_vs20 );
// Set Vertex Shader Constants
if ( info.m_nBumpTransform != -1 )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, info.m_nBumpTransform );
}
// Time % 1000
float vPackedVsConst1[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
float flTime = IS_PARAM_DEFINED( info.m_nTime ) && params[info.m_nTime]->GetFloatValue() > 0.0f ? params[info.m_nTime]->GetFloatValue() : pShaderAPI->CurrentTime();
vPackedVsConst1[0] = flTime;
vPackedVsConst1[0] -= (float)( (int)( vPackedVsConst1[0] / 1000.0f ) ) * 1000.0f;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, vPackedVsConst1, 1 );
DECLARE_DYNAMIC_PIXEL_SHADER( aftershock_ps20b );
SET_DYNAMIC_PIXEL_SHADER( aftershock_ps20b );
// Bind textures
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 ); // Refraction Map
if ( bBumpMapping )
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nBumpmap, info.m_nBumpFrame );
}
// Set Pixel Shader Constants
float vEyePos[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos );
pShaderAPI->SetPixelShaderConstant( 5, vEyePos, 1 );
float vPackedConst1[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPackedConst1[0] = IS_PARAM_DEFINED( info.m_nBlurAmount ) ? params[info.m_nBlurAmount]->GetFloatValue() : kDefaultBlurAmount;
vPackedConst1[1] = IS_PARAM_DEFINED( info.m_nRefractAmount ) ? params[info.m_nRefractAmount]->GetFloatValue() : kDefaultRefractAmount;
vPackedConst1[3] = vPackedVsConst1[0]; // Time
pShaderAPI->SetPixelShaderConstant( 6, vPackedConst1, 1 );
// Refract color tint
pShaderAPI->SetPixelShaderConstant( 7, IS_PARAM_DEFINED( info.m_nColorTint ) ? params[info.m_nColorTint]->GetVecValue() : kDefaultColorTint, 1 );
// Silhouette values
float vPackedConst8[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPackedConst8[0] = IS_PARAM_DEFINED( info.m_nSilhouetteColor ) ? params[info.m_nSilhouetteColor]->GetVecValue()[0] : kDefaultSilhouetteColor[0];
vPackedConst8[1] = IS_PARAM_DEFINED( info.m_nSilhouetteColor ) ? params[info.m_nSilhouetteColor]->GetVecValue()[1] : kDefaultSilhouetteColor[1];
vPackedConst8[2] = IS_PARAM_DEFINED( info.m_nSilhouetteColor ) ? params[info.m_nSilhouetteColor]->GetVecValue()[2] : kDefaultSilhouetteColor[2];
vPackedConst8[3] = IS_PARAM_DEFINED( info.m_nSilhouetteThickness ) ? params[info.m_nSilhouetteThickness]->GetFloatValue() : kDefaultSilhouetteThickness;
pShaderAPI->SetPixelShaderConstant( 8, vPackedConst8, 1 );
// Ground min/max
float vPackedConst9[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPackedConst9[0] = IS_PARAM_DEFINED( info.m_nGroundMin ) ? params[info.m_nGroundMin]->GetFloatValue() : kDefaultGroundMin;
vPackedConst9[1] = IS_PARAM_DEFINED( info.m_nGroundMax ) ? params[info.m_nGroundMax]->GetFloatValue() : kDefaultGroundMax;
pShaderAPI->SetPixelShaderConstant( 9, vPackedConst9, 1 );
// Set c0 and c1 to contain first two rows of ViewProj matrix
VMatrix mView, mProj;
pShaderAPI->GetMatrix( MATERIAL_VIEW, mView.m[0] );
pShaderAPI->GetMatrix( MATERIAL_PROJECTION, mProj.m[0] );
VMatrix mViewProj = mView * mProj;
mViewProj = mViewProj.Transpose3x3();
pShaderAPI->SetPixelShaderConstant( 0, mViewProj.m[0], 2 );
}
pShader->Draw();
}
void DrawPassComposite( const defParms_composite &info, CBaseVSShader *pShader, IMaterialVar **params,
IShaderShadow* pShaderShadow, IShaderDynamicAPI* pShaderAPI,
VertexCompressionType_t vertexCompression, CDeferredPerMaterialContextData *pDeferredContext )
{
const bool bModel = info.bModel;
const bool bIsDecal = IS_FLAG_SET( MATERIAL_VAR_DECAL );
const bool bFastVTex = g_pHardwareConfig->HasFastVertexTextures();
const bool bAlbedo = PARM_TEX( info.iAlbedo );
const bool bAlbedo2 = !bModel && bAlbedo && PARM_TEX( info.iAlbedo2 );
const bool bAlbedo3 = !bModel && bAlbedo && PARM_TEX( info.iAlbedo3 );
const bool bAlbedo4 = !bModel && bAlbedo && PARM_TEX( info.iAlbedo4 );
const bool bAlphatest = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) && bAlbedo;
const bool bTranslucent = IS_FLAG_SET( MATERIAL_VAR_TRANSLUCENT ) && bAlbedo && !bAlphatest;
const bool bNoCull = IS_FLAG_SET( MATERIAL_VAR_NOCULL );
const bool bUseSRGB = DEFCFG_USE_SRGB_CONVERSION != 0;
const bool bPhongFresnel = PARM_SET( info.iPhongFresnel );
const bool bEnvmap = PARM_TEX( info.iEnvmap );
const bool bEnvmapMask = bEnvmap && PARM_TEX( info.iEnvmapMask );
const bool bEnvmapMask2 = bEnvmapMask && PARM_TEX( info.iEnvmapMask2 );
const bool bEnvmapFresnel = bEnvmap && PARM_SET( info.iEnvmapFresnel );
const bool bRimLight = PARM_SET( info.iRimlightEnable );
const bool bRimLightModLight = bRimLight && PARM_SET( info.iRimlightModLight );
const bool bBlendmodulate = bAlbedo2 && PARM_TEX( info.iBlendmodulate );
const bool bBlendmodulate2 = bBlendmodulate && PARM_TEX( info.iBlendmodulate2 );
const bool bBlendmodulate3 = bBlendmodulate && PARM_TEX( info.iBlendmodulate3 );
const bool bSelfIllum = !bAlbedo2 && IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
const bool bSelfIllumMaskInEnvmapMask = bSelfIllum && bEnvmapMask && PARM_SET( info.iSelfIllumMaskInEnvmapAlpha );
const bool bSelfIllumMask = bSelfIllum && !bSelfIllumMaskInEnvmapMask && !bEnvmapMask && PARM_TEX( info.iSelfIllumMask );
const bool bMultiBlend = PARM_SET( info.iMultiblend )
&& bAlbedo && bAlbedo2 && bAlbedo3 && !bEnvmapMask && !bSelfIllumMask;
const bool bNeedsFresnel = bPhongFresnel || bEnvmapFresnel;
const bool bGBufferNormal = bEnvmap || bRimLight || bNeedsFresnel;
const bool bWorldEyeVec = bGBufferNormal;
AssertMsgOnce( !(bTranslucent || bAlphatest) || !bAlbedo2,
"blended albedo not supported by gbuffer pass!" );
AssertMsgOnce( IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK ) == false,
"Normal map sampling should stay out of composition pass." );
AssertMsgOnce( !PARM_TEX( info.iSelfIllumMask ) || !bEnvmapMask,
"Can't use separate selfillum mask with envmap mask - use SELFILLUM_ENVMAPMASK_ALPHA instead." );
AssertMsgOnce( PARM_SET( info.iMultiblend ) == bMultiBlend,
"Multiblend forced off due to invalid usage! May cause vertexformat mis-matches between passes." );
SHADOW_STATE
{
pShaderShadow->SetDefaultState();
pShaderShadow->EnableSRGBWrite( bUseSRGB );
if ( bNoCull )
{
pShaderShadow->EnableCulling( false );
}
int iVFmtFlags = VERTEX_POSITION;
int iUserDataSize = 0;
int *pTexCoordDim;
int iTexCoordNum;
GetTexcoordSettings( ( bModel && bIsDecal && bFastVTex ), bMultiBlend,
iTexCoordNum, &pTexCoordDim );
if ( bModel )
{
iVFmtFlags |= VERTEX_NORMAL;
iVFmtFlags |= VERTEX_FORMAT_COMPRESSED;
}
else
{
if ( bAlbedo2 )
iVFmtFlags |= VERTEX_COLOR;
}
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, bUseSRGB );
if ( bGBufferNormal )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false );
}
if ( bTranslucent )
{
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
}
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, false );
if ( bEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, true );
if ( bEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
if ( bAlbedo2 )
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
}
}
else if ( bSelfIllumMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
}
if ( bAlbedo2 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, bUseSRGB );
if ( bBlendmodulate )
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
}
if ( bMultiBlend )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER7, bUseSRGB );
if ( bAlbedo4 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, bUseSRGB );
}
if ( bBlendmodulate )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true );
}
}
pShaderShadow->EnableAlphaWrites( false );
pShaderShadow->EnableDepthWrites( !bTranslucent );
pShader->DefaultFog();
pShaderShadow->VertexShaderVertexFormat( iVFmtFlags, iTexCoordNum, pTexCoordDim, iUserDataSize );
DECLARE_STATIC_VERTEX_SHADER( composite_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bModel );
SET_STATIC_VERTEX_SHADER_COMBO( MORPHING_VTEX, bModel && bFastVTex );
SET_STATIC_VERTEX_SHADER_COMBO( DECAL, bModel && bIsDecal );
SET_STATIC_VERTEX_SHADER_COMBO( EYEVEC, bWorldEyeVec );
SET_STATIC_VERTEX_SHADER_COMBO( BASETEXTURE2, bAlbedo2 && !bMultiBlend );
SET_STATIC_VERTEX_SHADER_COMBO( BLENDMODULATE, bBlendmodulate );
SET_STATIC_VERTEX_SHADER_COMBO( MULTIBLEND, bMultiBlend );
SET_STATIC_VERTEX_SHADER( composite_vs30 );
DECLARE_STATIC_PIXEL_SHADER( composite_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( ALPHATEST, bAlphatest );
SET_STATIC_PIXEL_SHADER_COMBO( TRANSLUCENT, bTranslucent );
SET_STATIC_PIXEL_SHADER_COMBO( READNORMAL, bGBufferNormal );
SET_STATIC_PIXEL_SHADER_COMBO( NOCULL, bNoCull );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAP, bEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, bEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPFRESNEL, bEnvmapFresnel );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGFRESNEL, bPhongFresnel );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHT, bRimLight );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHTMODULATELIGHT, bRimLightModLight );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2, bAlbedo2 && !bMultiBlend );
SET_STATIC_PIXEL_SHADER_COMBO( BLENDMODULATE, bBlendmodulate );
SET_STATIC_PIXEL_SHADER_COMBO( MULTIBLEND, bMultiBlend );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, bSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM_MASK, bSelfIllumMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM_ENVMAP_ALPHA, bSelfIllumMaskInEnvmapMask );
SET_STATIC_PIXEL_SHADER( composite_ps30 );
}
DYNAMIC_STATE
{
Assert( pDeferredContext != NULL );
if ( pDeferredContext->m_bMaterialVarsChanged || !pDeferredContext->HasCommands( CDeferredPerMaterialContextData::DEFSTAGE_COMPOSITE )
|| building_cubemaps.GetBool() )
{
tmpBuf.Reset();
if ( bAlphatest )
{
PARM_VALIDATE( info.iAlphatestRef );
tmpBuf.SetPixelShaderConstant1( 0, PARM_FLOAT( info.iAlphatestRef ) );
}
if ( bAlbedo )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER0, info.iAlbedo );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
if ( bEnvmap )
{
if ( building_cubemaps.GetBool() )
tmpBuf.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_BLACK );
else
{
if ( PARM_TEX( info.iEnvmap ) && !bModel )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER3, info.iEnvmap );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_LOCAL_ENV_CUBEMAP );
}
if ( bEnvmapMask )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER4, info.iEnvmapMask );
if ( bAlbedo2 )
{
if ( bEnvmapMask2 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER7, info.iEnvmapMask2 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER7, TEXTURE_WHITE );
}
tmpBuf.SetPixelShaderConstant( 5, info.iEnvmapTint );
float fl6[4] = { 0 };
fl6[0] = PARM_FLOAT( info.iEnvmapSaturation );
fl6[1] = PARM_FLOAT( info.iEnvmapContrast );
tmpBuf.SetPixelShaderConstant( 6, fl6 );
}
if ( bNeedsFresnel )
{
tmpBuf.SetPixelShaderConstant( 7, info.iFresnelRanges );
}
if ( bRimLight )
{
float fl9[4] = { 0 };
fl9[0] = PARM_FLOAT( info.iRimlightExponent );
fl9[1] = PARM_FLOAT( info.iRimlightAlbedoScale );
tmpBuf.SetPixelShaderConstant( 9, fl9 );
}
if ( bAlbedo2 )
{
tmpBuf.BindTexture( pShader, SHADER_SAMPLER5, info.iAlbedo2 );
if ( bBlendmodulate )
{
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, info.iBlendmodulateTransform );
tmpBuf.BindTexture( pShader, SHADER_SAMPLER6, info.iBlendmodulate );
}
}
if ( bMultiBlend )
{
tmpBuf.BindTexture( pShader, SHADER_SAMPLER7, info.iAlbedo3 );
if ( bAlbedo4 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER8, info.iAlbedo4 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER8, TEXTURE_WHITE );
if ( bBlendmodulate )
{
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.iBlendmodulateTransform2 );
tmpBuf.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_5, info.iBlendmodulateTransform3 );
if ( bBlendmodulate2 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER9, info.iBlendmodulate2 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER9, TEXTURE_BLACK );
if ( bBlendmodulate3 )
tmpBuf.BindTexture( pShader, SHADER_SAMPLER10, info.iBlendmodulate3 );
else
tmpBuf.BindStandardTexture( SHADER_SAMPLER10, TEXTURE_BLACK );
}
}
if ( bSelfIllum && bSelfIllumMask )
{
tmpBuf.BindTexture( pShader, SHADER_SAMPLER4, info.iSelfIllumMask );
}
int x, y, w, t;
pShaderAPI->GetCurrentViewport( x, y, w, t );
float fl1[4] = { 1.0f / w, 1.0f / t, 0, 0 };
tmpBuf.SetPixelShaderConstant( 1, fl1 );
tmpBuf.SetPixelShaderFogParams( 2 );
float fl4 = { PARM_FLOAT( info.iPhongScale ) };
tmpBuf.SetPixelShaderConstant1( 4, fl4 );
tmpBuf.End();
pDeferredContext->SetCommands( CDeferredPerMaterialContextData::DEFSTAGE_COMPOSITE, tmpBuf.Copy() );
}
pShaderAPI->SetDefaultState();
if ( bModel && bFastVTex )
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( composite_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (bModel && (int)vertexCompression) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, (bModel && pShaderAPI->GetCurrentNumBones() > 0) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, (bModel && pShaderAPI->IsHWMorphingEnabled()) ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER( composite_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( composite_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( composite_ps30 );
if ( bModel && bFastVTex )
{
bool bUnusedTexCoords[3] = { false, true, !pShaderAPI->IsHWMorphingEnabled() || !bIsDecal };
pShaderAPI->MarkUnusedVertexFields( 0, 3, bUnusedTexCoords );
}
pShaderAPI->ExecuteCommandBuffer( pDeferredContext->GetCommands( CDeferredPerMaterialContextData::DEFSTAGE_COMPOSITE ) );
if ( bGBufferNormal )
pShader->BindTexture( SHADER_SAMPLER1, GetDeferredExt()->GetTexture_Normals() );
pShader->BindTexture( SHADER_SAMPLER2, GetDeferredExt()->GetTexture_LightAccum() );
CommitBaseDeferredConstants_Origin( pShaderAPI, 3 );
if ( bWorldEyeVec )
{
float vEyepos[4] = {0,0,0,0};
pShaderAPI->GetWorldSpaceCameraPosition( vEyepos );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, vEyepos );
}
if ( bRimLight )
{
pShaderAPI->SetPixelShaderConstant( 8, params[ info.iRimlightTint ]->GetVecValue() );
}
if ( bSelfIllum )
{
pShaderAPI->SetPixelShaderConstant( 10, params[ info.iSelfIllumTint ]->GetVecValue() );
}
}
pShader->Draw();
}
void CBaseVSShader::DrawFlashlight_dx90( IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, DrawFlashlight_dx90_Vars_t &vars )
{
// FLASHLIGHTFIXME: hack . . need to fix the vertex shader so that it can deal with and without bumps for vertexlitgeneric
if( !vars.m_bLightmappedGeneric )
{
vars.m_bBump = false;
}
bool bBump2 = vars.m_bWorldVertexTransition && vars.m_bBump && vars.m_nBumpmap2Var != -1 && params[vars.m_nBumpmap2Var]->IsTexture();
bool bSeamless = vars.m_fSeamlessScale != 0.0;
bool bDetail = vars.m_bLightmappedGeneric && (vars.m_nDetailVar != -1) && params[vars.m_nDetailVar]->IsDefined() && (vars.m_nDetailScale != -1);
int nDetailBlendMode = 0;
if ( bDetail )
{
nDetailBlendMode = GetIntParam( vars.m_nDetailTextureCombineMode, params );
ITexture *pDetailTexture = params[vars.m_nDetailVar]->GetTextureValue();
if ( pDetailTexture->GetFlags() & TEXTUREFLAGS_SSBUMP )
{
if ( vars.m_bBump )
nDetailBlendMode = 10; // ssbump
else
nDetailBlendMode = 11; // ssbump_nobump
}
}
if( pShaderShadow )
{
SetInitialShadowState();
pShaderShadow->EnableDepthWrites( false );
pShaderShadow->EnableAlphaWrites( false );
// Alpha blend
SetAdditiveBlendingShadowState( BASETEXTURE, true );
// Alpha test
pShaderShadow->EnableAlphaTest( IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) );
if ( vars.m_nAlphaTestReference != -1 && params[vars.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[vars.m_nAlphaTestReference]->GetFloatValue() );
}
// Spot sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
// Base sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
// Normalizing cubemap sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
// Normalizing cubemap sampler2 or normal map sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
// RandomRotation sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
// Flashlight depth sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER7 );
if( vars.m_bWorldVertexTransition )
{
// $basetexture2
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true );
}
if( bBump2 )
{
// Normalmap2 sampler
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
}
if( bDetail )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true ); // detail sampler
if ( nDetailBlendMode == 1 )
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, true );
}
pShaderShadow->EnableSRGBWrite( true );
if( vars.m_bLightmappedGeneric )
{
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( WORLDVERTEXTRANSITION, vars.m_bWorldVertexTransition );
SET_STATIC_VERTEX_SHADER_COMBO( NORMALMAP, vars.m_bBump );
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamless );
SET_STATIC_VERTEX_SHADER_COMBO( DETAIL, bDetail );
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs30 );
}
else
#endif
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( WORLDVERTEXTRANSITION, vars.m_bWorldVertexTransition );
SET_STATIC_VERTEX_SHADER_COMBO( NORMALMAP, vars.m_bBump );
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamless );
SET_STATIC_VERTEX_SHADER_COMBO( DETAIL, bDetail );
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs20 );
}
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
if( vars.m_bBump )
{
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T;
}
int numTexCoords = 1;
if( vars.m_bWorldVertexTransition )
{
flags |= VERTEX_COLOR;
numTexCoords = 2; // need lightmap texcoords to get alpha.
}
pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, 0 );
}
else
{
// Need a 3.0 vs here?
DECLARE_STATIC_VERTEX_SHADER( vertexlitgeneric_flashlight_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( TEETH, vars.m_bTeeth );
SET_STATIC_VERTEX_SHADER( vertexlitgeneric_flashlight_vs20 );
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int numTexCoords = 1;
pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, vars.m_bBump ? 4 : 0 );
}
int nBumpMapVariant = 0;
if ( vars.m_bBump )
{
nBumpMapVariant = ( vars.m_bSSBump ) ? 2 : 1;
}
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
int nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode();
DECLARE_STATIC_PIXEL_SHADER( flashlight_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP, nBumpMapVariant );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP2, bBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( WORLDVERTEXTRANSITION, vars.m_bWorldVertexTransition );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamless );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, bDetail );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( flashlight_ps30 );
}
else
#endif
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
int nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode();
DECLARE_STATIC_PIXEL_SHADER( flashlight_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP, nBumpMapVariant );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP2, bBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( WORLDVERTEXTRANSITION, vars.m_bWorldVertexTransition );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamless );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, bDetail );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( flashlight_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( flashlight_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP, nBumpMapVariant );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAP2, bBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( WORLDVERTEXTRANSITION, vars.m_bWorldVertexTransition );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamless );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, bDetail );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER( flashlight_ps20 );
}
FogToBlack();
PI_BeginCommandBuffer();
PI_SetModulationPixelShaderDynamicState( PSREG_DIFFUSE_MODULATION );
PI_EndCommandBuffer();
}
else
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
SetFlashLightColorFromState( flashlightState, pShaderAPI, false );
BindTexture( SHADER_SAMPLER0, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_SHADOW_NOISE_2D );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && flashlightState.m_bEnableShadows )
{
BindTexture( SHADER_SAMPLER7, pFlashlightDepthTexture, 0 );
// Tweaks associated with a given flashlight
float tweaks[4];
tweaks[0] = ShadowFilterFromState( flashlightState );
tweaks[1] = ShadowAttenFromState( flashlightState );
HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
int nTexWidth, nTexHeight;
pShaderAPI->GetStandardTextureDimensions( &nTexWidth, &nTexHeight, TEXTURE_SHADOW_NOISE_2D );
vScreenScale[0] = (float) nWidth / nTexWidth;
vScreenScale[1] = (float) nHeight / nTexHeight;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER7, TEXTURE_WHITE );
}
if( params[BASETEXTURE]->IsTexture() && mat_fullbright.GetInt() != 2 )
{
BindTexture( SHADER_SAMPLER1, BASETEXTURE, FRAME );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER1, TEXTURE_GREY );
}
if( vars.m_bWorldVertexTransition )
{
Assert( vars.m_nBaseTexture2Var >= 0 && vars.m_nBaseTexture2FrameVar >= 0 );
BindTexture( SHADER_SAMPLER4, vars.m_nBaseTexture2Var, vars.m_nBaseTexture2FrameVar );
}
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_NORMALIZATION_CUBEMAP );
if( vars.m_bBump )
{
BindTexture( SHADER_SAMPLER3, vars.m_nBumpmapVar, vars.m_nBumpmapFrame );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALIZATION_CUBEMAP );
}
if( bDetail )
{
BindTexture( SHADER_SAMPLER8, vars.m_nDetailVar );
}
if( vars.m_bWorldVertexTransition )
{
if( bBump2 )
{
BindTexture( SHADER_SAMPLER6, vars.m_nBumpmap2Var, vars.m_nBumpmap2Frame );
}
}
if( vars.m_bLightmappedGeneric )
{
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs30 );
SET_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs30 );
}
else
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs20 );
SET_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_flashlight_vs20 );
}
if ( bSeamless )
{
float const0[4]={ vars.m_fSeamlessScale,0,0,0};
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, const0 );
}
if ( bDetail )
{
float vDetailConstants[4] = {1,1,1,1};
if ( vars.m_nDetailTint != -1 )
{
params[vars.m_nDetailTint]->GetVecValue( vDetailConstants, 3 );
}
if ( vars.m_nDetailTextureBlendFactor != -1 )
{
vDetailConstants[3] = params[vars.m_nDetailTextureBlendFactor]->GetFloatValue();
}
pShaderAPI->SetPixelShaderConstant( 0, vDetailConstants, 1 );
}
}
else
{
DECLARE_DYNAMIC_VERTEX_SHADER( vertexlitgeneric_flashlight_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER( vertexlitgeneric_flashlight_vs20 );
if( vars.m_bTeeth )
{
Assert( vars.m_nTeethForwardVar >= 0 );
Assert( vars.m_nTeethIllumFactorVar >= 0 );
Vector4D lighting;
params[vars.m_nTeethForwardVar]->GetVecValue( lighting.Base(), 3 );
lighting[3] = params[vars.m_nTeethIllumFactorVar]->GetFloatValue();
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, lighting.Base() );
}
}
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
float vEyePos_SpecExponent[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
vEyePos_SpecExponent[3] = 0.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( flashlight_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, flashlightState.m_bEnableShadows );
SET_DYNAMIC_PIXEL_SHADER_COMBO( UBERLIGHT, flashlightState.m_bUberlight );
SET_DYNAMIC_PIXEL_SHADER( flashlight_ps30 );
SetupUberlightFromState( pShaderAPI, flashlightState );
}
else
#endif
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( flashlight_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, flashlightState.m_bEnableShadows );
SET_DYNAMIC_PIXEL_SHADER( flashlight_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( flashlight_ps20 );
SET_DYNAMIC_PIXEL_SHADER( flashlight_ps20 );
}
float atten[4]; // Set the flashlight attenuation factors
atten[0] = flashlightState.m_fConstantAtten;
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZAtten;
s_pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, atten, 1 );
float pos[4]; // Set the flashlight origin
pos[0] = flashlightState.m_vecLightOrigin[0];
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pos[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, pos, 1 ); // rim boost not really used here
SetFlashlightVertexShaderConstants( vars.m_bBump, vars.m_nBumpTransform, bDetail, vars.m_nDetailScale, bSeamless ? false : true );
}
Draw();
}
void DrawUsingVertexShader( IMaterialVar** params, IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow, VertexCompressionType_t vertexCompression )
{
bool hasBump = params[BUMPMAP]->IsTexture();
BlendType_t nBlendType = EvaluateBlendRequirements( BASETEXTURE, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !IS_FLAG_SET(MATERIAL_VAR_ALPHATEST); //dest alpha is free for special use
SHADOW_STATE
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Base map
int flags = VERTEX_POSITION | VERTEX_NORMAL;
int nTexCoordCount = 1;
int userDataSize = 0;
if ( hasBump )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Bump map
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Normalization sampler for per-pixel lighting
userDataSize = 4; // tangent S
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
if ( hasBump )
{
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( sdk_teeth_bump_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, params[INTRO]->GetIntValue() ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_teeth_bump_vs20 );
// ps_2_b version which does phong
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps20b );
SET_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps20 );
SET_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( sdk_teeth_bump_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, params[INTRO]->GetIntValue() ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_teeth_bump_vs30 );
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps30 );
SET_STATIC_PIXEL_SHADER( sdk_teeth_bump_ps30 );
}
#endif
}
else
{
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( sdk_teeth_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, params[INTRO]->GetIntValue() ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_teeth_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_ps20b );
SET_STATIC_PIXEL_SHADER( sdk_teeth_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_ps20 );
SET_STATIC_PIXEL_SHADER( sdk_teeth_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( sdk_teeth_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, params[INTRO]->GetIntValue() ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_teeth_vs30 );
DECLARE_STATIC_PIXEL_SHADER( sdk_teeth_ps30 );
SET_STATIC_PIXEL_SHADER( sdk_teeth_ps30 );
}
#endif
}
// On DX9, do sRGB
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBWrite( true );
FogToFogColor();
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
}
DYNAMIC_STATE
{
BindTexture( SHADER_SAMPLER0, BASETEXTURE, FRAME );
if ( hasBump )
{
BindTexture( SHADER_SAMPLER1, BUMPMAP );
}
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
pShaderAPI->SetPixelShaderStateAmbientLightCube( PSREG_AMBIENT_CUBE );
pShaderAPI->CommitPixelShaderLighting( PSREG_LIGHT_INFO_ARRAY );
Vector4D lighting;
params[FORWARD]->GetVecValue( lighting.Base(), 3 );
lighting[3] = params[ILLUMFACTOR]->GetFloatValue();
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, lighting.Base() );
LightState_t lightState;
pShaderAPI->GetDX9LightState( &lightState );
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
float vEyePos_SpecExponent[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
vEyePos_SpecExponent[3] = 0.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
if ( hasBump )
{
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_teeth_bump_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_teeth_bump_vs20 );
// ps_2_b version which does Phong
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
Vector4D vSpecExponent;
vSpecExponent[3] = params[PHONGEXPONENT]->GetFloatValue();
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vSpecExponent.Base(), 1 );
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps20 );
}
}
#ifndef _X360
else
{
SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_teeth_bump_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_teeth_bump_vs30 );
Vector4D vSpecExponent;
vSpecExponent[3] = params[PHONGEXPONENT]->GetFloatValue();
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vSpecExponent.Base(), 1 );
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( AMBIENT_LIGHT, lightState.m_bAmbientLight ? 1 : 0 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_bump_ps30 );
}
#endif
}
else
{
// For non-bumped case, ambient cube is computed in the vertex shader
SetAmbientCubeDynamicStateVertexShader();
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_teeth_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_teeth_vs20 );
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps20 );
}
}
#ifndef _X360
else
{
SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_teeth_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_teeth_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bFullyOpaque && pShaderAPI->ShouldWriteDepthToDestAlpha() );
SET_DYNAMIC_PIXEL_SHADER( sdk_teeth_ps30 );
}
#endif
}
if( params[INTRO]->GetIntValue() )
{
float curTime = params[WARPPARAM]->GetFloatValue();
float timeVec[4] = { 0.0f, 0.0f, 0.0f, curTime };
Assert( params[ENTITYORIGIN]->IsDefined() );
params[ENTITYORIGIN]->GetVecValue( timeVec, 3 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, timeVec, 1 );
}
}
Draw();
}
inline void DrawFlora( IMaterialVar **params, IShaderShadow* pShaderShadow,
IShaderDynamicAPI* pShaderAPI, VertexCompressionType_t vertexCompression, CBasePerMaterialContextData *pContextDataPtr )
{
const bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
const bool bHasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
SHADOW_STATE
{
SetInitialShadowState();
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if ( params[ALPHATESTREFERENCE]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[ALPHATESTREFERENCE]->GetFloatValue() );
}
DefaultFog();
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true ); // FOW
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true ); // Deferred light 1
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true ); // Deferred light 2
int iVFmtFlags = VERTEX_POSITION;
int iUserDataSize = 0;
// texcoord0 : base texcoord
int pTexCoordDim[3] = { 2, 2, 3 };
int nTexCoordCount = 1;
// This shader supports compressed vertices, so OR in that flag:
iVFmtFlags |= VERTEX_FORMAT_COMPRESSED;
if ( bHasVertexColor )
{
iVFmtFlags |= VERTEX_COLOR;
}
pShaderShadow->VertexShaderVertexFormat( iVFmtFlags, nTexCoordCount, pTexCoordDim, iUserDataSize );
// The vertex shader uses the vertex id stream
if( g_pHardwareConfig->HasFastVertexTextures() )
{
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
SET_FLAGS2( MATERIAL_VAR2_SUPPORTS_TESSELLATION );
}
// Vertex Shader
DECLARE_STATIC_VERTEX_SHADER( flora_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, bHasVertexColor );
SET_STATIC_VERTEX_SHADER( flora_vs30 );
// Pixel Shader
DECLARE_STATIC_PIXEL_SHADER( flora_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, bHasVertexColor );
SET_STATIC_PIXEL_SHADER( flora_ps30 );
// Textures
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
//pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
// Blending
EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaTest( true );
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GREATER, 0.0f );
}
DYNAMIC_STATE
{
// Reset render state
pShaderAPI->SetDefaultState();
BindTexture( SHADER_SAMPLER0, BASETEXTURE ); // Base Map 1
//if ( bHasFoW )
{
BindTexture( SHADER_SAMPLER10, FOW, -1 );
float vFoWSize[ 4 ];
Vector vMins = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MINS );
Vector vMaxs = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MAXS );
vFoWSize[ 0 ] = vMins.x;
vFoWSize[ 1 ] = vMins.y;
vFoWSize[ 2 ] = vMaxs.x - vMins.x;
vFoWSize[ 3 ] = vMaxs.y - vMins.y;
pShaderAPI->SetVertexShaderConstant( 26, vFoWSize );
}
BindTexture( SHADER_SAMPLER13, GetDeferredExt()->GetTexture_LightAccum() );
BindTexture( SHADER_SAMPLER14, GetDeferredExt()->GetTexture_LightAccum2() );
int x, y, w, t;
pShaderAPI->GetCurrentViewport( x, y, w, t );
float fl1[4] = { 1.0f / w, 1.0f / t, 0, 0 };
pShaderAPI->SetPixelShaderConstant( 3, fl1 );
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( flora_vs30 );
SET_DYNAMIC_VERTEX_SHADER( flora_vs30 );
// Set Pixel Shader Combos
DECLARE_DYNAMIC_PIXEL_SHADER( flora_ps30 );
SET_DYNAMIC_PIXEL_SHADER( flora_ps30 );
}
Draw();
}
//-----------------------------------------------------------------------------
// Draws the shader
//-----------------------------------------------------------------------------
void DrawExampleModel_DX9_Internal( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow,
bool bHasFlashlight, ExampleModel_DX9_Vars_t &info, VertexCompressionType_t vertexCompression,
CBasePerMaterialContextData **pContextDataPtr )
{
bool bHasBaseTexture = (info.m_nBaseTexture != -1) && params[info.m_nBaseTexture]->IsTexture();
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
BlendType_t nBlendType= pShader->EvaluateBlendRequirements( info.m_nBaseTexture, true );
bool bFullyOpaque = ( nBlendType != BT_BLENDADD ) && ( nBlendType != BT_BLEND ) && !bIsAlphaTested && !bHasFlashlight;
CExampleModel_DX9_Context *pContextData = reinterpret_cast< CExampleModel_DX9_Context *> ( *pContextDataPtr );
if ( !pContextData )
{
pContextData = new CExampleModel_DX9_Context;
*pContextDataPtr = pContextData;
}
if( pShader->IsSnapshotting() )
{
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
int nShadowFilterMode = 0;
if( bHasFlashlight )
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetAdditiveBlendingShadowState( info.m_nBaseTexture, true );
}
if( bIsAlphaTested )
{
// disable alpha test and use the zfunc zequals since alpha isn't guaranteed to
// be the same on both the regular pass and the flashlight pass.
pShaderShadow->EnableAlphaTest( false );
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
}
pShaderShadow->EnableBlending( true );
pShaderShadow->EnableDepthWrites( false );
// Be sure not to write to dest alpha
pShaderShadow->EnableAlphaWrites( false );
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
else // not flashlight pass
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetDefaultBlendingShadowState( info.m_nBaseTexture, true );
}
}
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int userDataSize = 0;
// Always enable...will bind white if nothing specified...
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Base (albedo) map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
if( bHasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER4 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Noise map
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Flashlight cookie
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, true );
userDataSize = 4; // tangent S
}
// Always enable, since flat normal will be bound
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Normal map
userDataSize = 4; // tangent S
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Normalizing cube map
pShaderShadow->EnableSRGBWrite( true );
// texcoord0 : base texcoord, texcoord2 : decal hw morph delta
int pTexCoordDim[3] = { 2, 0, 3 };
int nTexCoordCount = 1;
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, pTexCoordDim, userDataSize );
DECLARE_STATIC_VERTEX_SHADER( example_model_vs20 );
SET_STATIC_VERTEX_SHADER( example_model_vs20 );
// Assume we're only going to get in here if we support 2b
DECLARE_STATIC_PIXEL_SHADER( example_model_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( CONVERT_TO_SRGB, 0 );
SET_STATIC_PIXEL_SHADER( example_model_ps20b );
if( bHasFlashlight )
{
pShader->FogToBlack();
}
else
{
pShader->DefaultFog();
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for underwater stuff
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
}
else // not snapshotting -- begin dynamic state
{
bool bLightingOnly = mat_fullbright.GetInt() == 2 && !IS_FLAG_SET( MATERIAL_VAR_NO_DEBUG_OVERRIDE );
if( bHasBaseTexture )
{
pShader->BindTexture( SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
LightState_t lightState = { 0, false, false };
bool bFlashlightShadows = false;
if( bHasFlashlight )
{
Assert( info.m_nFlashlightTexture >= 0 && info.m_nFlashlightTextureFrame >= 0 );
pShader->BindTexture( SHADER_SAMPLER6, info.m_nFlashlightTexture, info.m_nFlashlightTextureFrame );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
bFlashlightShadows = state.m_bEnableShadows && ( pFlashlightDepthTexture != NULL );
SetFlashLightColorFromState( state, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && state.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER4, pFlashlightDepthTexture, 0 );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_SHADOW_NOISE_2D );
}
}
else // no flashlight
{
pShaderAPI->GetDX9LightState( &lightState );
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int fogIndex = ( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z ) ? 1 : 0;
int numBones = pShaderAPI->GetCurrentNumBones();
bool bWriteDepthToAlpha = false;
bool bWriteWaterFogToAlpha = false;
if( bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
DECLARE_DYNAMIC_VERTEX_SHADER( example_model_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, numBones > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING)!=0);
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER( example_model_vs20 );
DECLARE_DYNAMIC_PIXEL_SHADER( example_model_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( example_model_ps20b );
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
pShader->SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
pShader->SetAmbientCubeDynamicStateVertexShader();
if( !bHasFlashlight )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
}
pShaderAPI->SetPixelShaderStateAmbientLightCube( PSREG_AMBIENT_CUBE, !lightState.m_bAmbientLight ); // Force to black if not bAmbientLight
pShaderAPI->CommitPixelShaderLighting( PSREG_LIGHT_INFO_ARRAY );
// handle mat_fullbright 2 (diffuse lighting only)
if( bLightingOnly )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
}
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
if( bHasFlashlight )
{
VMatrix worldToTexture;
float atten[4], pos[4], tweaks[4];
const FlashlightState_t &flashlightState = pShaderAPI->GetFlashlightState( worldToTexture );
SetFlashLightColorFromState( flashlightState, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
pShader->BindTexture( SHADER_SAMPLER6, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
atten[0] = flashlightState.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, atten, 1 );
pos[0] = flashlightState.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, pos, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_TO_WORLD_TEXTURE, worldToTexture.Base(), 4 );
// Tweaks associated with a given flashlight
tweaks[0] = ShadowFilterFromState( flashlightState );
tweaks[1] = ShadowAttenFromState( flashlightState );
pShader->HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
vScreenScale[0] = (float) nWidth / 32.0f;
vScreenScale[1] = (float) nHeight / 32.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
}
}
pShader->Draw();
}
static void DrawFlashlight( bool bDX9, CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, Eyes_DX8_DX9_Vars_t &info, VertexCompressionType_t vertexCompression )
{
if( pShaderShadow )
{
pShaderShadow->EnableDepthWrites( false );
pShader->EnableAlphaBlending( SHADER_BLEND_ONE, SHADER_BLEND_ONE ); // Write over the eyes that were already there
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Spot
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Base
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Normalizing cubemap
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Iris
// Set stream format (note that this shader supports compression)
int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
// Be sure not to write to dest alpha
pShaderShadow->EnableAlphaWrites( false );
#ifdef STDSHADER_DX9_DLL_EXPORT
if ( bDX9 )
{
int nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( sdk_eyes_flashlight_vs20 );
SET_STATIC_VERTEX_SHADER( sdk_eyes_flashlight_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20 );
SET_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( sdk_eyes_flashlight_vs30 );
SET_STATIC_VERTEX_SHADER( sdk_eyes_flashlight_vs30 );
DECLARE_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( sdk_eyes_flashlight_ps30 );
}
#endif
// On DX9, get the gamma read and write correct
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true ); // Spot
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true ); // Base
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, true ); // Iris
pShaderShadow->EnableSRGBWrite( true );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER4 );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Shadow noise rotation map
}
}
else
#endif
{
// DX8 uses old asm shaders
sdk_eyes_flashlight_vs11_Static_Index vshIndex;
pShaderShadow->SetVertexShader( "sdk_eyes_flashlight_vs11", vshIndex.GetIndex() );
sdk_eyes_flashlight_ps11_Static_Index pshIndex;
pShaderShadow->SetPixelShader( "sdk_eyes_flashlight_ps11", pshIndex.GetIndex() );
}
pShader->FogToBlack();
}
else
{
// Specify that we have XYZ texcoords that need to be divided by W before the pixel shader.
// NOTE Tried to divide XY by Z, but doesn't work.
// The dx9.0c runtime says that we shouldn't have a non-zero dimension when using vertex and pixel shaders.
if ( !bDX9 )
{
pShaderAPI->SetTextureTransformDimension( SHADER_TEXTURE_STAGE0, 0, true );
}
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
pShader->BindTexture( SHADER_SAMPLER0, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
pShader->BindTexture( SHADER_SAMPLER1, info.m_nBaseTexture, info.m_nFrame );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_NORMALIZATION_CUBEMAP );
pShader->BindTexture( SHADER_SAMPLER3, info.m_nIris, info.m_nIrisFrame );
#ifdef STDSHADER_DX9_DLL_EXPORT
if ( bDX9 )
{
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_eyes_flashlight_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_eyes_flashlight_vs20 );
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_eyes_flashlight_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_eyes_flashlight_vs30 );
}
#endif
// float vPSConst[4] = {params[info.m_nDilation]->GetFloatValue(), 0.0f, 0.0f, 0.0f};
// pShaderAPI->SetPixelShaderConstant( 0, vPSConst, 1 );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
SetFlashLightColorFromState( flashlightState, pShaderAPI );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && flashlightState.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER4, pFlashlightDepthTexture, 0 );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_SHADOW_NOISE_2D );
}
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
float vEyePos_SpecExponent[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
vEyePos_SpecExponent[3] = 0.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, flashlightState.m_bEnableShadows );
SET_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20b );
SetDepthFlashlightParams( pShader, pShaderAPI, worldToTexture, flashlightState );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps20 );
}
}
#ifndef _X360
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, flashlightState.m_bEnableShadows );
SET_DYNAMIC_PIXEL_SHADER( sdk_eyes_flashlight_ps30 );
SetDepthFlashlightParams( pShader, pShaderAPI, worldToTexture, flashlightState );
}
#endif
}
else // older asm shaders for DX8
#endif
{
sdk_eyes_flashlight_vs11_Dynamic_Index vshIndex;
vshIndex.SetDOWATERFOG( pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
vshIndex.SetSKINNING( pShaderAPI->GetCurrentNumBones() > 0 );
pShaderAPI->SetVertexShaderIndex( vshIndex.GetIndex() );
sdk_eyes_flashlight_ps11_Dynamic_Index pshIndex;
pShaderAPI->SetPixelShaderIndex( pshIndex.GetIndex() );
}
// This uses from VERTEX_SHADER_SHADER_SPECIFIC_CONST_0 to VERTEX_SHADER_SHADER_SPECIFIC_CONST_5
pShader->SetFlashlightVertexShaderConstants( false, -1, false, -1, false );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, info.m_nEyeOrigin );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, info.m_nEyeUp );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_8, info.m_nIrisU );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_9, info.m_nIrisV );
}
pShader->Draw();
}
void DrawLightmappedGeneric_DX9_Internal(CBaseVSShader *pShader, IMaterialVar** params, bool hasFlashlight,
IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow,
LightmappedGeneric_DX9_Vars_t &info,
CBasePerMaterialContextData **pContextDataPtr
)
{
CLightmappedGeneric_DX9_Context *pContextData = reinterpret_cast< CLightmappedGeneric_DX9_Context *> ( *pContextDataPtr );
if ( pShaderShadow || ( ! pContextData ) || pContextData->m_bMaterialVarsChanged || hasFlashlight )
{
bool hasBaseTexture = params[info.m_nBaseTexture]->IsTexture();
int nAlphaChannelTextureVar = hasBaseTexture ? (int)info.m_nBaseTexture : (int)info.m_nEnvmapMask;
BlendType_t nBlendType = pShader->EvaluateBlendRequirements( nAlphaChannelTextureVar, hasBaseTexture );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
bool bFullyOpaqueWithoutAlphaTest = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && (!hasFlashlight || IsX360()); //dest alpha is free for special use
bool bFullyOpaque = bFullyOpaqueWithoutAlphaTest && !bIsAlphaTested;
bool bNeedRegenStaticCmds = (! pContextData ) || pShaderShadow;
if ( ! pContextData ) // make sure allocated
{
pContextData = new CLightmappedGeneric_DX9_Context;
*pContextDataPtr = pContextData;
}
bool hasBump = ( params[info.m_nBumpmap]->IsTexture() ) && ( !g_pHardwareConfig->PreferReducedFillrate() );
bool hasSSBump = hasBump && (info.m_nSelfShadowedBumpFlag != -1) && ( params[info.m_nSelfShadowedBumpFlag]->GetIntValue() );
bool hasBaseTexture2 = hasBaseTexture && params[info.m_nBaseTexture2]->IsTexture();
bool hasLightWarpTexture = params[info.m_nLightWarpTexture]->IsTexture();
bool hasBump2 = hasBump && params[info.m_nBumpmap2]->IsTexture();
bool hasDetailTexture = params[info.m_nDetail]->IsTexture();
bool hasSelfIllum = IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
bool hasBumpMask = hasBump && hasBump2 && params[info.m_nBumpMask]->IsTexture() && !hasSelfIllum &&
!hasDetailTexture && !hasBaseTexture2 && (params[info.m_nBaseTextureNoEnvmap]->GetIntValue() == 0);
bool bHasBlendModulateTexture =
(info.m_nBlendModulateTexture != -1) &&
(params[info.m_nBlendModulateTexture]->IsTexture() );
bool hasNormalMapAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
// Parallax cubemaps
bool hasParallaxCorrection = params[info.m_nEnvmapParallaxObb1]->IsDefined();
if ( hasFlashlight && !IsX360() )
{
// !!speed!! do this in the caller so we don't build struct every time
CBaseVSShader::DrawFlashlight_dx90_Vars_t vars;
vars.m_bBump = hasBump;
vars.m_nBumpmapVar = info.m_nBumpmap;
vars.m_nBumpmapFrame = info.m_nBumpFrame;
vars.m_nBumpTransform = info.m_nBumpTransform;
vars.m_nFlashlightTextureVar = info.m_nFlashlightTexture;
vars.m_nFlashlightTextureFrameVar = info.m_nFlashlightTextureFrame;
vars.m_bLightmappedGeneric = true;
vars.m_bWorldVertexTransition = hasBaseTexture2;
vars.m_nBaseTexture2Var = info.m_nBaseTexture2;
vars.m_nBaseTexture2FrameVar = info.m_nBaseTexture2Frame;
vars.m_nBumpmap2Var = info.m_nBumpmap2;
vars.m_nBumpmap2Frame = info.m_nBumpFrame2;
vars.m_nBump2Transform = info.m_nBumpTransform2;
vars.m_nAlphaTestReference = info.m_nAlphaTestReference;
vars.m_bSSBump = hasSSBump;
vars.m_nDetailVar = info.m_nDetail;
vars.m_nDetailScale = info.m_nDetailScale;
vars.m_nDetailTextureCombineMode = info.m_nDetailTextureCombineMode;
vars.m_nDetailTextureBlendFactor = info.m_nDetailTextureBlendFactor;
vars.m_nDetailTint = info.m_nDetailTint;
if ( ( info.m_nSeamlessMappingScale != -1 ) )
vars.m_fSeamlessScale = params[info.m_nSeamlessMappingScale]->GetFloatValue();
else
vars.m_fSeamlessScale = 0.0;
pShader->DrawFlashlight_dx90( params, pShaderAPI, pShaderShadow, vars );
return;
}
pContextData->m_bFullyOpaque = bFullyOpaque;
pContextData->m_bFullyOpaqueWithoutAlphaTest = bFullyOpaqueWithoutAlphaTest;
NormalDecodeMode_t nNormalDecodeMode = NORMAL_DECODE_NONE;
if ( hasBump && g_pHardwareConfig->SupportsNormalMapCompression() && g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
ITexture *pBumpTex = params[info.m_nBumpmap]->GetTextureValue();
if ( pBumpTex )
{
nNormalDecodeMode = pBumpTex->GetNormalDecodeMode();
if ( hasBump2 ) // Check encoding of secondary normal if there is oneg
{
ITexture *pBumpTex2 = params[info.m_nBumpmap]->GetTextureValue();
if ( pBumpTex2 && ( pBumpTex2->GetNormalDecodeMode() != nNormalDecodeMode ) )
{
DevMsg("LightmappedGeneric: Primary and Secondary normal map compression formats don't match. This is unsupported!\n");
Assert(0);
}
}
}
}
int nNormalMaskDecodeMode = 0;
if ( hasBumpMask && g_pHardwareConfig->SupportsNormalMapCompression() && g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
ITexture *pBumpMaskTex = params[info.m_nBumpMask]->GetTextureValue();
if ( pBumpMaskTex )
{
nNormalMaskDecodeMode = pBumpMaskTex->GetNormalDecodeMode();
}
}
bool bHasOutline = IsBoolSet( info.m_nOutline, params );
pContextData->m_bPixelShaderForceFastPathBecauseOutline = bHasOutline;
bool bHasSoftEdges = IsBoolSet( info.m_nSoftEdges, params );
bool hasEnvmapMask = params[info.m_nEnvmapMask]->IsTexture();
float fDetailBlendFactor = GetFloatParam( info.m_nDetailTextureBlendFactor, params, 1.0 );
if ( pShaderShadow || bNeedRegenStaticCmds )
{
bool hasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool hasDiffuseBumpmap = hasBump && (params[info.m_nNoDiffuseBumpLighting]->GetIntValue() == 0);
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
bool bSeamlessMapping = ( ( info.m_nSeamlessMappingScale != -1 ) &&
( params[info.m_nSeamlessMappingScale]->GetFloatValue() != 0.0 ) );
if ( bNeedRegenStaticCmds )
{
pContextData->ResetStaticCmds();
CCommandBufferBuilder< CFixedCommandStorageBuffer< 5000 > > staticCmdsBuf;
if( !hasBaseTexture )
{
if( hasEnvmap )
{
// if we only have an envmap (no basetexture), then we want the albedo to be black.
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_BLACK );
}
else
{
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
}
staticCmdsBuf.BindStandardTexture( SHADER_SAMPLER1, TEXTURE_LIGHTMAP );
if ( bSeamlessMapping )
{
staticCmdsBuf.SetVertexShaderConstant4(
VERTEX_SHADER_SHADER_SPECIFIC_CONST_0,
params[info.m_nSeamlessMappingScale]->GetFloatValue(),0,0,0 );
}
staticCmdsBuf.StoreEyePosInPixelShaderConstant( 10 );
staticCmdsBuf.SetPixelShaderFogParams( 11 );
staticCmdsBuf.End();
// now, copy buf
pContextData->m_pStaticCmds = new uint8[staticCmdsBuf.Size()];
memcpy( pContextData->m_pStaticCmds, staticCmdsBuf.Base(), staticCmdsBuf.Size() );
}
if ( pShaderShadow )
{
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if ( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
pShader->SetDefaultBlendingShadowState( nAlphaChannelTextureVar, hasBaseTexture );
unsigned int flags = VERTEX_POSITION;
// base texture
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
if ( hasLightWarpTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, false );
}
if ( bHasBlendModulateTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, false );
}
if ( hasBaseTexture2 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER7, true );
}
// if( hasLightmap )
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
}
else
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false );
}
if( hasEnvmap || ( IsX360() && hasFlashlight ) )
{
if( hasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
}
}
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T | VERTEX_NORMAL;
}
int nDetailBlendMode = 0;
if ( hasDetailTexture )
{
nDetailBlendMode = GetIntParam( info.m_nDetailTextureCombineMode, params );
ITexture *pDetailTexture = params[info.m_nDetail]->GetTextureValue();
if ( pDetailTexture->GetFlags() & TEXTUREFLAGS_SSBUMP )
{
if ( hasBump )
nDetailBlendMode = 10; // ssbump
else
nDetailBlendMode = 11; // ssbump_nobump
}
}
if( hasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true );
bool bSRGBState = ( nDetailBlendMode == 1 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER12, bSRGBState );
}
if( hasBump || hasNormalMapAlphaEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true ); // Normal map alpha, in the compressed normal case
}
}
if( hasBump2 )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true ); // Secondary normal alpha, in the compressed normal case
}
}
if( hasBumpMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true );
if ( nNormalMaskDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true ); // Normal mask alpha, in the compressed normal case
}
}
if( hasEnvmapMask )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
}
if( hasFlashlight && IsX360() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER14 );
pShaderShadow->EnableTexture( SHADER_SAMPLER15, true );
}
if( hasVertexColor || hasBaseTexture2 || hasBump2 )
{
flags |= VERTEX_COLOR;
}
// texcoord0 : base texcoord
// texcoord1 : lightmap texcoord
// texcoord2 : lightmap texcoord offset
int numTexCoords = 2;
if( hasBump )
{
numTexCoords = 3;
}
pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, 0 );
// Pre-cache pixel shaders
bool hasBaseAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_BASEALPHAENVMAPMASK );
int bumpmap_variant=(hasSSBump) ? 2 : hasBump;
bool bMaskedBlending=( (info.m_nMaskedBlending != -1) &&
(params[info.m_nMaskedBlending]->GetIntValue() != 0) );
DECLARE_STATIC_VERTEX_SHADER( sdk_lightmappedgeneric_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( ENVMAP_MASK, hasEnvmapMask );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, params[info.m_nEnvmap]->IsTexture() );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_VERTEX_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR ) );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXALPHATEXBLENDFACTOR, hasBaseTexture2 || hasBump2 );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMASK, hasBumpMask );
bool bReliefMapping = false; //( bumpmap_variant == 2 ) && ( ! bSeamlessMapping );
SET_STATIC_VERTEX_SHADER_COMBO( RELIEF_MAPPING, false );//bReliefMapping );
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
#ifdef _X360
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, hasFlashlight);
#endif
SET_STATIC_VERTEX_SHADER(sdk_lightmappedgeneric_vs20);
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20b);
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2, hasBaseTexture2 );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bumpmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP2, hasBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, hasEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURENOENVMAP, params[info.m_nBaseTextureNoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2NOENVMAP, params[info.m_nBaseTexture2NoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( WARPLIGHTING, hasLightWarpTexture );
SET_STATIC_PIXEL_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKEDBLENDING, bMaskedBlending);
SET_STATIC_PIXEL_SHADER_COMBO( RELIEF_MAPPING, bReliefMapping );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( OUTLINE, bHasOutline );
SET_STATIC_PIXEL_SHADER_COMBO( SOFTEDGES, bHasSoftEdges );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( NORMAL_DECODE_MODE, (int) nNormalDecodeMode );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMASK_DECODE_MODE, (int) nNormalMaskDecodeMode );
// Parallax cubemaps enabled for 2_0b and onwards
SET_STATIC_PIXEL_SHADER_COMBO( PARALLAXCORRECT, hasParallaxCorrection );
#ifdef _X360
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight);
#endif
SET_STATIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20b);
}
else
{
DECLARE_STATIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20);
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2, hasBaseTexture2 );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bumpmap_variant );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP2, hasBump2 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMASK, hasBumpMask );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, hasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( ENVMAPMASK, hasEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMAPALPHAENVMAPMASK, hasNormalMapAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURENOENVMAP, params[info.m_nBaseTextureNoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( BASETEXTURE2NOENVMAP, params[info.m_nBaseTexture2NoEnvmap]->GetIntValue() );
SET_STATIC_PIXEL_SHADER_COMBO( WARPLIGHTING, hasLightWarpTexture );
SET_STATIC_PIXEL_SHADER_COMBO( FANCY_BLENDING, bHasBlendModulateTexture );
SET_STATIC_PIXEL_SHADER_COMBO( MASKEDBLENDING, bMaskedBlending);
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( OUTLINE, bHasOutline );
SET_STATIC_PIXEL_SHADER_COMBO( SOFTEDGES, bHasSoftEdges );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( NORMAL_DECODE_MODE, 0 ); // No normal compression with ps_2_0 (yikes!)
SET_STATIC_PIXEL_SHADER_COMBO( NORMALMASK_DECODE_MODE, 0 ); // No normal compression with ps_2_0
// Parallax cubemaps
SET_STATIC_PIXEL_SHADER_COMBO(PARALLAXCORRECT, 0); // No parallax cubemaps with ps_2_0
SET_STATIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20);
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for
// underwater stuff and writing depth to dest alpha
// But only do it if we're not using the alpha already for translucency
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
pShaderShadow->EnableSRGBWrite( true );
pShader->DefaultFog();
} // end shadow state
} // end shadow || regen display list
if ( pShaderAPI && pContextData->m_bMaterialVarsChanged )
{
// need to regenerate the semistatic cmds
pContextData->m_SemiStaticCmdsOut.Reset();
pContextData->m_bMaterialVarsChanged = false;
bool bHasBlendMaskTransform= (
(info.m_nBlendMaskTransform != -1) &&
(info.m_nMaskedBlending != -1) &&
(params[info.m_nMaskedBlending]->GetIntValue() ) &&
( ! (params[info.m_nBumpTransform]->MatrixIsIdentity() ) ) );
// If we don't have a texture transform, we don't have
// to set vertex shader constants or run vertex shader instructions
// for the texture transform.
bool bHasTextureTransform =
!( params[info.m_nBaseTextureTransform]->MatrixIsIdentity() &&
params[info.m_nBumpTransform]->MatrixIsIdentity() &&
params[info.m_nBumpTransform2]->MatrixIsIdentity() &&
params[info.m_nEnvmapMaskTransform]->MatrixIsIdentity() );
bHasTextureTransform |= bHasBlendMaskTransform;
pContextData->m_bVertexShaderFastPath = !bHasTextureTransform;
if( params[info.m_nDetail]->IsTexture() )
{
pContextData->m_bVertexShaderFastPath = false;
}
if (bHasBlendMaskTransform)
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform(
VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, info.m_nBlendMaskTransform );
}
if ( ! pContextData->m_bVertexShaderFastPath )
{
bool bSeamlessMapping = ( ( info.m_nSeamlessMappingScale != -1 ) &&
( params[info.m_nSeamlessMappingScale]->GetFloatValue() != 0.0 ) );
bool hasEnvmapMask = params[info.m_nEnvmapMask]->IsTexture();
if (!bSeamlessMapping )
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
// If we have a detail texture, then the bump texcoords are the same as the base texcoords.
if( hasBump && !hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
}
if( hasEnvmapMask )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nEnvmapMaskTransform );
}
else if ( hasBump2 )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, info.m_nBumpTransform2 );
}
}
pContextData->m_SemiStaticCmdsOut.SetEnvMapTintPixelShaderDynamicState( 0, info.m_nEnvmapTint );
// set up shader modulation color
float color[4] = { 1.0, 1.0, 1.0, 1.0 };
pShader->ComputeModulationColor( color );
float flLScale = pShaderAPI->GetLightMapScaleFactor();
color[0] *= flLScale;
color[1] *= flLScale;
color[2] *= flLScale;
pContextData->m_SemiStaticCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_MODULATION_COLOR, color );
color[3] *= ( IS_PARAM_DEFINED( info.m_nAlpha2 ) && params[ info.m_nAlpha2 ]->GetFloatValue() > 0.0f ) ? params[ info.m_nAlpha2 ]->GetFloatValue() : 1.0f;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 12, color );
if ( hasDetailTexture )
{
float detailTintAndBlend[4] = {1, 1, 1, 1};
if ( info.m_nDetailTint != -1 )
{
params[info.m_nDetailTint]->GetVecValue( detailTintAndBlend, 3 );
}
detailTintAndBlend[3] = fDetailBlendFactor;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 8, detailTintAndBlend );
}
float envmapTintVal[4];
float selfIllumTintVal[4];
params[info.m_nEnvmapTint]->GetVecValue( envmapTintVal, 3 );
params[info.m_nSelfIllumTint]->GetVecValue( selfIllumTintVal, 3 );
float envmapContrast = params[info.m_nEnvmapContrast]->GetFloatValue();
float envmapSaturation = params[info.m_nEnvmapSaturation]->GetFloatValue();
float fresnelReflection = params[info.m_nFresnelReflection]->GetFloatValue();
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
pContextData->m_bPixelShaderFastPath = true;
bool bUsingContrast = hasEnvmap && ( (envmapContrast != 0.0f) && (envmapContrast != 1.0f) ) && (envmapSaturation != 1.0f);
bool bUsingFresnel = hasEnvmap && (fresnelReflection != 1.0f);
bool bUsingSelfIllumTint = IS_FLAG_SET(MATERIAL_VAR_SELFILLUM) && (selfIllumTintVal[0] != 1.0f || selfIllumTintVal[1] != 1.0f || selfIllumTintVal[2] != 1.0f);
if ( bUsingContrast || bUsingFresnel || bUsingSelfIllumTint || !g_pConfig->bShowSpecular )
{
pContextData->m_bPixelShaderFastPath = false;
}
if( !pContextData->m_bPixelShaderFastPath )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstants( 2, 3 );
pContextData->m_SemiStaticCmdsOut.OutputConstantData( params[info.m_nEnvmapContrast]->GetVecValue() );
pContextData->m_SemiStaticCmdsOut.OutputConstantData( params[info.m_nEnvmapSaturation]->GetVecValue() );
float flFresnel = params[info.m_nFresnelReflection]->GetFloatValue();
// [ 0, 0, 1-R(0), R(0) ]
pContextData->m_SemiStaticCmdsOut.OutputConstantData4( 0., 0., 1.0 - flFresnel, flFresnel );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 7, params[info.m_nSelfIllumTint]->GetVecValue() );
}
else
{
if ( bHasOutline )
{
float flOutlineParms[8] = { GetFloatParam( info.m_nOutlineStart0, params ),
GetFloatParam( info.m_nOutlineStart1, params ),
GetFloatParam( info.m_nOutlineEnd0, params ),
GetFloatParam( info.m_nOutlineEnd1, params ),
0,0,0,
GetFloatParam( info.m_nOutlineAlpha, params ) };
if ( info.m_nOutlineColor != -1 )
{
params[info.m_nOutlineColor]->GetVecValue( flOutlineParms + 4, 3 );
}
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 2, flOutlineParms, 2 );
}
if ( bHasSoftEdges )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant4(
4, GetFloatParam( info.m_nEdgeSoftnessStart, params ),
GetFloatParam( info.m_nEdgeSoftnessEnd, params ),
0,0 );
}
}
// texture binds
if( hasBaseTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
// handle mat_fullbright 2
bool bLightingOnly = mat_fullbright.GetInt() == 2 && !IS_FLAG_SET( MATERIAL_VAR_NO_DEBUG_OVERRIDE );
if( bLightingOnly )
{
// BASE TEXTURE
if( hasSelfIllum )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY_ALPHA_ZERO );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
}
// BASE TEXTURE 2
if( hasBaseTexture2 )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER7, TEXTURE_GREY );
}
// DETAIL TEXTURE
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER12, TEXTURE_GREY );
}
// disable color modulation
float color[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pContextData->m_SemiStaticCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_MODULATION_COLOR, color );
// turn off environment mapping
envmapTintVal[0] = 0.0f;
envmapTintVal[1] = 0.0f;
envmapTintVal[2] = 0.0f;
}
// always set the transform for detail textures since I'm assuming that you'll
// always have a detailscale.
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBaseTextureTransform, info.m_nDetailScale );
}
if( hasBaseTexture2 )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER7, info.m_nBaseTexture2, info.m_nBaseTexture2Frame );
}
if( hasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nDetail, info.m_nDetailFrame );
}
if( hasBump || hasNormalMapAlphaEnvmapMask )
{
if( !g_pConfig->m_bFastNoBump )
{
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pContextData->m_SemiStaticCmdsOut.BindMultiTexture( pShader, SHADER_SAMPLER4, SHADER_SAMPLER9, info.m_nBumpmap, info.m_nBumpFrame );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER4, info.m_nBumpmap, info.m_nBumpFrame );
}
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER4, TEXTURE_NORMALMAP_FLAT );
}
}
if( hasBump2 )
{
if( !g_pConfig->m_bFastNoBump )
{
if ( nNormalDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
pContextData->m_SemiStaticCmdsOut.BindMultiTexture( pShader, SHADER_SAMPLER5, SHADER_SAMPLER10, info.m_nBumpmap2, info.m_nBumpFrame2 );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER5, info.m_nBumpmap2, info.m_nBumpFrame2 );
}
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALMAP_FLAT );
}
}
if( hasBumpMask )
{
if( !g_pConfig->m_bFastNoBump )
{
if ( nNormalMaskDecodeMode == NORMAL_DECODE_ATI2N_ALPHA )
{
Assert(0);
//pContextData->m_SemiStaticCmdsOut.BindTexture( SHADER_SAMPLER8, SHADER_SAMPLER11, info.m_nBumpMask );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER8, info.m_nBumpMask, -1 );
}
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER8, TEXTURE_NORMALMAP_FLAT );
}
}
if( hasEnvmapMask )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER5, info.m_nEnvmapMask, info.m_nEnvmapMaskFrame );
}
if ( hasLightWarpTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER6, info.m_nLightWarpTexture, -1 );
}
if ( bHasBlendModulateTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER3, info.m_nBlendModulateTexture, -1 );
}
// Parallax cubemaps
if (hasParallaxCorrection)
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant(21, params[info.m_nEnvmapOrigin]->GetVecValue());
float* vecs[3];
vecs[0] = const_cast<float*>(params[info.m_nEnvmapParallaxObb1]->GetVecValue());
vecs[1] = const_cast<float*>(params[info.m_nEnvmapParallaxObb2]->GetVecValue());
vecs[2] = const_cast<float*>(params[info.m_nEnvmapParallaxObb3]->GetVecValue());
float matrix[4][4];
for (int i = 0; i < 3; i++)
{
for (int j = 0; j < 4; j++)
{
matrix[i][j] = vecs[i][j];
}
}
matrix[3][0] = matrix[3][1] = matrix[3][2] = 0;
matrix[3][3] = 1;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant(22, &matrix[0][0], 4);
}
pContextData->m_SemiStaticCmdsOut.End();
}
}
DYNAMIC_STATE
{
CCommandBufferBuilder< CFixedCommandStorageBuffer< 1000 > > DynamicCmdsOut;
DynamicCmdsOut.Call( pContextData->m_pStaticCmds );
DynamicCmdsOut.Call( pContextData->m_SemiStaticCmdsOut.Base() );
bool hasEnvmap = params[info.m_nEnvmap]->IsTexture();
if( hasEnvmap )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER2, info.m_nEnvmap, info.m_nEnvmapFrame );
}
int nFixedLightingMode = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_ENABLE_FIXED_LIGHTING );
bool bVertexShaderFastPath = pContextData->m_bVertexShaderFastPath;
if( nFixedLightingMode != 0 )
{
if ( pContextData->m_bPixelShaderForceFastPathBecauseOutline )
nFixedLightingMode = 0;
else
bVertexShaderFastPath = false;
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
DECLARE_DYNAMIC_VERTEX_SHADER(sdk_lightmappedgeneric_vs20);
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( FASTPATH, bVertexShaderFastPath );
SET_DYNAMIC_VERTEX_SHADER_COMBO(
LIGHTING_PREVIEW,
(nFixedLightingMode)?1:0
);
SET_DYNAMIC_VERTEX_SHADER_CMD(DynamicCmdsOut, sdk_lightmappedgeneric_vs20);
bool bPixelShaderFastPath = pContextData->m_bPixelShaderFastPath;
if( nFixedLightingMode !=0 )
{
bPixelShaderFastPath = false;
}
bool bWriteDepthToAlpha;
bool bWriteWaterFogToAlpha;
if( pContextData->m_bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
else
{
//can't write a special value to dest alpha if we're actually using as-intended alpha
bWriteDepthToAlpha = false;
bWriteWaterFogToAlpha = false;
}
float envmapContrast = params[info.m_nEnvmapContrast]->GetFloatValue();
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20b);
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATH, bPixelShaderFastPath || pContextData->m_bPixelShaderForceFastPathBecauseOutline );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATHENVMAPCONTRAST, bPixelShaderFastPath && envmapContrast == 1.0f );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nFixedLightingMode );
SET_DYNAMIC_PIXEL_SHADER_CMD(DynamicCmdsOut, sdk_lightmappedgeneric_ps20b);
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER(sdk_lightmappedgeneric_ps20);
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATH, bPixelShaderFastPath );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FASTPATHENVMAPCONTRAST, bPixelShaderFastPath && envmapContrast == 1.0f );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( LIGHTING_PREVIEW, nFixedLightingMode );
SET_DYNAMIC_PIXEL_SHADER_CMD(DynamicCmdsOut, sdk_lightmappedgeneric_ps20);
}
if( hasFlashlight && IsX360() )
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
DynamicCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, worldToTexture.Base(), 4 );
SetFlashLightColorFromState( flashlightState, pShaderAPI );
float atten[4], pos[4];
atten[0] = flashlightState.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
DynamicCmdsOut.SetPixelShaderConstant( 13, atten, 1 );
pos[0] = flashlightState.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
DynamicCmdsOut.SetPixelShaderConstant( 14, pos, 1 );
pShader->BindTexture( SHADER_SAMPLER13, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && flashlightState.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER14, pFlashlightDepthTexture, 0 );
DynamicCmdsOut.BindStandardTexture( SHADER_SAMPLER15, TEXTURE_SHADOW_NOISE_2D );
// Tweaks associated with a given flashlight
float tweaks[4];
tweaks[0] = ShadowFilterFromState( flashlightState );
tweaks[1] = ShadowAttenFromState( flashlightState );
pShader->HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
DynamicCmdsOut.SetPixelShaderConstant( 19, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
vScreenScale[0] = (float) nWidth / 32.0f;
vScreenScale[1] = (float) nHeight / 32.0f;
DynamicCmdsOut.SetPixelShaderConstant( 31, vScreenScale, 1 );
}
}
DynamicCmdsOut.End();
pShaderAPI->ExecuteCommandBuffer( DynamicCmdsOut.Base() );
}
pShader->Draw();
if( IsPC() && (IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0) && pContextData->m_bFullyOpaqueWithoutAlphaTest )
{
//Alpha testing makes it so we can't write to dest alpha
//Writing to depth makes it so later polygons can't write to dest alpha either
//This leads to situations with garbage in dest alpha.
//Fix it now by converting depth to dest alpha for any pixels that just wrote.
pShader->DrawEqualDepthToDestAlpha();
}
}
void DrawFogOfWarBlendedPass( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, FogOfWarBlendedPassVars_t &info, VertexCompressionType_t vertexCompression )
{
bool bVertexLitGeneric = false;
bool bHasFlashlight = false;
SHADOW_STATE
{
bool hasBaseAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_BASEALPHAENVMAPMASK );
bool bHasSelfIllum = (!bHasFlashlight || IsX360() ) && IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
// Reset shadow state manually since we're drawing from two materials
pShader->SetInitialShadowState();
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
// Vertex Shader
DECLARE_STATIC_VERTEX_SHADER( fogofwar_blended_pass_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, true );
SET_STATIC_VERTEX_SHADER( fogofwar_blended_pass_vs20 );
// Pixel Shader
DECLARE_STATIC_PIXEL_SHADER( fogofwar_blended_pass_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( BASEALPHAENVMAPMASK, hasBaseAlphaEnvmapMask );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, bHasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( FOW, true );
SET_STATIC_PIXEL_SHADER( fogofwar_blended_pass_ps20b );
pShader->DefaultFog();
// Textures
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
//pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
// Blending
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GREATER, 0.0f );
}
DYNAMIC_STATE
{
// Decide if this pass should be drawn
static ConVarRef sv_fogofwar("sv_fogofwar");
//static ConVarRef sv_fogofwar_tilesize("sv_fogofwar_tilesize");
if( !sv_fogofwar.GetBool() )
{
pShader->Draw( false );
return;
}
// Reset render state manually since we're drawing from two materials
pShaderAPI->SetDefaultState();
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( fogofwar_blended_pass_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER( fogofwar_blended_pass_vs20 );
// Set Vertex Shader Constants
//pShader->SetAmbientCubeDynamicStateVertexShader();
// Set Pixel Shader Combos
DECLARE_DYNAMIC_PIXEL_SHADER( fogofwar_blended_pass_ps20b );
SET_DYNAMIC_PIXEL_SHADER( fogofwar_blended_pass_ps20b );
// Bind textures
pShader->BindTexture( SHADER_SAMPLER0, info.m_nBaseTexture );
pShader->BindTexture( SHADER_SAMPLER1, info.m_nFogOfWarTexture );
// Set Pixel Shader Constants
//pShader->SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
float eyePos[4];
pShaderAPI->GetWorldSpaceCameraPosition( eyePos );
pShaderAPI->SetPixelShaderConstant( 0, eyePos, 1 );
bool bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bool bWriteWaterFogToAlpha = false;
bool bHasVertexAlpha = bVertexLitGeneric ? false : IS_FLAG_SET( MATERIAL_VAR_VERTEXALPHA );
float fPixelFogType = pShaderAPI->GetPixelFogCombo() == 1 ? 1 : 0;
float fWriteDepthToAlpha = bWriteDepthToAlpha && IsPC() ? 1 : 0;
float fWriteWaterFogToDestAlpha = bWriteWaterFogToAlpha ? 1 : 0;
float fVertexAlpha = bHasVertexAlpha ? 1 : 0;
// Controls for lerp-style paths through shader code (bump and non-bump have use different register)
float vShaderControls[4] = { fPixelFogType, fWriteDepthToAlpha, fWriteWaterFogToDestAlpha, fVertexAlpha };
pShaderAPI->SetPixelShaderConstant( 1, vShaderControls, 1 );
pShaderAPI->SetPixelShaderFogParams(2);
float vFoWSize[ 4 ];
Vector vMins = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MINS );
Vector vMaxs = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MAXS );
vFoWSize[ 0 ] = vMins.x;
vFoWSize[ 1 ] = vMins.y;
vFoWSize[ 2 ] = vMaxs.x - vMins.x;
vFoWSize[ 3 ] = vMaxs.y - vMins.y;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, vFoWSize );
/*
// Fog of war color
static float c[4];
c[0] = mat_fogofwar_r.GetFloat();
c[1] = mat_fogofwar_g.GetFloat();
c[2] = mat_fogofwar_b.GetFloat();
c[3] = mat_fogofwar_a.GetFloat();
pShaderAPI->SetPixelShaderConstant( 3, (const float *)(&c), 1 );
*/
// Tilesize
//static float ts[4];
//ts[0] = sv_fogofwar_tilesize.GetInt();
//pShaderAPI->SetPixelShaderConstant( 4, (const float *)(&ts), 1 );
}
pShader->Draw();
}
void DrawCloakBlendedPass( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, CloakBlendedPassVars_t &info, VertexCompressionType_t vertexCompression )
{
bool bBumpMapping = ( !g_pConfig->UseBumpmapping() ) || ( info.m_nBumpmap == -1 ) || !params[info.m_nBumpmap]->IsTexture() ? 0 : 1;
SHADOW_STATE
{
// Reset shadow state manually since we're drawing from two materials
pShader->SetInitialShadowState( );
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
// Vertex Shader
DECLARE_STATIC_VERTEX_SHADER( cloak_blended_pass_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, bBumpMapping ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( cloak_blended_pass_vs20 );
// Pixel Shader
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( cloak_blended_pass_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bBumpMapping ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( cloak_blended_pass_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( cloak_blended_pass_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bBumpMapping ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( cloak_blended_pass_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
// Vertex Shader
DECLARE_STATIC_VERTEX_SHADER( cloak_blended_pass_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, bBumpMapping ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( cloak_blended_pass_vs30 );
// Pixel Shader
DECLARE_STATIC_PIXEL_SHADER( cloak_blended_pass_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, bBumpMapping ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( cloak_blended_pass_ps30 );
}
#endif
// Textures
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Refraction texture
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
if ( bBumpMapping )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Bump
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false ); // Not sRGB
}
pShaderShadow->EnableSRGBWrite( true );
// Blending
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaWrites( false );
// !!! We need to turn this back on because EnableAlphaBlending() above disables it!
pShaderShadow->EnableDepthWrites( true );
}
DYNAMIC_STATE
{
// Reset render state manually since we're drawing from two materials
pShaderAPI->SetDefaultState();
// Set Vertex Shader Constants
if ( ( bBumpMapping ) && ( info.m_nBumpTransform != -1 ) )
{
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBumpTransform );
}
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( cloak_blended_pass_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( cloak_blended_pass_vs20 );
// Set Pixel Shader Combos
if( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps20b );
SET_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps20 );
SET_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps20 );
}
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( cloak_blended_pass_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( cloak_blended_pass_vs30 );
// Set Pixel Shader Combos
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps30 );
SET_DYNAMIC_PIXEL_SHADER( cloak_blended_pass_ps30 );
}
#endif
// Bind textures
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 ); // Refraction Map
if ( bBumpMapping )
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nBumpmap, info.m_nBumpFrame );
}
// Set Pixel Shader Constants
float vEyePos[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos );
pShaderAPI->SetPixelShaderConstant( 5, vEyePos, 1 );
float vPackedConst1[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPackedConst1[0] = IS_PARAM_DEFINED( info.m_nCloakFactor ) ? params[info.m_nCloakFactor]->GetFloatValue() : kDefaultCloakFactor;
vPackedConst1[1] = IS_PARAM_DEFINED( info.m_nRefractAmount ) ? params[info.m_nRefractAmount]->GetFloatValue() : kDefaultRefractAmount;
pShaderAPI->SetPixelShaderConstant( 6, vPackedConst1, 1 );
// Refract color tint
pShaderAPI->SetPixelShaderConstant( 7, IS_PARAM_DEFINED( info.m_nCloakColorTint ) ? params[info.m_nCloakColorTint]->GetVecValue() : kDefaultCloakColorTint, 1 );
// Set c0 and c1 to contain first two rows of ViewProj matrix
VMatrix mView, mProj;
pShaderAPI->GetMatrix( MATERIAL_VIEW, mView.m[0] );
pShaderAPI->GetMatrix( MATERIAL_PROJECTION, mProj.m[0] );
VMatrix mViewProj = mView * mProj;
mViewProj = mViewProj.Transpose3x3();
pShaderAPI->SetPixelShaderConstant( 0, mViewProj.m[0], 2 );
}
pShader->Draw();
}
void DrawPhong_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI, IShaderShadow* pShaderShadow,
VertexLitGeneric_DX9_Vars_t &info, VertexCompressionType_t vertexCompression, CBasePerMaterialContextData **pContextDataPtr, bool bDeferredActive )
{
CPhong_DX9_Context *pContextData = reinterpret_cast< CPhong_DX9_Context *> ( *pContextDataPtr );
bool bHasFlashlight = !bDeferredActive && pShader->UsingFlashlight( params );
bool bHasFlashlightOnly = bHasFlashlight && !IsX360();
#ifndef _X360
bool bIsDecal = IS_FLAG_SET( MATERIAL_VAR_DECAL );
#endif
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
BlendType_t nBlendType = pShader->EvaluateBlendRequirements( info.m_nBaseTexture, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !bIsAlphaTested && !bHasFlashlightOnly; //dest alpha is free for special use
bool bHasDisplacement = (info.m_nDisplacementMap != -1) && params[info.m_nDisplacementMap]->IsTexture();
#if !defined( PLATFORM_X360 )
bool bHasDisplacementWrinkles = (info.m_nDisplacementWrinkleMap != -1) && params[info.m_nDisplacementWrinkleMap]->GetIntValue();
#endif
bool bHasTeamColorTexture = ( info.m_nTeamColorTexture != -1 ) && params[info.m_nTeamColorTexture]->IsTexture();
bool bHasFoW = ( ( info.m_nFoW != -1 ) && ( params[ info.m_nFoW ]->IsTexture() != 0 ) );
bool bFOWValidTexture = true;
if ( bHasFoW == true )
{
ITexture *pTexture = params[ info.m_nFoW ]->GetTextureValue();
if ( ( pTexture->GetFlags() & TEXTUREFLAGS_RENDERTARGET ) == 0 )
{
bHasFoW = true;
bFOWValidTexture = false;
}
}
else
{
bHasFoW = true;
bFOWValidTexture = false;
}
if( pShader->IsSnapshotting() )
{
PhongShaderInfo_t phongInfo;
ComputePhongShaderInfo( pShader, params, info, bHasFlashlightOnly, &phongInfo );
bool bShaderSrgbRead = ( IsX360() && IS_PARAM_DEFINED( info.m_nShaderSrgbRead360 ) && params[info.m_nShaderSrgbRead360]->GetIntValue() );
int nDetailBlendMode = ( info.m_nDetailTextureCombineMode == -1 ) ? 0 : params[info.m_nDetailTextureCombineMode]->GetIntValue();
bool bHasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR );
bool bHasVertexAlpha = IS_FLAG_SET( MATERIAL_VAR_VERTEXALPHA );
// look at color and alphamod stuff.
// Unlit generic never uses the flashlight
bool bHasEnvmap = !bHasFlashlightOnly && params[info.m_nEnvmap]->IsTexture();
// Alpha test: FIXME: shouldn't this be handled in CBaseVSShader::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( info.m_nAlphaTestReference != -1 && params[info.m_nAlphaTestReference]->GetFloatValue() > 0.0f )
{
pShaderShadow->AlphaFunc( SHADER_ALPHAFUNC_GEQUAL, params[info.m_nAlphaTestReference]->GetFloatValue() );
}
// Based upon vendor and device dependent formats
int nShadowFilterMode = bHasFlashlight ? g_pHardwareConfig->GetShadowFilterMode() : 0;
if( bHasFlashlightOnly )
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetAdditiveBlendingShadowState( info.m_nBaseTexture, true );
}
if( bIsAlphaTested )
{
// disable alpha test and use the zfunc zequals since alpha isn't guaranteed to
// be the same on both the regular pass and the flashlight pass.
pShaderShadow->EnableAlphaTest( false );
pShaderShadow->DepthFunc( SHADER_DEPTHFUNC_EQUAL );
}
pShaderShadow->EnableBlending( true );
pShaderShadow->EnableDepthWrites( false );
// Be sure not to write to dest alpha
pShaderShadow->EnableAlphaWrites( false );
}
if ( !bHasFlashlightOnly ) // not flashlight pass
{
if (params[info.m_nBaseTexture]->IsTexture())
{
pShader->SetDefaultBlendingShadowState( info.m_nBaseTexture, true );
}
if ( bHasEnvmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true ); // Cubic environment map
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, true );
}
}
}
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int userDataSize = 0;
// Always enable...will bind white if nothing specified...
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Base (albedo) map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, !bShaderSrgbRead );
if ( !bHasFoW && !bDeferredActive && (phongInfo.m_bHasBaseTextureWrinkle) )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true ); // Base (albedo) compression map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER9, !bShaderSrgbRead );
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true ); // Base (albedo) stretch map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER10, !bShaderSrgbRead );
}
if( phongInfo.m_bHasDiffuseWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Diffuse warp texture
}
if( phongInfo.m_bHasPhongWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Specular warp texture
}
// Specular exponent map or dummy
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Specular exponent map
if( bHasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER4 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Noise map
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Flashlight cookie
}
// Always enable, since flat normal will be bound
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Normal map
userDataSize = 4; // tangent S
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Normalizing cube map
if ( !bHasFoW && !bDeferredActive && (phongInfo.m_bHasBumpWrinkle || phongInfo.m_bHasBaseTextureWrinkle) )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true ); // Normal compression map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER11, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true ); // Normal stretch map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER12, false );
}
if( bHasFoW )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true );
}
if( bDeferredActive )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true );
}
if ( phongInfo.m_bHasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER13, true );
if ( nDetailBlendMode != 0 ) //Not Mod2X
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER13, true );
}
}
if ( phongInfo.m_bHasSelfIllum )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER14, true );
}
if( bHasVertexColor || bHasVertexAlpha )
{
flags |= VERTEX_COLOR;
}
// Always enable ambient occlusion sampler on PC on DX10 parts
if ( IsPC() && g_pHardwareConfig->HasFastVertexTextures() )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER15, true );
}
if( bHasTeamColorTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true );
}
if ( bHasDisplacement && IsPC() && g_pHardwareConfig->HasFastVertexTextures() )
{
pShaderShadow->EnableVertexTexture( SHADER_VERTEXTEXTURE_SAMPLER2, true );
}
pShaderShadow->EnableSRGBWrite( true );
// texcoord0 : base texcoord, texcoord2 : decal hw morph delta
int pTexCoordDim[3] = { 2, 0, 3 };
int nTexCoordCount = 1;
#ifndef _X360
// Special morphed decal information
if ( bIsDecal && g_pHardwareConfig->HasFastVertexTextures() )
{
nTexCoordCount = 3;
}
#endif
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, pTexCoordDim, userDataSize );
#if !defined( PLATFORM_X360 )
bool bWorldNormal = ( ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH == ( IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 )));
#endif
// This is to allow phong materials to disable half lambert. Half lambert has always been forced on in phong,
// so the only safe way to allow artists to disable half lambert is to create this param that disables the
// default behavior of forcing half lambert on.
bool bPhongHalfLambert = IS_PARAM_DEFINED( info.m_nPhongDisableHalfLambert ) ? ( params[ info.m_nPhongDisableHalfLambert ]->GetIntValue() == 0 ) : true;
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
SET_FLAGS2( MATERIAL_VAR2_SUPPORTS_TESSELLATION );
}
DECLARE_STATIC_VERTEX_SHADER( phong_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( WORLD_NORMAL, bWorldNormal );
SET_STATIC_VERTEX_SHADER_COMBO( DECAL, bIsDecal );
SET_STATIC_VERTEX_SHADER_COMBO( FOW, bHasFoW );
SET_STATIC_VERTEX_SHADER( phong_vs30 );
if( bDeferredActive )
{
DECLARE_STATIC_PIXEL_SHADER( phong_deferred_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, phongInfo.m_bHasSelfIllum && !bHasFlashlightOnly );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUMFRESNEL, phongInfo.m_bHasSelfIllumFresnel && !bHasFlashlightOnly );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, phongInfo.m_bHasDiffuseWarp && phongInfo.m_bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGWARPTEXTURE, phongInfo.m_bHasPhongWarp && phongInfo.m_bHasPhong );
//SET_STATIC_PIXEL_SHADER_COMBO( WRINKLEMAP, !bHasFoW && phongInfo.m_bHasBaseTextureWrinkle );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, phongInfo.m_bHasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHT, phongInfo.m_bHasRimLight );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER_COMBO( WORLD_NORMAL, bWorldNormal );
SET_STATIC_PIXEL_SHADER_COMBO( PHONG_HALFLAMBERT, bPhongHalfLambert );
SET_STATIC_PIXEL_SHADER_COMBO( TEAMCOLORTEXTURE, bHasTeamColorTexture );
//SET_STATIC_PIXEL_SHADER_COMBO( FOW, /*bHasFoW*/ 1 );
SET_STATIC_PIXEL_SHADER( phong_deferred_ps30 );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( phong_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, phongInfo.m_bHasSelfIllum && !bHasFlashlightOnly );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUMFRESNEL, phongInfo.m_bHasSelfIllumFresnel && !bHasFlashlightOnly );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, phongInfo.m_bHasDiffuseWarp && phongInfo.m_bHasPhong );
SET_STATIC_PIXEL_SHADER_COMBO( PHONGWARPTEXTURE, phongInfo.m_bHasPhongWarp && phongInfo.m_bHasPhong );
//SET_STATIC_PIXEL_SHADER_COMBO( WRINKLEMAP, !bHasFoW && phongInfo.m_bHasBaseTextureWrinkle );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, phongInfo.m_bHasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_BLEND_MODE, nDetailBlendMode );
SET_STATIC_PIXEL_SHADER_COMBO( RIMLIGHT, phongInfo.m_bHasRimLight );
SET_STATIC_PIXEL_SHADER_COMBO( CUBEMAP, bHasEnvmap );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER_COMBO( WORLD_NORMAL, bWorldNormal );
SET_STATIC_PIXEL_SHADER_COMBO( PHONG_HALFLAMBERT, bPhongHalfLambert );
SET_STATIC_PIXEL_SHADER_COMBO( TEAMCOLORTEXTURE, bHasTeamColorTexture );
//SET_STATIC_PIXEL_SHADER_COMBO( FOW, /*bHasFoW*/ 1 );
SET_STATIC_PIXEL_SHADER( phong_ps30 );
}
if( bHasFlashlightOnly )
{
pShader->FogToBlack();
}
else
{
pShader->DefaultFog();
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for underwater stuff
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
pShader->PI_BeginCommandBuffer();
pShader->PI_SetPixelShaderAmbientLightCube( PSREG_AMBIENT_CUBE );
pShader->PI_SetPixelShaderLocalLighting( PSREG_LIGHT_INFO_ARRAY );
pShader->PI_SetVertexShaderAmbientLightCube();
// material can opt out of per-instance modulation via $nodiffusemodulation
bool bAllowDiffuseModulation = ( info.m_nAllowDiffuseModulation == -1 ) ? true : ( params[info.m_nAllowDiffuseModulation]->GetIntValue() != 0 );
if ( bAllowDiffuseModulation )
{
pShader->PI_SetModulationPixelShaderDynamicState_LinearColorSpace( 1 );
}
else
{
pShader->PI_SetModulationPixelShaderDynamicState_Identity( 1 );
}
pShader->PI_EndCommandBuffer();
}
else // not snapshotting -- begin dynamic state
{
// Deal with semisatic
if ( ( !pContextData ) || ( pContextData->m_bMaterialVarsChanged ) )
{
if ( !pContextData ) // make sure allocated
{
pContextData = new CPhong_DX9_Context;
*pContextDataPtr = pContextData;
}
pContextData->m_SemiStaticCmdsOut.Reset();
pContextData->m_bMaterialVarsChanged = false;
PhongShaderInfo_t phongInfo;
ComputePhongShaderInfo( pShader, params, info, bHasFlashlightOnly, &phongInfo );
bool bHasBump = (info.m_nBumpmap != -1) && params[info.m_nBumpmap]->IsTexture();
bool bLightingOnly = mat_fullbright.GetInt() == 2 && !IS_FLAG_SET( MATERIAL_VAR_NO_DEBUG_OVERRIDE );
bool bHasSelfIllumMask = ( phongInfo.m_bHasSelfIllum ) && (info.m_nSelfIllumMask != -1) && params[info.m_nSelfIllumMask]->IsTexture();
float fBlendFactor = ( info.m_nDetailTextureBlendFactor == -1 )? 1 : params[info.m_nDetailTextureBlendFactor]->GetFloatValue();
bool bHasSpecularExponentTexture = (info.m_nPhongExponentTexture != -1) && params[info.m_nPhongExponentTexture]->IsTexture();
bool bHasPhongTintMap = bHasSpecularExponentTexture && (info.m_nPhongAlbedoTint != -1) && ( params[info.m_nPhongAlbedoTint]->GetIntValue() != 0 );
bool bHasNormalMapAlphaEnvmapMask = IS_FLAG_SET( MATERIAL_VAR_NORMALMAPALPHAENVMAPMASK );
bool bHasRimMaskMap = bHasSpecularExponentTexture && phongInfo.m_bHasRimLight && (info.m_nRimMask != -1) && ( params[info.m_nRimMask]->GetIntValue() != 0 );
bool bHasSinglePassFlashlight = IsX360(); // NOTE: If you change this, fix state.m_nDepthTweakConstant below! And, deal with SINGLE_PASS_FLASHLIGHT in phong_ps20b.fxc
if( phongInfo.m_bHasBaseTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER0, info.m_nBaseTexture, info.m_nBaseTextureFrame );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
if ( !bHasFoW && !bDeferredActive && phongInfo.m_bHasBaseTextureWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER9, info.m_nWrinkle, info.m_nBaseTextureFrame );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER10, info.m_nStretch, info.m_nBaseTextureFrame );
}
if( phongInfo.m_bHasDiffuseWarp && phongInfo.m_bHasPhong )
{
if ( r_lightwarpidentity.GetBool() )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER2, TEXTURE_IDENTITY_LIGHTWARP );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER2, info.m_nDiffuseWarpTexture );
}
}
if( phongInfo.m_bHasPhongWarp )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER1, info.m_nPhongWarpTexture );
}
if( bHasSpecularExponentTexture && phongInfo.m_bHasPhong )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER7, info.m_nPhongExponentTexture );
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER7, TEXTURE_WHITE );
}
if( !g_pConfig->m_bFastNoBump )
{
if( bHasBump )
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER3, info.m_nBumpmap, info.m_nBumpFrame );
else
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
if ( !bHasFoW && !bDeferredActive && phongInfo.m_bHasBumpWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER11, info.m_nNormalWrinkle, info.m_nBumpFrame );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nNormalStretch, info.m_nBumpFrame );
}
else if ( !bHasFoW && !bDeferredActive && phongInfo.m_bHasBaseTextureWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER11, info.m_nBumpmap, info.m_nBumpFrame );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nBumpmap, info.m_nBumpFrame );
}
}
else // Just flat bump maps
{
if ( bHasBump )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER3, TEXTURE_NORMALMAP_FLAT );
}
if ( !bHasFoW && !bDeferredActive && phongInfo.m_bHasBaseTextureWrinkle || phongInfo.m_bHasBumpWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER11, TEXTURE_NORMALMAP_FLAT );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, TEXTURE_NORMALMAP_FLAT );
}
}
if ( phongInfo.m_bHasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER13, info.m_nDetail, info.m_nDetailFrame );
}
if ( phongInfo.m_bHasSelfIllum )
{
if ( bHasSelfIllumMask ) // Separate texture for self illum?
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER14, info.m_nSelfIllumMask ); // Bind it
}
else // else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER14, TEXTURE_BLACK ); // Bind dummy
}
}
if( !bHasFlashlightOnly )
{
if ( phongInfo.m_bHasEnvmap )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER8, info.m_nEnvmap, info.m_nEnvmapFrame );
}
}
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nBaseTextureTransform );
if( bHasBump )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBumpTransform );
}
if ( phongInfo.m_bHasDetailTexture )
{
if ( IS_PARAM_DEFINED( info.m_nDetailTextureTransform ) )
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4,
info.m_nDetailTextureTransform,
info.m_nDetailScale );
}
else
{
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4,
info.m_nBaseTextureTransform,
info.m_nDetailScale );
}
}
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant_W( PSREG_SELFILLUMTINT, info.m_nSelfIllumTint, fBlendFactor );
bool bInvertPhongMask = ( info.m_nInvertPhongMask != -1 ) && ( params[info.m_nInvertPhongMask]->GetIntValue() != 0 );
float fInvertPhongMask = bInvertPhongMask ? 1 : 0;
bool bHasBaseAlphaPhongMask = (info.m_nBaseMapAlphaPhongMask != -1) && ( params[info.m_nBaseMapAlphaPhongMask]->GetIntValue() != 0 );
float fHasBaseAlphaPhongMask = bHasBaseAlphaPhongMask ? 1 : 0;
bool bBlendTintByBaseAlpha = (info.m_nBlendTintByBaseAlpha != -1) && ( params[info.m_nBlendTintByBaseAlpha]->GetIntValue() != 0 );
float fBlendTintByBaseAlpha = bBlendTintByBaseAlpha ? 1 : 0;
// Controls for lerp-style paths through shader code
float vShaderControls[4] = { fHasBaseAlphaPhongMask, 0.0f, 1.0f-fBlendTintByBaseAlpha, fInvertPhongMask };
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_SHADER_CONTROLS, vShaderControls, 1 );
if ( phongInfo.m_bHasSelfIllumFresnel && !bHasFlashlightOnly )
{
float vConstScaleBiasExp[4] = { 1.0f, 0.0f, 1.0f, 0.0f };
float flMin = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[0] : 0.0f;
float flMax = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[1] : 1.0f;
float flExp = IS_PARAM_DEFINED( info.m_nSelfIllumFresnelMinMaxExp ) ? params[info.m_nSelfIllumFresnelMinMaxExp]->GetVecValue()[2] : 1.0f;
vConstScaleBiasExp[1] = ( flMax != 0.0f ) ? ( flMin / flMax ) : 0.0f; // Bias
vConstScaleBiasExp[0] = 1.0f - vConstScaleBiasExp[1]; // Scale
vConstScaleBiasExp[2] = flExp; // Exp
vConstScaleBiasExp[3] = flMax; // Brightness
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_SELFILLUM_SCALE_BIAS_EXP, vConstScaleBiasExp, 1 );
}
if( !bHasFlashlightOnly )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
if( phongInfo.m_bHasEnvmap )
{
float vEnvMapTint_MaskControl[4] = {1.0f, 1.0f, 1.0f, 0.0f};
// If we have a tint, grab it
if ( (info.m_nEnvmapTint != -1) && params[info.m_nEnvmapTint]->IsDefined() )
params[info.m_nEnvmapTint]->GetVecValue(vEnvMapTint_MaskControl, 3);
// Set control for source of env map mask (normal alpha or base alpha)
vEnvMapTint_MaskControl[3] = bHasNormalMapAlphaEnvmapMask ? 1.0f : 0.0f;
// Handle mat_fullbright 2 (diffuse lighting only with 50% gamma space basetexture)
if( bLightingOnly )
{
vEnvMapTint_MaskControl[0] = vEnvMapTint_MaskControl[1] = vEnvMapTint_MaskControl[2] = 0.0f;
}
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, vEnvMapTint_MaskControl, 1 );
}
}
// Pack Phong exponent in with the eye position
float vSpecularTint[4] = {1, 1, 1, 4};
float vFresnelRanges_SpecBoost[4] = {0, 0.5, 1, 1}, vRimBoost[4] = {1, 1, 1, 1};
// Get the tint parameter
if ( (info.m_nPhongTint != -1) && params[info.m_nPhongTint]->IsDefined() )
{
params[info.m_nPhongTint]->GetVecValue(vSpecularTint, 3);
}
// Get the rim light power (goes in w of Phong tint)
if ( phongInfo.m_bHasRimLight && (info.m_nRimLightPower != -1) && params[info.m_nRimLightPower]->IsDefined() )
{
vSpecularTint[3] = params[info.m_nRimLightPower]->GetFloatValue();
vSpecularTint[3] = MAX(vSpecularTint[3], 1.0f); // Make sure this is at least 1
}
// Get the rim boost (goes in w of flashlight position)
if ( phongInfo.m_bHasRimLight && (info.m_nRimLightBoost != -1) && params[info.m_nRimLightBoost]->IsDefined() )
{
vRimBoost[3] = params[info.m_nRimLightBoost]->GetFloatValue();
}
// Single pass flashlight has to use a separate constant for this stuff since a flashlight constant is repurposed for rimlighting when doing multi-pass flashlight.
if ( phongInfo.m_bHasRimLight )
{
if ( bHasSinglePassFlashlight )
{
float vRimParams[4] = {0, 0, 0, 0};
vRimParams[0] = bHasRimMaskMap ? params[info.m_nRimMask]->GetFloatValue() : 0.0f;
vRimParams[1] = params[info.m_nRimLightBoost]->GetFloatValue();
// Rim mask...if this is true, use alpha channel of spec exponent texture to mask the rim term
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_RIMPARAMS, vRimParams, 1 );
}
else if ( !bHasFlashlight )
{
float vRimMaskControl[4] = {0, 0, 0, 0}; // Only x is relevant in shader code
vRimMaskControl[0] = bHasRimMaskMap ? params[info.m_nRimMask]->GetFloatValue() : 0.0f;
// Rim mask...if this is true, use alpha channel of spec exponent texture to mask the rim term
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, vRimMaskControl, 1 );
}
}
// If it's all zeros, there was no constant tint in the vmt
if ( (vSpecularTint[0] == 0.0f) && (vSpecularTint[1] == 0.0f) && (vSpecularTint[2] == 0.0f) )
{
if ( bHasPhongTintMap ) // If we have a map to use, tell the shader
{
vSpecularTint[0] = -1;
}
else // Otherwise, just tint with white
{
vSpecularTint[0] = 1.0f;
vSpecularTint[1] = 1.0f;
vSpecularTint[2] = 1.0f;
}
}
// handle mat_fullbright 2 (diffuse lighting only)
if( bLightingOnly )
{
// BASETEXTURE
if( phongInfo.m_bHasSelfIllum && !bHasFlashlightOnly )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY_ALPHA_ZERO );
if ( phongInfo.m_bHasBaseTextureWrinkle || phongInfo.m_bHasBumpWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER9, TEXTURE_GREY_ALPHA_ZERO ); // Compressed wrinklemap
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER10, TEXTURE_GREY_ALPHA_ZERO ); // Stretched wrinklemap
}
}
else
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER0, TEXTURE_GREY );
if ( phongInfo.m_bHasBaseTextureWrinkle || phongInfo.m_bHasBumpWrinkle )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER9, TEXTURE_GREY ); // Compressed wrinklemap
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER10, TEXTURE_GREY ); // Stretched wrinklemap
}
}
// DETAILTEXTURE
if ( phongInfo.m_bHasDetailTexture )
{
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER13, TEXTURE_GREY );
}
// turn off specularity
vSpecularTint[0] = vSpecularTint[1] = vSpecularTint[2] = 0.0f;
}
if ( (info.m_nPhongFresnelRanges != -1) && params[info.m_nPhongFresnelRanges]->IsDefined() )
{
params[info.m_nPhongFresnelRanges]->GetVecValue( vFresnelRanges_SpecBoost, 3 ); // Grab optional Fresnel range parameters
}
if ( (info.m_nPhongBoost != -1 ) && params[info.m_nPhongBoost]->IsDefined()) // Grab optional Phong boost param
{
vFresnelRanges_SpecBoost[3] = params[info.m_nPhongBoost]->GetFloatValue();
}
else
{
vFresnelRanges_SpecBoost[3] = 1.0f;
}
bool bHasBaseLuminancePhongMask = (info.m_nBaseMapLuminancePhongMask != -1) && ( params[info.m_nBaseMapLuminancePhongMask]->GetIntValue() != 0 );
float fHasBaseLuminancePhongMask = bHasBaseLuminancePhongMask ? 1 : 0;
float vShaderControls2[4] = {0.0f, fHasBaseLuminancePhongMask, 0.0f, 0.0f};
if ( !bHasFlashlightOnly )
{
if ( phongInfo.m_bHasEnvmap )
{
if ( (info.m_nEnvmapFresnel != -1) && params[info.m_nEnvmapFresnel]->IsDefined() )
{
vShaderControls2[0] = params[info.m_nEnvmapFresnel]->GetFloatValue();
}
}
}
if ( (info.m_nPhongExponent != -1) && params[info.m_nPhongExponent]->IsDefined() )
{
vShaderControls2[2] = params[info.m_nPhongExponent]->GetFloatValue(); // This overrides the channel in the map
}
else
{
vShaderControls2[2] = 0; // Use the alpha channel of the normal map for the exponent
}
vShaderControls2[3] = bHasSelfIllumMask ? 1.0f : 0.0f;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_FRESNEL_SPEC_PARAMS, vFresnelRanges_SpecBoost, 1 );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, vRimBoost, 1 ); // Rim boost in w on non-flashlight pass
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_SPEC_RIM_PARAMS, vSpecularTint, 1 );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_SHADER_CONTROLS_2, vShaderControls2, 1 );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderFogParams( PSREG_FOG_PARAMS );
if ( bHasFlashlight )
{
CBCmdSetPixelShaderFlashlightState_t state;
state.m_LightSampler = SHADER_SAMPLER6;
state.m_DepthSampler = SHADER_SAMPLER4;
state.m_ShadowNoiseSampler = SHADER_SAMPLER5;
state.m_nColorConstant = PSREG_FLASHLIGHT_COLOR;
state.m_nAttenConstant = PSREG_FLASHLIGHT_ATTENUATION;
state.m_nOriginConstant = PSREG_FLASHLIGHT_POSITION_RIM_BOOST;
state.m_nDepthTweakConstant = bHasSinglePassFlashlight ? 43 : PSREG_ENVMAP_TINT__SHADOW_TWEAKS; // NOTE: Reg 43 not available on < ps3.0!
state.m_nScreenScaleConstant = PSREG_FLASHLIGHT_SCREEN_SCALE;
state.m_nWorldToTextureConstant = PSREG_FLASHLIGHT_TO_WORLD_TEXTURE;
state.m_bFlashlightNoLambert = false;
state.m_bSinglePassFlashlight = bHasSinglePassFlashlight;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderFlashlightState( state );
if ( !IsX360() && ( g_pHardwareConfig->GetDXSupportLevel() > 92 ) )
{
pContextData->m_SemiStaticCmdsOut.SetPixelShaderUberLightState(
PSREG_UBERLIGHT_SMOOTH_EDGE_0, PSREG_UBERLIGHT_SMOOTH_EDGE_1,
PSREG_UBERLIGHT_SMOOTH_EDGE_OOW, PSREG_UBERLIGHT_SHEAR_ROUND,
PSREG_UBERLIGHT_AABB, PSREG_UBERLIGHT_WORLD_TO_LIGHT );
}
}
// Team color constant + sampler
if( bHasTeamColorTexture )
{
static const float kDefaultTeamColor[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
const float *vecTeamColor = IS_PARAM_DEFINED( info.m_nTeamColor ) ? params[info.m_nTeamColor]->GetVecValue() : kDefaultTeamColor;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( PSREG_RIMPARAMS, vecTeamColor, 1 );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nTeamColorTexture, -1 );
}
pContextData->m_SemiStaticCmdsOut.End();
}
CCommandBufferBuilder< CFixedCommandStorageBuffer< 1000 > > DynamicCmdsOut;
DynamicCmdsOut.Call( pContextData->m_SemiStaticCmdsOut.Base() );
// On PC, we sample from ambient occlusion texture
if ( IsPC() && g_pHardwareConfig->HasFastVertexTextures() )
{
ITexture *pAOTexture = pShaderAPI->GetTextureRenderingParameter( TEXTURE_RENDERPARM_AMBIENT_OCCLUSION );
if ( pAOTexture )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER15, pAOTexture, 0 );
}
else
{
DynamicCmdsOut.BindStandardTexture( SHADER_SAMPLER15, TEXTURE_WHITE );
}
}
bool bFlashlightShadows = false;
bool bUberlight = false;
float flAmbientOcclusionStrength = ( info.m_nAmbientOcclusion == -1 ) ? 0.0f : params[info.m_nAmbientOcclusion]->GetFloatValue();
if ( bHasFlashlight )
{
pShaderAPI->GetFlashlightShaderInfo( &bFlashlightShadows, &bUberlight );
flAmbientOcclusionStrength *= pShaderAPI->GetFlashlightAmbientOcclusion();
}
float vEyePos_AmbientOcclusion[4];
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_AmbientOcclusion );
vEyePos_AmbientOcclusion[3] = clamp( flAmbientOcclusionStrength, 0.0f, 1.0f );
DynamicCmdsOut.SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_AmbientOcclusion, 1 );
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int numBones = pShaderAPI->GetCurrentNumBones();
bool bWriteDepthToAlpha = false;
bool bWriteWaterFogToAlpha = false;
if( bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
LightState_t lightState = { 0, false, false };
if( !bHasFlashlightOnly )
{
pShaderAPI->GetDX9LightState( &lightState );
}
if ( bHasFoW )
{
if( bFOWValidTexture )
pShader->BindTexture( SHADER_SAMPLER9, info.m_nFoW, -1 );
else
pShaderAPI->BindStandardTexture( SHADER_SAMPLER9, TEXTURE_WHITE );
float vFoWSize[ 4 ];
Vector vMins = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MINS );
Vector vMaxs = pShaderAPI->GetVectorRenderingParameter( VECTOR_RENDERPARM_GLOBAL_FOW_MAXS );
vFoWSize[ 0 ] = vMins.x;
vFoWSize[ 1 ] = vMins.y;
vFoWSize[ 2 ] = vMaxs.x - vMins.x;
vFoWSize[ 3 ] = vMaxs.y - vMins.y;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, vFoWSize );
}
if( bDeferredActive )
{
pShader->BindTexture( SHADER_SAMPLER10, GetDeferredExt()->GetTexture_LightAccum() );
pShader->BindTexture( SHADER_SAMPLER11, GetDeferredExt()->GetTexture_LightAccum2() );
int x, y, w, t;
pShaderAPI->GetCurrentViewport( x, y, w, t );
float fl1[4] = { 1.0f / w, 1.0f / t, 0, 0 };
pShaderAPI->SetPixelShaderConstant( PSREG_UBERLIGHT_SMOOTH_EDGE_0, fl1 );
}
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
int nLightingPreviewMode = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_ENABLE_FIXED_LIGHTING );
if ( ( nLightingPreviewMode == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH ) && IsPC() )
{
float vEyeDir[4];
pShaderAPI->GetWorldSpaceCameraDirection( vEyeDir );
float flFarZ = pShaderAPI->GetFarZ();
vEyeDir[0] /= flFarZ; // Divide by farZ for SSAO algorithm
vEyeDir[1] /= flFarZ;
vEyeDir[2] /= flFarZ;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_8, vEyeDir );
}
TessellationMode_t nTessellationMode = pShaderAPI->GetTessellationMode();
if ( nTessellationMode != TESSELLATION_MODE_DISABLED && g_pHardwareConfig->HasFastVertexTextures() )
{
pShaderAPI->BindStandardVertexTexture( SHADER_VERTEXTEXTURE_SAMPLER1, TEXTURE_SUBDIVISION_PATCHES );
float vSubDDimensions[4] = { 1.0f/pShaderAPI->GetSubDHeight(),
bHasDisplacement && mat_displacementmap.GetBool() ? 1.0f : 0.0f,
bHasDisplacementWrinkles && mat_displacementmap.GetBool() ? 1.0f : 0.0f, 0.0f };
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_9, vSubDDimensions );
if( bHasDisplacement )
{
pShader->BindVertexTexture( SHADER_VERTEXTEXTURE_SAMPLER2, info.m_nDisplacementMap );
}
else
{
pShaderAPI->BindStandardVertexTexture( SHADER_VERTEXTEXTURE_SAMPLER2, TEXTURE_BLACK );
}
// Currently, tessellation is mutually exclusive with any kind of GPU-side skinning, morphing or vertex compression
Assert( !pShaderAPI->IsHWMorphingEnabled() );
Assert( numBones == 0 );
Assert( vertexCompression == 0);
}
else
{
nTessellationMode = TESSELLATION_MODE_DISABLED;
}
DECLARE_DYNAMIC_VERTEX_SHADER( phong_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, ( numBones > 0) && ( nTessellationMode == TESSELLATION_MODE_DISABLED ) );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression && ( nTessellationMode == TESSELLATION_MODE_DISABLED ) );
SET_DYNAMIC_VERTEX_SHADER_COMBO( TESSELLATION, nTessellationMode );
SET_DYNAMIC_VERTEX_SHADER( phong_vs30 );
if( bDeferredActive )
{
DECLARE_DYNAMIC_PIXEL_SHADER( phong_deferred_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, nLightingPreviewMode ? 0 : lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, nLightingPreviewMode ? false : bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, nLightingPreviewMode ? false : bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER_COMBO( UBERLIGHT, bUberlight );
SET_DYNAMIC_PIXEL_SHADER( phong_deferred_ps30 );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( phong_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, nLightingPreviewMode ? 0 : lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, nLightingPreviewMode ? false : bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, nLightingPreviewMode ? false : bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER_COMBO( UBERLIGHT, bUberlight );
SET_DYNAMIC_PIXEL_SHADER( phong_ps30 );
}
bool bUnusedTexCoords[3] = { false, false, !pShaderAPI->IsHWMorphingEnabled() || !bIsDecal };
pShaderAPI->MarkUnusedVertexFields( 0, 3, bUnusedTexCoords );
// Set constant to enable translation of VPOS to render target coordinates in ps_3_0
pShaderAPI->SetScreenSizeForVPOS();
DynamicCmdsOut.End();
pShaderAPI->ExecuteCommandBuffer( DynamicCmdsOut.Base() );
}
pShader->Draw();
}
void Draw_Eyes_Refract_Internal( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, bool bDrawFlashlightAdditivePass, Eye_Refract_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool bDiffuseWarp = IS_PARAM_DEFINED( info.m_nDiffuseWarpTexture );
bool bIntro = IS_PARAM_DEFINED( info.m_nIntro ) ? ( params[info.m_nIntro]->GetIntValue() ? true : false ) : false;
SHADOW_STATE
{
SET_FLAGS2( MATERIAL_VAR2_LIGHTING_VERTEX_LIT );
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // Cornea normal
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Iris
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // Cube reflection
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Ambient occlusion
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 0;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
if ( bDiffuseWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // Light warp
}
int nShadowFilterMode = 0;
if ( bDrawFlashlightAdditivePass == true )
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
pShaderShadow->EnableDepthWrites( false );
pShader->EnableAlphaBlending( SHADER_BLEND_ONE, SHADER_BLEND_ONE ); // Write over the eyes that were already there
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // Flashlight cookie
}
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( sdk_eye_refract_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT ) );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, bIntro ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_eye_refract_vs20 );
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
bool bSphereTexKillCombo = IS_PARAM_DEFINED( info.m_nSphereTexKillCombo ) ? ( params[info.m_nSphereTexKillCombo]->GetIntValue() ? true : false ) : ( kDefaultSphereTexKillCombo ? true : false );
bool bRayTraceSphere = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? ( params[info.m_nRaytraceSphere]->GetIntValue() ? true : false ) : ( kDefaultRaytraceSphere ? true : false );
DECLARE_STATIC_PIXEL_SHADER( sdk_eye_refract_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( SPHERETEXKILLCOMBO, bSphereTexKillCombo ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( RAYTRACESPHERE, bRayTraceSphere ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( sdk_eye_refract_ps20b );
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER6 );
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Noise map
}
}
else
{
DECLARE_STATIC_PIXEL_SHADER( sdk_eye_refract_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER( sdk_eye_refract_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( sdk_eye_refract_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( HALFLAMBERT, IS_FLAG_SET( MATERIAL_VAR_HALFLAMBERT ) );
SET_STATIC_VERTEX_SHADER_COMBO( INTRO, bIntro ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_VERTEX_SHADER( sdk_eye_refract_vs30 );
bool bSphereTexKillCombo = IS_PARAM_DEFINED( info.m_nSphereTexKillCombo ) ? ( params[info.m_nSphereTexKillCombo]->GetIntValue() ? true : false ) : ( kDefaultSphereTexKillCombo ? true : false );
bool bRayTraceSphere = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? ( params[info.m_nRaytraceSphere]->GetIntValue() ? true : false ) : ( kDefaultRaytraceSphere ? true : false );
DECLARE_STATIC_PIXEL_SHADER( sdk_eye_refract_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( SPHERETEXKILLCOMBO, bSphereTexKillCombo ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( RAYTRACESPHERE, bRayTraceSphere ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bDrawFlashlightAdditivePass ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, bDiffuseWarp ? 1 : 0 );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( sdk_eye_refract_ps30 );
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Shadow depth map
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Noise map
}
}
#endif
// On DX9, get the gamma read and write correct
//pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, false ); // Cornea normal
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true ); // Iris
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true ); // Cube map reflection
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, true ); // Ambient occlusion
pShaderShadow->EnableSRGBWrite( true );
if ( bDiffuseWarp )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true ); // Light Warp
}
if ( bDrawFlashlightAdditivePass == true )
{
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true ); // Flashlight cookie
}
// Fog
if ( bDrawFlashlightAdditivePass == true )
{
pShader->FogToBlack();
}
else
{
pShader->FogToFogColor();
}
}
DYNAMIC_STATE
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture = NULL;
FlashlightState_t flashlightState;
bool bFlashlightShadows = false;
if ( bDrawFlashlightAdditivePass == true )
{
flashlightState = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
bFlashlightShadows = flashlightState.m_bEnableShadows;
}
pShader->BindTexture( SHADER_SAMPLER0, info.m_nCorneaTexture );
pShader->BindTexture( SHADER_SAMPLER1, info.m_nIris, info.m_nIrisFrame );
pShader->BindTexture( SHADER_SAMPLER2, info.m_nEnvmap );
pShader->BindTexture( SHADER_SAMPLER3, info.m_nAmbientOcclTexture );
if ( bDiffuseWarp )
{
if ( r_lightwarpidentity.GetBool() )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER4, TEXTURE_IDENTITY_LIGHTWARP );
}
else
{
pShader->BindTexture( SHADER_SAMPLER4, info.m_nDiffuseWarpTexture );
}
}
if ( bDrawFlashlightAdditivePass == true )
pShader->BindTexture( SHADER_SAMPLER5, flashlightState.m_pSpotlightTexture, flashlightState.m_nSpotlightTextureFrame );
pShader->SetAmbientCubeDynamicStateVertexShader();
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, info.m_nEyeOrigin );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nIrisU );
pShader->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_3, info.m_nIrisV );
if ( bDrawFlashlightAdditivePass == true )
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_4, flashlightState.m_vecLightOrigin.Base(), 1 );
LightState_t lightState = { 0, false, false };
if ( bDrawFlashlightAdditivePass == false )
{
pShaderAPI->GetDX9LightState( &lightState );
}
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_eye_refract_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_eye_refract_vs20 );
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_10, VERTEX_SHADER_SHADER_SPECIFIC_CONST_11, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( sdk_eye_refract_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, pShaderAPI->GetSceneFogMode() == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DYNAMIC_LIGHT, lightState.HasDynamicLight() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( STATIC_LIGHT, lightState.m_bStaticLight ? 1 : 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( sdk_eye_refract_vs30 );
}
#endif
// Get luminance of ambient cube and saturate it
float fAverageAmbient = max(0.0f, min( pShaderAPI->GetAmbientLightCubeLuminance(), 1.0f ) );
// Special constant for DX9 eyes: { Dilation, Glossiness, x, x };
float vPSConst[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
vPSConst[0] = IS_PARAM_DEFINED( info.m_nDilation ) ? params[info.m_nDilation]->GetFloatValue() : kDefaultDilation;
vPSConst[1] = IS_PARAM_DEFINED( info.m_nGlossiness ) ? params[info.m_nGlossiness]->GetFloatValue() : kDefaultGlossiness;
vPSConst[2] = fAverageAmbient;
vPSConst[3] = IS_PARAM_DEFINED( info.m_nCorneaBumpStrength ) ? params[info.m_nCorneaBumpStrength]->GetFloatValue() : kDefaultCorneaBumpStrength;
pShaderAPI->SetPixelShaderConstant( 0, vPSConst, 1 );
pShaderAPI->SetPixelShaderConstant( 1, IS_PARAM_DEFINED( info.m_nEyeOrigin ) ? params[info.m_nEyeOrigin]->GetVecValue() : kDefaultEyeOrigin, 1 );
pShaderAPI->SetPixelShaderConstant( 2, IS_PARAM_DEFINED( info.m_nIrisU ) ? params[info.m_nIrisU]->GetVecValue() : kDefaultIrisU, 1 );
pShaderAPI->SetPixelShaderConstant( 3, IS_PARAM_DEFINED( info.m_nIrisV ) ? params[info.m_nIrisV]->GetVecValue() : kDefaultIrisV, 1 );
float vEyePos[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos );
pShaderAPI->SetPixelShaderConstant( 4, vEyePos, 1 );
pShaderAPI->SetPixelShaderConstant( 5, IS_PARAM_DEFINED( info.m_nAmbientOcclColor ) ? params[info.m_nAmbientOcclColor]->GetVecValue() : kDefaultAmbientOcclColor, 1 );
float vPackedConst6[4] = { 1.0f, 1.0f, 1.0f, 1.0f };
//vPackedConst6[0] Unused
vPackedConst6[1] = IS_PARAM_DEFINED( info.m_nEyeballRadius ) ? params[info.m_nEyeballRadius]->GetFloatValue() : kDefaultEyeballRadius;
//vPackedConst6[2] = IS_PARAM_DEFINED( info.m_nRaytraceSphere ) ? params[info.m_nRaytraceSphere]->GetFloatValue() : kDefaultRaytraceSphere;
vPackedConst6[3] = IS_PARAM_DEFINED( info.m_nParallaxStrength ) ? params[info.m_nParallaxStrength]->GetFloatValue() : kDefaultParallaxStrength;
pShaderAPI->SetPixelShaderConstant( 6, vPackedConst6, 1 );
float fPixelFogType = pShaderAPI->GetPixelFogCombo() == 1 ? 1 : 0;
// Controls for lerp-style paths through shader code
float vShaderControls[4] = { fPixelFogType, 0, 0, 0 };
pShaderAPI->SetPixelShaderConstant( 10, vShaderControls, 1 );
if ( bDrawFlashlightAdditivePass == true )
{
SetFlashLightColorFromState( flashlightState, pShaderAPI );
if ( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && flashlightState.m_bEnableShadows )
{
pShader->BindTexture( SHADER_SAMPLER6, pFlashlightDepthTexture, 0 );
pShaderAPI->BindStandardTexture( SHADER_SAMPLER7, TEXTURE_SHADOW_NOISE_2D );
}
}
// Flashlight tax
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps20b );
}
else // ps.2.0
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps20 );
}
}
#ifndef _X360
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( sdk_eye_refract_ps30 );
}
#endif
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
if ( bDrawFlashlightAdditivePass == true )
{
float atten[4], pos[4], tweaks[4];
atten[0] = flashlightState.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZ;
pShaderAPI->SetPixelShaderConstant( 7, atten, 1 );
pos[0] = flashlightState.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pShaderAPI->SetPixelShaderConstant( 8, pos, 1 );
//pShaderAPI->SetPixelShaderConstant( 9, worldToTexture.Base(), 4 );
//10
//11
//12
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, worldToTexture[0], 1 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, worldToTexture[1], 1 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_8, worldToTexture[2], 1 );
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_9, worldToTexture[3], 1 );
// Tweaks associated with a given flashlight
tweaks[0] = flashlightState.m_flShadowFilterSize / flashlightState.m_flShadowMapResolution;
tweaks[1] = ShadowAttenFromState( flashlightState );
pShader->HashShadow2DJitter( flashlightState.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
pShaderAPI->SetPixelShaderConstant( 9, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
vScreenScale[0] = (float) nWidth / 32.0f;
vScreenScale[1] = (float) nHeight / 32.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
}
else // Lighting constants when not drawing flashlight
{
pShaderAPI->CommitPixelShaderLighting( PSREG_LIGHT_INFO_ARRAY );
}
// Intro tax
if ( bIntro )
{
float curTime = params[info.m_nWarpParam]->GetFloatValue();
float timeVec[4] = { 0.0f, 0.0f, 0.0f, curTime };
if ( IS_PARAM_DEFINED( info.m_nEntityOrigin ) )
{
params[info.m_nEntityOrigin]->GetVecValue( timeVec, 3 );
}
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, timeVec, 1 );
}
}
pShader->Draw();
}
void DrawCloak_DX9( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, Cloak_DX9_Vars_t &info, VertexCompressionType_t vertexCompression )
{
bool bIsModel = IS_FLAG_SET( MATERIAL_VAR_MODEL );
bool bMasked = (params[info.m_nMasked]->GetIntValue() != 0);
bool hasDiffuseWarp = (info.m_nDiffuseWarpTexture != -1) && params[info.m_nDiffuseWarpTexture]->IsTexture();
bool hasPhongExponentTexture = (info.m_nPhongExponentTexture != -1) && params[info.m_nPhongExponentTexture]->IsTexture();
bool hasPhongTintMap = hasPhongExponentTexture && (info.m_nPhongAlbedoTint != -1) && ( params[info.m_nPhongAlbedoTint]->GetIntValue() != 0 );
bool bHasRimLight = (info.m_nRimLight != -1) && ( params[info.m_nRimLight]->GetIntValue() != 0 );
bool bHasRimMaskMap = hasPhongExponentTexture && bHasRimLight && (info.m_nRimMask != -1) && ( params[info.m_nRimMask]->GetIntValue() != 0 );
SHADOW_STATE
{
SET_FLAGS2( MATERIAL_VAR2_LIGHTING_VERTEX_LIT );
pShader->SetInitialShadowState( );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true ); // Always SRGB read on base map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true ); // Refraction map sampler...
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true );
pShaderShadow->EnableSRGBWrite( true );
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL;
int nTexCoordCount = 1;
int userDataSize = 0;
if( bIsModel )
{
userDataSize = 4;
}
else
{
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T;
}
// This shader supports compressed vertices, so OR in that flag:
flags |= VERTEX_FORMAT_COMPRESSED;
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, NULL, userDataSize );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_STATIC_VERTEX_SHADER( cloak_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER( cloak_vs20 );
// Bind ps_2_b shader so we can get Phong terms
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( cloak_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, hasDiffuseWarp );
SET_STATIC_PIXEL_SHADER( cloak_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( cloak_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, hasDiffuseWarp );
SET_STATIC_PIXEL_SHADER( cloak_ps20 );
}
}
#ifndef _X360
else
{
// The vertex shader uses the vertex id stream
SET_FLAGS2( MATERIAL_VAR2_USES_VERTEXID );
DECLARE_STATIC_VERTEX_SHADER( cloak_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( MODEL, bIsModel );
SET_STATIC_VERTEX_SHADER( cloak_vs30 );
// Bind ps_2_b shader so we can get Phong terms
DECLARE_STATIC_PIXEL_SHADER( cloak_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( LIGHTWARPTEXTURE, hasDiffuseWarp );
SET_STATIC_PIXEL_SHADER( cloak_ps30 );
}
#endif
pShader->DefaultFog();
if( bMasked )
{
pShader->EnableAlphaBlending( SHADER_BLEND_ONE_MINUS_SRC_ALPHA, SHADER_BLEND_SRC_ALPHA );
}
}
DYNAMIC_STATE
{
pShaderAPI->SetDefaultState();
// Bind textures
pShader->BindTexture( SHADER_SAMPLER0, info.m_nBaseTexture, 0 ); // Base Map
pShaderAPI->BindStandardTexture( SHADER_SAMPLER2, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 ); // Refraction Map
pShader->BindTexture( SHADER_SAMPLER3, info.m_nNormalMap, info.m_nBumpFrame ); // Normal Map
pShaderAPI->BindStandardTexture( SHADER_SAMPLER5, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED ); // Normalization cube map
if ( hasDiffuseWarp )
{
if ( r_lightwarpidentity.GetBool() )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER1, TEXTURE_IDENTITY_LIGHTWARP );
}
else
{
pShader->BindTexture( SHADER_SAMPLER1, info.m_nDiffuseWarpTexture ); // Light warp texture
}
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
int fogIndex = ( fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z ) ? 1 : 0;
LightState_t lightState;
pShaderAPI->GetDX9LightState( &lightState );
#ifndef _X360
if ( !g_pHardwareConfig->HasFastVertexTextures() )
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( cloak_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( cloak_vs20 );
// Bind ps_2_b shader so we can get Phong, rim and a cloudier refraction
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_ps20b );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( cloak_ps20b );
}
else
{
// JasonM Hack
//
// In general, cloaking on ps_2_0 needs re-working for multipass...yuck...
//
int nPS20NumLights = max( lightState.m_nNumLights, 1 );
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_ps20 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, nPS20NumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( cloak_ps20 );
}
}
#ifndef _X360
else
{
pShader->SetHWMorphVertexShaderState( VERTEX_SHADER_SHADER_SPECIFIC_CONST_6, VERTEX_SHADER_SHADER_SPECIFIC_CONST_7, SHADER_VERTEXTEXTURE_SAMPLER0 );
DECLARE_DYNAMIC_VERTEX_SHADER( cloak_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( DOWATERFOG, fogIndex );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( MORPHING, pShaderAPI->IsHWMorphingEnabled() );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( cloak_vs30 );
DECLARE_DYNAMIC_PIXEL_SHADER( cloak_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z );
SET_DYNAMIC_PIXEL_SHADER_COMBO( PIXELFOGTYPE, pShaderAPI->GetPixelFogCombo() );
SET_DYNAMIC_PIXEL_SHADER( cloak_ps30 );
}
#endif
pShader->SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, info.m_nBumpTransform );
if( g_pHardwareConfig->GetHDRType() == HDR_TYPE_NONE )
{
pShader->SetPixelShaderConstant( 27, info.m_nRefractTint );
}
else
{
pShader->SetPixelShaderConstantGammaToLinear( 27, info.m_nRefractTint );
}
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
// Pack phong exponent in with the eye position
float vEyePos_SpecExponent[4], vFresnelRanges_SpecBoost[4] = {0, 0.5, 1, 1};
float vSpecularTint[4] = {1, 1, 1, 1}, vRimBoost[4] = {1, 1, 1, 1};
pShaderAPI->GetWorldSpaceCameraPosition( vEyePos_SpecExponent );
if ( (info.m_nPhongExponent != -1) && params[info.m_nPhongExponent]->IsDefined() )
vEyePos_SpecExponent[3] = params[info.m_nPhongExponent]->GetFloatValue(); // This overrides the channel in the map
else
vEyePos_SpecExponent[3] = 0; // Use the alpha channel of the normal map for the exponent
if ( (info.m_nPhongTint != -1 ) && params[info.m_nPhongTint]->IsDefined() ) // Get the tint parameter
params[info.m_nPhongTint]->GetVecValue(vSpecularTint, 4);
// Get the rim light power (goes in w of Phong tint)
if ( bHasRimLight && (info.m_nRimLightPower != -1) && params[info.m_nRimLightPower]->IsDefined() )
{
vSpecularTint[3] = params[info.m_nRimLightPower]->GetFloatValue();
vSpecularTint[3] = max(vSpecularTint[3], 1.0f); // Make sure this is at least 1
}
// Get the rim boost power (goes in w of flashlight position)
if ( bHasRimLight && (info.m_nRimLightBoost != -1) && params[info.m_nRimLightBoost]->IsDefined() )
{
vRimBoost[3] = params[info.m_nRimLightBoost]->GetFloatValue();
}
// Rim mask...if this is true, use alpha channel of spec exponent texture to mask the rim term
if ( bHasRimMaskMap )
{
float vRimMaskControl[4] = {0, 0, 0, 0}; // Only x is relevant in shader code
vRimMaskControl[0] = params[info.m_nRimMask]->GetFloatValue();
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, vRimMaskControl, 1 );
}
// If it's all zeros, there was no constant tint in the vmt
if ( (vSpecularTint[0] == 0.0f) && (vSpecularTint[1] == 0.0f) && (vSpecularTint[2] == 0.0f) )
{
if ( hasPhongTintMap ) // If we have a map to use, tell the shader
{
vSpecularTint[0] = -1;
}
else // Otherwise, just tint with white
{
vSpecularTint[0] = 1.0f;
vSpecularTint[1] = 1.0f;
vSpecularTint[2] = 1.0f;
}
}
if ( (info.m_nPhongFresnelRanges != -1 ) && params[info.m_nPhongFresnelRanges]->IsDefined() )
params[info.m_nPhongFresnelRanges]->GetVecValue( vFresnelRanges_SpecBoost, 3 ); // Grab optional fresnel range parameters
if ( ( info.m_nPhongBoost != -1 ) &¶ms[info.m_nPhongBoost]->IsDefined() ) // Grab optional phong boost param
vFresnelRanges_SpecBoost[3] = params[info.m_nPhongBoost]->GetFloatValue();
else
vFresnelRanges_SpecBoost[3] = 1.0f;
pShaderAPI->SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, vEyePos_SpecExponent, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_FRESNEL_SPEC_PARAMS, vFresnelRanges_SpecBoost, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_SPEC_RIM_PARAMS, vSpecularTint, 1 );
pShaderAPI->SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, vRimBoost, 1 ); // Rim boost in w on non-flashlight pass
pShaderAPI->SetPixelShaderFogParams( PSREG_FOG_PARAMS );
// Lighting constants
pShaderAPI->SetPixelShaderStateAmbientLightCube( PSREG_AMBIENT_CUBE, !lightState.m_bAmbientLight );
pShaderAPI->CommitPixelShaderLighting( PSREG_LIGHT_INFO_ARRAY );
// Set c0 and c1 to contain first two rows of ViewProj matrix
VMatrix matView, matProj, matViewProj;
pShaderAPI->GetMatrix( MATERIAL_VIEW, matView.m[0] );
pShaderAPI->GetMatrix( MATERIAL_PROJECTION, matProj.m[0] );
matViewProj = matView * matProj;
pShaderAPI->SetPixelShaderConstant( 0, matViewProj.m[0], 2 );
// Cloaking control constants
float vCloakControls[4] = { params[info.m_nRefractAmount]->GetFloatValue(), params[info.m_nCloakFactor]->GetFloatValue(), 0.0f, 0.0f };
pShaderAPI->SetPixelShaderConstant( 3, vCloakControls, 1 );
}
pShader->Draw();
}
void DrawPass( IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, bool hasFlashlight, VertexCompressionType_t vertexCompression )
{
bool bSinglePassFlashlight = false;
bool hasBump = params[BUMPMAP]->IsTexture();
bool hasDiffuseBumpmap = hasBump && (params[NODIFFUSEBUMPLIGHTING]->GetIntValue() == 0);
bool hasBaseTexture = params[BASETEXTURE]->IsTexture();
bool hasDetailTexture = /*!hasBump && */params[DETAIL]->IsTexture();
bool hasVertexColor = IS_FLAG_SET( MATERIAL_VAR_VERTEXCOLOR ) != 0;
bool bHasDetailAlpha = params[DETAIL_ALPHA_MASK_BASE_TEXTURE]->GetIntValue() != 0;
bool bIsAlphaTested = IS_FLAG_SET( MATERIAL_VAR_ALPHATEST ) != 0;
BlendType_t nBlendType = EvaluateBlendRequirements( BASETEXTURE, true );
bool bFullyOpaque = (nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !IS_FLAG_SET(MATERIAL_VAR_ALPHATEST); //dest alpha is free for special use
bool bSeamlessMapping = params[SEAMLESS_SCALE]->GetFloatValue() != 0.0;
bool bShaderSrgbRead = ( IsX360() && IS_PARAM_DEFINED( SHADERSRGBREAD360 ) && params[SHADERSRGBREAD360]->GetIntValue() );
SHADOW_STATE
{
int nShadowFilterMode = 0;
// Alpha test: FIXME: shouldn't this be handled in Shader_t::SetInitialShadowState
pShaderShadow->EnableAlphaTest( bIsAlphaTested );
if( hasFlashlight )
{
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
SetAdditiveBlendingShadowState( BASETEXTURE, true );
pShaderShadow->EnableDepthWrites( false );
// Be sure not to write to dest alpha
pShaderShadow->EnableAlphaWrites( false );
}
else
{
SetDefaultBlendingShadowState( BASETEXTURE, true );
}
unsigned int flags = VERTEX_POSITION;
if( hasBaseTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, !bShaderSrgbRead );
}
// if( hasLightmap )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, true );
}
if( hasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true );
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER7 );
flags |= VERTEX_TANGENT_S | VERTEX_TANGENT_T | VERTEX_NORMAL;
}
if( hasDetailTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true );
}
if( hasBump )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true );
}
if( hasVertexColor )
{
flags |= VERTEX_COLOR;
}
// Normalizing cube map
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true );
// texcoord0 : base texcoord
// texcoord1 : lightmap texcoord
// texcoord2 : lightmap texcoord offset
int numTexCoords = 2;
if( hasBump )
{
numTexCoords = 3;
}
pShaderShadow->VertexShaderVertexFormat( flags, numTexCoords, 0, 0 );
// Pre-cache pixel shaders
bool hasSelfIllum = IS_FLAG_SET( MATERIAL_VAR_SELFILLUM );
pShaderShadow->EnableSRGBWrite( true );
int nLightingPreviewMode = IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER0 ) + 2 * IS_FLAG2_SET( MATERIAL_VAR2_USE_GBUFFER1 );
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
SET_STATIC_VERTEX_SHADER_COMBO( ENVMAP_MASK, false );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMASK, false );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, hasFlashlight );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_VERTEX_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXALPHATEXBLENDFACTOR, false );
SET_STATIC_VERTEX_SHADER_COMBO( PARALLAX_MAPPING, 0 ); //( bumpmap_variant == 2 )?1:0);
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamlessMapping ); //( bumpmap_variant == 2 )?1:0);
SET_STATIC_VERTEX_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_VERTEX_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_VERTEX_SHADER_COMBO( FANCY_BLENDING, false );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode != 0 );
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
}
else
#endif
{
DECLARE_STATIC_VERTEX_SHADER( lightmappedgeneric_vs20 );
SET_STATIC_VERTEX_SHADER_COMBO( ENVMAP_MASK, false );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMASK, false );
SET_STATIC_VERTEX_SHADER_COMBO( TANGENTSPACE, hasFlashlight );
SET_STATIC_VERTEX_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_VERTEX_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_VERTEX_SHADER_COMBO( VERTEXALPHATEXBLENDFACTOR, false );
SET_STATIC_VERTEX_SHADER_COMBO( PARALLAX_MAPPING, 0 ); //( bumpmap_variant == 2 )?1:0);
SET_STATIC_VERTEX_SHADER_COMBO( SEAMLESS, bSeamlessMapping ); //( bumpmap_variant == 2 )?1:0);
SET_STATIC_VERTEX_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_VERTEX_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_VERTEX_SHADER_COMBO( FANCY_BLENDING, false );
SET_STATIC_VERTEX_SHADER_COMBO( LIGHTING_PREVIEW, nLightingPreviewMode != 0 );
#ifdef _X360
SET_STATIC_VERTEX_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
#endif
SET_STATIC_VERTEX_SHADER( lightmappedgeneric_vs20 );
}
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_STATIC_PIXEL_SHADER( worldtwotextureblend_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_ALPHA_MASK_BASE_TEXTURE, bHasDetailAlpha );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER( worldtwotextureblend_ps30 );
}
else
#endif
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_STATIC_PIXEL_SHADER( worldtwotextureblend_ps20b );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_ALPHA_MASK_BASE_TEXTURE, bHasDetailAlpha );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER( worldtwotextureblend_ps20b );
}
else
{
DECLARE_STATIC_PIXEL_SHADER( worldtwotextureblend_ps20 );
SET_STATIC_PIXEL_SHADER_COMBO( DETAILTEXTURE, hasDetailTexture );
SET_STATIC_PIXEL_SHADER_COMBO( BUMPMAP, hasBump );
SET_STATIC_PIXEL_SHADER_COMBO( DIFFUSEBUMPMAP, hasDiffuseBumpmap );
SET_STATIC_PIXEL_SHADER_COMBO( VERTEXCOLOR, hasVertexColor );
SET_STATIC_PIXEL_SHADER_COMBO( SELFILLUM, hasSelfIllum );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL_ALPHA_MASK_BASE_TEXTURE, bHasDetailAlpha );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHT, hasFlashlight );
SET_STATIC_PIXEL_SHADER_COMBO( SEAMLESS, bSeamlessMapping );
SET_STATIC_PIXEL_SHADER_COMBO( SHADER_SRGB_READ, bShaderSrgbRead );
SET_STATIC_PIXEL_SHADER( worldtwotextureblend_ps20 );
}
// HACK HACK HACK - enable alpha writes all the time so that we have them for
// underwater stuff.
// But only do it if we're not using the alpha already for translucency
pShaderShadow->EnableAlphaWrites( bFullyOpaque );
if( hasFlashlight )
{
FogToBlack();
}
else
{
DefaultFog();
}
PI_BeginCommandBuffer();
PI_SetModulationVertexShaderDynamicState( );
PI_EndCommandBuffer();
}
DYNAMIC_STATE
{
if( hasBaseTexture )
{
BindTexture( SHADER_SAMPLER0, BASETEXTURE, FRAME );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER0, TEXTURE_WHITE );
}
// if( hasLightmap )
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER1, TEXTURE_LIGHTMAP );
}
bool bFlashlightShadows = false;
bool bUberlight = false;
if( hasFlashlight )
{
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
bFlashlightShadows = state.m_bEnableShadows;
bUberlight = state.m_bUberlight;
SetFlashLightColorFromState( state, pShaderAPI, bSinglePassFlashlight );
BindTexture( SHADER_SAMPLER2, state.m_pSpotlightTexture, state.m_nSpotlightTextureFrame );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() )
{
BindTexture( SHADER_SAMPLER7, pFlashlightDepthTexture );
}
}
if( hasDetailTexture )
{
BindTexture( SHADER_SAMPLER3, DETAIL, DETAILFRAME );
}
if( hasBump )
{
if( !g_pConfig->m_bFastNoBump )
{
BindTexture( SHADER_SAMPLER4, BUMPMAP, BUMPFRAME );
}
else
{
pShaderAPI->BindStandardTexture( SHADER_SAMPLER4, TEXTURE_NORMALMAP_FLAT );
}
}
pShaderAPI->BindStandardTexture( SHADER_SAMPLER6, TEXTURE_NORMALIZATION_CUBEMAP_SIGNED );
// If we don't have a texture transform, we don't have
// to set vertex shader constants or run vertex shader instructions
// for the texture transform.
bool bHasTextureTransform =
!( params[BASETEXTURETRANSFORM]->MatrixIsIdentity() &&
params[BUMPTRANSFORM]->MatrixIsIdentity() );
bool bVertexShaderFastPath = !bHasTextureTransform;
if( params[DETAIL]->IsTexture() )
{
bVertexShaderFastPath = false;
}
if( pShaderAPI->GetIntRenderingParameter(INT_RENDERPARM_ENABLE_FIXED_LIGHTING) != 0 )
{
bVertexShaderFastPath = false;
}
if( !bVertexShaderFastPath )
{
if ( !bSeamlessMapping )
{
SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, BASETEXTURETRANSFORM );
}
if( hasBump && !bHasDetailAlpha )
{
SetVertexShaderTextureTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, BUMPTRANSFORM );
Assert( !hasDetailTexture );
}
}
MaterialFogMode_t fogType = pShaderAPI->GetSceneFogMode();
if ( IsPC() )
{
bool bWorldNormal = pShaderAPI->GetIntRenderingParameter( INT_RENDERPARM_ENABLE_FIXED_LIGHTING ) == ENABLE_FIXED_LIGHTING_OUTPUTNORMAL_AND_DEPTH;
if ( bWorldNormal )
{
float vEyeDir[4];
pShaderAPI->GetWorldSpaceCameraDirection( vEyeDir );
float flFarZ = pShaderAPI->GetFarZ();
vEyeDir[0] /= flFarZ; // Divide by farZ for SSAO algorithm
vEyeDir[1] /= flFarZ;
vEyeDir[2] /= flFarZ;
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_12, vEyeDir );
}
}
#ifndef _X360
if (g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( FASTPATH, bVertexShaderFastPath );
SET_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_vs30 );
}
else
#endif
{
DECLARE_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_vs20 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( FASTPATH, bVertexShaderFastPath );
SET_DYNAMIC_VERTEX_SHADER( lightmappedgeneric_vs20 );
}
bool bWriteDepthToAlpha;
bool bWriteWaterFogToAlpha;
if( bFullyOpaque )
{
bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha();
bWriteWaterFogToAlpha = (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z);
AssertMsg( !(bWriteDepthToAlpha && bWriteWaterFogToAlpha), "Can't write two values to alpha at the same time." );
}
else
{
//can't write a special value to dest alpha if we're actually using as-intended alpha
bWriteDepthToAlpha = false;
bWriteWaterFogToAlpha = false;
}
#ifndef _X360
if ( g_pHardwareConfig->HasFastVertexTextures() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps30 );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER_COMBO( UBERLIGHT, bUberlight );
SET_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps30 );
}
else
#endif
if ( g_pHardwareConfig->SupportsPixelShaders_2_b() )
{
DECLARE_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps20b );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, bWriteWaterFogToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITE_DEPTH_TO_DESTALPHA, bWriteDepthToAlpha );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps20b );
}
else
{
DECLARE_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps20 );
// Don't write fog to alpha if we're using translucency
SET_DYNAMIC_PIXEL_SHADER_COMBO( WRITEWATERFOGTODESTALPHA, (fogType == MATERIAL_FOG_LINEAR_BELOW_FOG_Z) &&
(nBlendType != BT_BLENDADD) && (nBlendType != BT_BLEND) && !bIsAlphaTested );
SET_DYNAMIC_PIXEL_SHADER( worldtwotextureblend_ps20 );
}
// always set the transform for detail textures since I'm assuming that you'll
// always have a detailscale.
if( hasDetailTexture )
{
SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, BASETEXTURETRANSFORM, DETAILSCALE );
Assert( !( hasBump && !bHasDetailAlpha ) );
}
SetPixelShaderConstantGammaToLinear( 7, SELFILLUMTINT );
float eyePos[4];
pShaderAPI->GetWorldSpaceCameraPosition( eyePos );
pShaderAPI->SetPixelShaderConstant( 10, eyePos, 1 );
pShaderAPI->SetPixelShaderFogParams( 11 );
if ( bSeamlessMapping )
{
float map_scale[4]={ params[SEAMLESS_SCALE]->GetFloatValue(),0,0,0};
pShaderAPI->SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, map_scale );
}
if( hasFlashlight )
{
VMatrix worldToTexture;
const FlashlightState_t &flashlightState = pShaderAPI->GetFlashlightState( worldToTexture );
// Set the flashlight attenuation factors
float atten[4];
atten[0] = flashlightState.m_fConstantAtten;
atten[1] = flashlightState.m_fLinearAtten;
atten[2] = flashlightState.m_fQuadraticAtten;
atten[3] = flashlightState.m_FarZAtten;
pShaderAPI->SetPixelShaderConstant( 20, atten, 1 );
// Set the flashlight origin
float pos[4];
pos[0] = flashlightState.m_vecLightOrigin[0];
pos[1] = flashlightState.m_vecLightOrigin[1];
pos[2] = flashlightState.m_vecLightOrigin[2];
pos[3] = flashlightState.m_FarZ; // didn't have this in main. . probably need this?
pShaderAPI->SetPixelShaderConstant( 15, pos, 1 );
pShaderAPI->SetPixelShaderConstant( 16, worldToTexture.Base(), 4 );
if ( IsPC() && g_pHardwareConfig->HasFastVertexTextures() )
{
SetupUberlightFromState( pShaderAPI, flashlightState );
}
}
}
Draw();
}
void DrawFlesh( CBaseVSShader *pShader, IMaterialVar** params, IShaderDynamicAPI *pShaderAPI,
IShaderShadow* pShaderShadow, FleshVars_t &info, VertexCompressionType_t vertexCompression,
CBasePerMaterialContextData **pContextDataPtr )
{
CFlesh_DX9_Context *pContextData = reinterpret_cast< CFlesh_DX9_Context *> ( *pContextDataPtr );
bool bHasFlashlight = pShader->UsingFlashlight( params );
bool bAlphaBlend = IS_FLAG_SET( MATERIAL_VAR_TRANSLUCENT );
bool bDetail = ( info.m_nDetailTexture != -1 ) && ( params[info.m_nDetailTexture]->IsTexture() );
if ( pShader->IsSnapshotting() || (! pContextData ) || ( pContextData->m_bMaterialVarsChanged ) )
{
bool bTransMatMasks = (info.m_nTransMatMasksTexture != -1) && params[info.m_nTransMatMasksTexture]->IsTexture();
bool bEffectMasks = (info.m_nEffectMasksTexture != -1) && params[info.m_nEffectMasksTexture]->IsTexture();
bool bIridescentWarp = (info.m_nIridescentWarpTexture != -1) && params[info.m_nIridescentWarpTexture]->IsTexture();
bool bFresnelColorWarp = (info.m_nFresnelColorWarpTexture != -1) && params[info.m_nFresnelColorWarpTexture]->IsTexture();
bool bColorWarp = (info.m_nColorWarpTexture != -1) && params[info.m_nColorWarpTexture]->IsTexture();
bool bOpacityTexture = (info.m_nOpacityTexture != -1) && params[info.m_nOpacityTexture]->IsTexture();
bool bInteriorLayer = (info.m_nInteriorEnable != -1) && ( params[info.m_nInteriorEnable]->GetIntValue() > 0 );
bool bBackScatter = ( info.m_nBackScatter != -1 ) && ( params[info.m_nBackScatter]->GetFloatValue() > 0 );
bool bForwardScatter = ( info.m_nForwardScatter != -1) && ( params[info.m_nForwardScatter]->GetFloatValue() > 0 );
bool bNormal2 = ( info.m_nNormal2Softness != -1 ) && ( params[info.m_nNormal2Softness]->GetFloatValue() > 0 );
if ( pShader->IsSnapshotting() )
{
// Set stream format (note that this shader supports compression)
unsigned int flags = VERTEX_POSITION | VERTEX_NORMAL | VERTEX_FORMAT_COMPRESSED;
int nTexCoordCount = 1;
int userDataSize = 4;
int texCoordDims[4] = { 2, 2, 2, 2 };
pShaderShadow->VertexShaderVertexFormat( flags, nTexCoordCount, texCoordDims, userDataSize );
int nShadowFilterMode = 0;
if ( bHasFlashlight )
{
nShadowFilterMode = g_pHardwareConfig->GetShadowFilterMode(); // Based upon vendor and device dependent formats
}
DECLARE_STATIC_VERTEX_SHADER( flesh_vs30 );
SET_STATIC_VERTEX_SHADER( flesh_vs30 );
// Pixel Shader
if( /* g_pHardwareConfig->SupportsPixelShaders_3_0() */ true )
{
DECLARE_STATIC_PIXEL_SHADER( flesh_ps30 );
SET_STATIC_PIXEL_SHADER_COMBO( ALPHABLEND, bAlphaBlend );
SET_STATIC_PIXEL_SHADER_COMBO( TRANSMAT, bTransMatMasks );
SET_STATIC_PIXEL_SHADER_COMBO( FRESNEL_WARP, bFresnelColorWarp );
SET_STATIC_PIXEL_SHADER_COMBO( EFFECTS, bEffectMasks );
SET_STATIC_PIXEL_SHADER_COMBO( TINTING, bColorWarp );
SET_STATIC_PIXEL_SHADER_COMBO( IRIDESCENCE, bIridescentWarp );
SET_STATIC_PIXEL_SHADER_COMBO( OPACITY_TEXTURE, bOpacityTexture );
SET_STATIC_PIXEL_SHADER_COMBO( DETAIL, bDetail );
SET_STATIC_PIXEL_SHADER_COMBO( NORMAL2SOFT, bNormal2 );
SET_STATIC_PIXEL_SHADER_COMBO( INTERIOR_LAYER, bInteriorLayer );
SET_STATIC_PIXEL_SHADER_COMBO( BACK_SCATTER, bBackScatter );
SET_STATIC_PIXEL_SHADER_COMBO( FORWARD_SCATTER, bForwardScatter );
SET_STATIC_PIXEL_SHADER_COMBO( HIGH_PRECISION_DEPTH, (g_pHardwareConfig->GetHDRType() == HDR_TYPE_FLOAT) ? true : false );
SET_STATIC_PIXEL_SHADER_COMBO( FLASHLIGHTDEPTHFILTERMODE, nShadowFilterMode );
SET_STATIC_PIXEL_SHADER( flesh_ps30 );
}
else
{
Assert( !"No ps_3_0" );
}
// Textures
pShaderShadow->EnableTexture( SHADER_SAMPLER0, true ); // [sRGB] Base
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER0, true );
pShaderShadow->EnableTexture( SHADER_SAMPLER1, true ); // Bump
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER1, false );
if( bInteriorLayer )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER2, true ); // [sRGB] Backbuffer
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER2, true );
}
if( bTransMatMasks )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER3, true ); // Trans mat masks
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER3, false );
}
if( bColorWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER4, true ); // [sRGB] Color Warp
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER4, true );
}
if( bFresnelColorWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER5, true ); // [sRGB] Fresnel color warp (should be sRGB?)
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER5, true );
}
if( bOpacityTexture )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER6, true ); // Opacity
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER6, false );
}
if( bEffectMasks )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER10, true ); // Effect masks
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER10, false );
}
if( bIridescentWarp )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER11, true ); // [sRGB] Iridescent warp
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER11, true );
}
if( bDetail )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER12, true ); // [sRGB] Detail
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER12, true );
}
if ( bHasFlashlight )
{
pShaderShadow->EnableTexture( SHADER_SAMPLER7, true ); // Shadow depth map
pShaderShadow->SetShadowDepthFiltering( SHADER_SAMPLER7 );
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER7, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER8, true ); // Noise map
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER8, false );
pShaderShadow->EnableTexture( SHADER_SAMPLER9, true ); //[sRGB] Flashlight cookie
pShaderShadow->EnableSRGBRead( SHADER_SAMPLER9, true );
// Flashlight passes - additive blending
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE );
pShaderShadow->EnableAlphaWrites( false );
pShaderShadow->EnableDepthWrites( false );
}
else if ( bAlphaBlend )
{
// Base pass - alpha blending (regular translucency)
pShader->EnableAlphaBlending( SHADER_BLEND_SRC_ALPHA, SHADER_BLEND_ONE_MINUS_SRC_ALPHA );
pShaderShadow->EnableAlphaWrites( false ); // TODO: write alpha for fog or not?
pShaderShadow->EnableDepthWrites( true ); // Rely on depth-sorting
}
else
{
// Base pass - opaque blending (solid flesh or refractive translucency)
pShader->DisableAlphaBlending();
pShaderShadow->EnableAlphaWrites( true );
pShaderShadow->EnableDepthWrites( true );
}
pShaderShadow->EnableSRGBWrite( true );
// Per-instance state
pShader->PI_BeginCommandBuffer();
pShader->PI_SetVertexShaderAmbientLightCube();
pShader->PI_SetPixelShaderAmbientLightCube( PSREG_AMBIENT_CUBE );
pShader->PI_SetPixelShaderLocalLighting( PSREG_LIGHT_INFO_ARRAY );
pShader->PI_EndCommandBuffer();
}
if ( pShaderAPI && ( (! pContextData ) || ( pContextData->m_bMaterialVarsChanged ) ) )
{
if ( !pContextData ) // make sure allocated
{
pContextData = new CFlesh_DX9_Context;
*pContextDataPtr = pContextData;
}
pContextData->m_bMaterialVarsChanged = false;
pContextData->m_SemiStaticCmdsOut.Reset();
///////////////////////////
// Semi-static block
///////////////////////////
float flConsts[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
flConsts[0] = IS_PARAM_DEFINED( info.m_nBumpStrength ) ? params[info.m_nBumpStrength]->GetFloatValue() : kDefaultBumpStrength;
flConsts[1] = (g_pHardwareConfig->GetHDRType() == HDR_TYPE_FLOAT) ? 8192.0f : 192.0f; // destalpha dest scale factor. TODO: put this in its own const and call shaderAPI method to set
flConsts[2] = IS_PARAM_DEFINED( info.m_nInteriorFogStrength ) ? params[info.m_nInteriorFogStrength]->GetFloatValue() : kDefaultInteriorFogStrength;
flConsts[3] = IS_PARAM_DEFINED( info.m_nInteriorRefractStrength ) ? params[info.m_nInteriorRefractStrength]->GetFloatValue() : kDefaultInteriorRefractStrength;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 0, flConsts, 1 );
Assert( IS_PARAM_DEFINED( info.m_nFresnelParams ) );
if ( IS_PARAM_DEFINED( info.m_nFresnelParams ) )
params[info.m_nFresnelParams]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultFresnelParams, sizeof( kDefaultFresnelParams ) );
flConsts[3] = params[info.m_nInteriorBackgroundBoost]->GetFloatValue();
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 1, flConsts, 1 );
flConsts[0] = IS_PARAM_DEFINED( info.m_nRimLightExp ) ? params[info.m_nRimLightExp]->GetFloatValue() : kDefaultRimLightExp;
flConsts[1] = IS_PARAM_DEFINED( info.m_nRimLightScale ) ? params[info.m_nRimLightScale]->GetFloatValue() : kDefaultRimLightScale;
flConsts[2] = IS_PARAM_DEFINED( info.m_nSpecScale ) ? params[info.m_nSpecScale]->GetFloatValue() : kDefaultSpecScale;
flConsts[3] = IS_PARAM_DEFINED( info.m_nSpecExp2 ) ? params[info.m_nSpecExp2]->GetFloatValue() : kDefaultSpecExp;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 3, flConsts, 1 );
flConsts[0] = IS_PARAM_DEFINED( info.m_nSpecScale2 ) ? params[info.m_nSpecScale2]->GetFloatValue() : kDefaultSpecScale;
flConsts[1] = IS_PARAM_DEFINED( info.m_nFresnelBumpStrength ) ? params[info.m_nFresnelBumpStrength]->GetFloatValue() : kDefaultFresnelBumpStrength;
flConsts[2] = IS_PARAM_DEFINED( info.m_nDiffuseSoftNormal ) ? params[info.m_nDiffuseSoftNormal]->GetFloatValue() : kDefaultDiffuseSoftNormal;
flConsts[3] = IS_PARAM_DEFINED( info.m_nInteriorAmbientScale ) ? params[info.m_nInteriorAmbientScale]->GetFloatValue() : kDefaultInteriorAmbientScale;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 10, flConsts, 1 );
// Depth alpha [ TODO: support fog ]
bool bWriteDepthToAlpha = pShaderAPI->ShouldWriteDepthToDestAlpha() && !bAlphaBlend;
if ( IS_PARAM_DEFINED( info.m_nSpecFresnel ) )
params[info.m_nSpecFresnel]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultSpecFresnel, sizeof( kDefaultSpecFresnel ) );
flConsts[3] = bWriteDepthToAlpha ? 1.0f : 0.0f;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 12, flConsts, 1 );
if ( IS_PARAM_DEFINED( info.m_nPhongColorTint ) )
params[info.m_nPhongColorTint]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultPhongColorTint, sizeof( kDefaultPhongColorTint ) );
flConsts[3] = IS_PARAM_DEFINED( info.m_nInteriorBackLightScale ) ? params[info.m_nInteriorBackLightScale]->GetFloatValue() : kDefaultInteriorBackLightScale;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 19, flConsts, 1 );
if( bIridescentWarp || bFresnelColorWarp )
{
flConsts[0] = ( IS_PARAM_DEFINED( info.m_nIridescenceBoost ) ) ? params[info.m_nIridescenceBoost]->GetFloatValue(): kDefaultIridescenceBoost;
flConsts[1] = ( IS_PARAM_DEFINED( info.m_nIridescenceExponent ) ) ? params[info.m_nIridescenceExponent]->GetFloatValue(): kDefaultIridescenceExponent;
flConsts[2] = ( IS_PARAM_DEFINED( info.m_nHueShiftIntensity ) ) ? params[info.m_nHueShiftIntensity]->GetFloatValue(): kDefaultHueShiftIntensity;
flConsts[3] = ( IS_PARAM_DEFINED( info.m_nHueShiftFresnelExponent ) ) ? params[info.m_nHueShiftFresnelExponent]->GetFloatValue(): kDefaultHueShiftFresnelExponent;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 26, flConsts, 1 );
}
if ( IS_PARAM_DEFINED( info.m_nSelfIllumTint ) )
params[info.m_nSelfIllumTint]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultSelfIllumTint, sizeof( kDefaultSelfIllumTint ) );
float flDiffuseExp = IS_PARAM_DEFINED( info.m_nDiffuseExponent ) ? params[info.m_nDiffuseExponent]->GetFloatValue() : kDefaultDiffuseExponent;
flConsts[3] = pow( 0.5f, flDiffuseExp );
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 27, flConsts, 1 );
if ( IS_PARAM_DEFINED( info.m_nInteriorColor ) )
params[info.m_nInteriorColor]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultInteriorColor, sizeof( kDefaultInteriorColor ) );
flConsts[3] = params[info.m_nInteriorRefractBlur]->GetFloatValue();
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 32, flConsts, 1 );
if ( IS_PARAM_DEFINED( info.m_nSpecFresnel2 ) )
params[info.m_nSpecFresnel2]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultSpecFresnel2, sizeof( kDefaultSpecFresnel2 ) );
flConsts[3] = IS_PARAM_DEFINED( info.m_nPhong2Softness ) ? params[info.m_nPhong2Softness]->GetFloatValue() : kDefaultPhong2Softness;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 42, flConsts, 1 );
flConsts[0] = flDiffuseExp;
flConsts[1] = IS_PARAM_DEFINED( info.m_nNormal2Softness ) ? params[info.m_nNormal2Softness]->GetFloatValue() : kDefaultNormal2Softness;
flConsts[2] = IS_PARAM_DEFINED( info.m_nAmbientBoost ) ? params[info.m_nAmbientBoost]->GetFloatValue() : kDefaultAmbientBoost;
flConsts[3] = IS_PARAM_DEFINED( info.m_nAmbientBoostMaskMode ) ? params[info.m_nAmbientBoostMaskMode]->GetIntValue() : kDefaultAmbientBoostMaskMode;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 43, flConsts, 1 );
if ( bForwardScatter || bBackScatter )
{
flConsts[0] = IS_PARAM_DEFINED( info.m_nForwardScatter ) ? params[info.m_nForwardScatter]->GetFloatValue() : kDefaultForwardScatter;
flConsts[1] = IS_PARAM_DEFINED( info.m_nBackScatter ) ? params[info.m_nBackScatter]->GetFloatValue() : kDefaultBackScatter;
flConsts[2] = IS_PARAM_DEFINED( info.m_nSSDepth ) ? params[info.m_nSSDepth]->GetFloatValue() : kDefaultSSDepth;
flConsts[3] = IS_PARAM_DEFINED( info.m_nSSBentNormalIntensity ) ? params[info.m_nSSBentNormalIntensity]->GetFloatValue() : kDefaultSSBentNormalIntensity;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 44, flConsts, 1 );
if( IS_PARAM_DEFINED( info.m_nSSColorTint ) )
params[info.m_nSSColorTint]->GetVecValue( flConsts, 3 );
else
memcpy( flConsts, kDefaultSSColorTint, sizeof( kDefaultSSColorTint ) );
flConsts[3] = IS_PARAM_DEFINED( info.m_nSSTintByAlbedo ) ? params[info.m_nSSTintByAlbedo]->GetFloatValue() : kDefaultSSTintByAlbedo;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 45, flConsts, 1 );
}
flConsts[0] = 0.0f;
flConsts[1] = 0.0f;
if ( bDetail )
{
flConsts[0] = IS_PARAM_DEFINED( info.m_nDetailBlendMode ) ? params[info.m_nDetailBlendMode]->GetIntValue() : kDefaultDetailBlendMode;
flConsts[1] = IS_PARAM_DEFINED( info.m_nDetailBlendFactor) ? params[info.m_nDetailBlendFactor]->GetFloatValue() : kDefaultDetailBlendFactor;
flConsts[2] = 0.0f;
}
flConsts[3] = IS_PARAM_DEFINED( info.m_nSpecExp ) ? params[info.m_nSpecExp]->GetFloatValue() : kDefaultSpecExp;
pContextData->m_SemiStaticCmdsOut.SetPixelShaderConstant( 46, flConsts, 1 );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER0, BASETEXTURE, -1 );
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER1, info.m_nNormalMap, -1 );
pContextData->m_SemiStaticCmdsOut.BindStandardTexture( SHADER_SAMPLER2, TEXTURE_FRAME_BUFFER_FULL_TEXTURE_0 ); // Refraction Map
if ( bTransMatMasks )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER3, info.m_nTransMatMasksTexture, -1 );
}
if ( bColorWarp )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER4, info.m_nColorWarpTexture, -1 );
}
if ( bFresnelColorWarp )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER5, info.m_nFresnelColorWarpTexture, -1 );
}
if ( bOpacityTexture )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER6, info.m_nOpacityTexture, -1 );
}
if ( bEffectMasks )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER10, info.m_nEffectMasksTexture, -1 );
}
if ( bIridescentWarp )
{
pContextData->m_SemiStaticCmdsOut.BindTexture( pShader, SHADER_SAMPLER11, info.m_nIridescentWarpTexture, -1 );
}
// VS consts
flConsts[0] = IS_PARAM_DEFINED( info.m_nUVScale ) ? params[info.m_nUVScale]->GetFloatValue() : kDefaultUVScale;
pContextData->m_SemiStaticCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_0, flConsts, 1 );
flConsts[0] = IS_PARAM_DEFINED( info.m_nDetailScale ) ? params[info.m_nDetailScale]->GetFloatValue() : kDefaultDetailScale;
pContextData->m_SemiStaticCmdsOut.SetVertexShaderConstant( VERTEX_SHADER_SHADER_SPECIFIC_CONST_1, flConsts, 1 );
if ( IS_PARAM_DEFINED( info.m_nDetailTextureTransform ) )
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nDetailTextureTransform, info.m_nDetailScale );
else
pContextData->m_SemiStaticCmdsOut.SetVertexShaderTextureScaledTransform( VERTEX_SHADER_SHADER_SPECIFIC_CONST_2, info.m_nBaseTextureTransform, info.m_nDetailScale );
pContextData->m_SemiStaticCmdsOut.End();
// end semi-static block
}
}
if ( pShaderAPI ) //DYNAMIC_STATE
{
CCommandBufferBuilder< CFixedCommandStorageBuffer< 400 > > DynamicCmdsOut;
DynamicCmdsOut.Call( pContextData->m_SemiStaticCmdsOut.Base() );
///////////////////////////
// dynamic block
///////////////////////////
float camPos[4] = { 0.0f, 0.0f, 0.0f, 0.0f };
pShaderAPI->GetWorldSpaceCameraPosition( camPos );
DynamicCmdsOut.SetPixelShaderConstant( PSREG_EYEPOS_SPEC_EXPONENT, camPos );
if ( bDetail )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER12, info.m_nDetailTexture, info.m_nDetailFrame );
}
float mView[16];
pShaderAPI->GetMatrix( MATERIAL_VIEW, mView );
DynamicCmdsOut.SetPixelShaderConstant( 33, mView, 3 );
DynamicCmdsOut.SetPixelShaderFogParams( 36 );
LightState_t lightState = { 0, false, false };
pShaderAPI->GetDX9LightState( &lightState );
// flashlightfixme: put this in common code.
bool bFlashlightShadows = false;
if ( bHasFlashlight )
{
Assert( info.m_nFlashlightTexture >= 0 && info.m_nFlashlightTextureFrame >= 0 );
VMatrix worldToTexture;
ITexture *pFlashlightDepthTexture;
FlashlightState_t state = pShaderAPI->GetFlashlightStateEx( worldToTexture, &pFlashlightDepthTexture );
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER9, state.m_pSpotlightTexture, state.m_nSpotlightTextureFrame );
bFlashlightShadows = state.m_bEnableShadows;
SetFlashLightColorFromState( state, pShaderAPI, PSREG_FLASHLIGHT_COLOR );
if( pFlashlightDepthTexture && g_pConfig->ShadowDepthTexture() && state.m_bEnableShadows )
{
DynamicCmdsOut.BindTexture( pShader, SHADER_SAMPLER7, pFlashlightDepthTexture, -1 );
DynamicCmdsOut.BindStandardTexture( SHADER_SAMPLER8, TEXTURE_SHADOW_NOISE_2D );
}
float atten[4], pos[4], tweaks[4];
atten[0] = state.m_fConstantAtten; // Set the flashlight attenuation factors
atten[1] = state.m_fLinearAtten;
atten[2] = state.m_fQuadraticAtten;
atten[3] = state.m_FarZAtten;
DynamicCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_ATTENUATION, atten, 1 );
pos[0] = state.m_vecLightOrigin[0]; // Set the flashlight origin
pos[1] = state.m_vecLightOrigin[1];
pos[2] = state.m_vecLightOrigin[2];
pos[3] = state.m_FarZ;
DynamicCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_POSITION_RIM_BOOST, pos, 1 ); // steps on rim boost
DynamicCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_TO_WORLD_TEXTURE, worldToTexture.Base(), 4 );
// Tweaks associated with a given flashlight
tweaks[0] = ShadowFilterFromState( state );
tweaks[1] = ShadowAttenFromState( state );
pShader->HashShadow2DJitter( state.m_flShadowJitterSeed, &tweaks[2], &tweaks[3] );
DynamicCmdsOut.SetPixelShaderConstant( PSREG_ENVMAP_TINT__SHADOW_TWEAKS, tweaks, 1 );
// Dimensions of screen, used for screen-space noise map sampling
float vScreenScale[4] = {1280.0f / 32.0f, 720.0f / 32.0f, 0, 0};
int nWidth, nHeight;
pShaderAPI->GetBackBufferDimensions( nWidth, nHeight );
int nTexWidth, nTexHeight;
pShaderAPI->GetStandardTextureDimensions( &nTexWidth, &nTexHeight, TEXTURE_SHADOW_NOISE_2D );
vScreenScale[0] = (float) nWidth / nTexWidth;
vScreenScale[1] = (float) nHeight / nTexHeight;
DynamicCmdsOut.SetPixelShaderConstant( PSREG_FLASHLIGHT_SCREEN_SCALE, vScreenScale, 1 );
}
DynamicCmdsOut.End();
// end dynamic block
pShaderAPI->ExecuteCommandBuffer( DynamicCmdsOut.Base() );
// Set Vertex Shader Combos
DECLARE_DYNAMIC_VERTEX_SHADER( flesh_vs30 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( SKINNING, pShaderAPI->GetCurrentNumBones() > 0 );
SET_DYNAMIC_VERTEX_SHADER_COMBO( COMPRESSED_VERTS, (int)vertexCompression );
SET_DYNAMIC_VERTEX_SHADER( flesh_vs30 );
// Set Pixel Shader Combos
if( /*g_pHardwareConfig->SupportsPixelShaders_2_b()*/ true )
{
DECLARE_DYNAMIC_PIXEL_SHADER( flesh_ps30 );
SET_DYNAMIC_PIXEL_SHADER_COMBO( NUM_LIGHTS, lightState.m_nNumLights );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHT, bHasFlashlight );
SET_DYNAMIC_PIXEL_SHADER_COMBO( FLASHLIGHTSHADOWS, bFlashlightShadows );
SET_DYNAMIC_PIXEL_SHADER( flesh_ps30 );
}
else
{
Assert( !"No ps_3_0" );
}
}
pShader->Draw();
}