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# include "quakedef.h"
/*
room for improvement :
There is no screen - space culling of lit surfaces .
model meshes are interpolated multiple times per frame
*/
# if defined(RTLIGHTS) && !defined(SERVERONLY)
# ifdef VKQUAKE
# include "../vk/vkrenderer.h"
# endif
# include "glquake.h"
# include "shader.h"
# ifdef D3D9QUAKE
# include "shader.h"
# if !defined(HMONITOR_DECLARED) && (WINVER < 0x0500)
# define HMONITOR_DECLARED
DECLARE_HANDLE ( HMONITOR ) ;
# endif
# include <d3d9.h>
extern LPDIRECT3DDEVICE9 pD3DDev9 ;
void D3D9BE_Cull ( unsigned int sflags ) ;
void D3D9BE_RenderShadowBuffer ( unsigned int numverts , IDirect3DVertexBuffer9 * vbuf , unsigned int numindicies , IDirect3DIndexBuffer9 * ibuf ) ;
# endif
# ifdef D3D11QUAKE
void D3D11BE_GenerateShadowBuffer ( void * * vbuf , vecV_t * verts , int numverts , void * * ibuf , index_t * indicies , int numindicies ) ;
void D3D11BE_RenderShadowBuffer ( unsigned int numverts , void * vbuf , unsigned int numindicies , void * ibuf ) ;
void D3D11_DestroyShadowBuffer ( void * vbuf , void * ibuf ) ;
void D3D11BE_DoneShadows ( void ) ;
# endif
# ifdef VKQUAKE
# endif
void GLBE_RenderShadowBuffer ( unsigned int numverts , int vbo , vecV_t * verts , unsigned numindicies , int ibo , index_t * indicies ) ;
static void SHM_Shutdown ( void ) ;
# define SHADOWMAP_SIZE 512
# define PROJECTION_DISTANCE (float)(dl->radius*2) //0x7fffffff
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# ifdef BEF_PUSHDEPTH
extern qboolean r_pushdepth ;
# endif
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texid_t crepuscular_texture_id ;
fbostate_t crepuscular_fbo ;
shader_t * crepuscular_shader ;
cvar_t r_shadow_shadowmapping_nearclip = CVAR ( " r_shadow_shadowmapping_nearclip " , " 1 " ) ;
cvar_t r_shadow_shadowmapping_bias = CVAR ( " r_shadow_shadowmapping_bias " , " 0.03 " ) ;
cvar_t r_shadow_scissor = CVARD ( " r_shadow_scissor " , " 1 " , " constrains stencil shadows to the onscreen box that contains the maxmium extents of the light. This avoids unnecessary work. " ) ;
cvar_t r_shadow_realtime_world = CVARFD ( " r_shadow_realtime_world " , " 0 " , CVAR_ARCHIVE , " Enables the use of static/world realtime lights. " ) ;
cvar_t r_shadow_realtime_world_shadows = CVARF ( " r_shadow_realtime_world_shadows " , " 1 " , CVAR_ARCHIVE ) ;
cvar_t r_shadow_realtime_world_lightmaps = CVARFD ( " r_shadow_realtime_world_lightmaps " , " 0 " , 0 , " Specifies how much of the map's normal lightmap to retain when using world realtime lights. 0 completely replaces lighting. " ) ;
cvar_t r_shadow_realtime_dlight = CVARFD ( " r_shadow_realtime_dlight " , " 1 " , CVAR_ARCHIVE , " Enables the use of dynamic realtime lights, allowing explosions to use bumpmaps etc properly. " ) ;
cvar_t r_shadow_realtime_dlight_shadows = CVARFD ( " r_shadow_realtime_dlight_shadows " , " 1 " , CVAR_ARCHIVE , " Allows dynamic realtime lights to cast shadows as they move. " ) ;
cvar_t r_shadow_realtime_dlight_ambient = CVAR ( " r_shadow_realtime_dlight_ambient " , " 0 " ) ;
cvar_t r_shadow_realtime_dlight_diffuse = CVAR ( " r_shadow_realtime_dlight_diffuse " , " 1 " ) ;
cvar_t r_shadow_realtime_dlight_specular = CVAR ( " r_shadow_realtime_dlight_specular " , " 4 " ) ; //excessive, but noticable. its called stylized, okay? shiesh, some people
cvar_t r_editlights_import_radius = CVAR ( " r_editlights_import_radius " , " 1 " ) ;
cvar_t r_editlights_import_ambient = CVAR ( " r_editlights_import_ambient " , " 0 " ) ;
cvar_t r_editlights_import_diffuse = CVAR ( " r_editlights_import_diffuse " , " 1 " ) ;
cvar_t r_editlights_import_specular = CVAR ( " r_editlights_import_specular " , " 1 " ) ; //excessive, but noticable. its called stylized, okay? shiesh, some people
cvar_t r_shadow_playershadows = CVARD ( " r_shadow_playershadows " , " 1 " , " Controls the presence of shadows on the local player. " ) ;
cvar_t r_shadow_shadowmapping = CVARD ( " r_shadow_shadowmapping " , " 1 " , " Enables soft shadows instead of stencil shadows. " ) ;
cvar_t r_shadow_shadowmapping_precision = CVARD ( " r_shadow_shadowmapping_precision " , " 1 " , " Scales the shadowmap detail level up or down. " ) ;
extern cvar_t r_shadow_shadowmapping_nearclip ;
extern cvar_t r_shadow_shadowmapping_bias ;
cvar_t r_sun_dir = CVARD ( " r_sun_dir " , " 0.2 0.5 0.8 " , " Specifies the direction that crepusular rays appear along " ) ;
cvar_t r_sun_colour = CVARFD ( " r_sun_colour " , " 0 0 0 " , CVAR_ARCHIVE , " Specifies the colour of sunlight that appears in the form of crepuscular rays. " ) ;
static void Sh_DrawEntLighting ( dlight_t * light , vec3_t colour ) ;
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static pvsbuffer_t lvisb , lvisb2 ;
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/*
called on framebuffer resize .
flushes textures so they can be regenerated at the real size
*/
void Sh_Reset ( void )
{
# ifdef GLQUAKE
if ( crepuscular_texture_id )
{
Image_DestroyTexture ( crepuscular_texture_id ) ;
crepuscular_texture_id = r_nulltex ;
}
GLBE_FBO_Destroy ( & crepuscular_fbo ) ;
# endif
}
void Sh_Shutdown ( void )
{
Sh_Reset ( ) ;
SHM_Shutdown ( ) ;
}
typedef struct {
unsigned int count ;
unsigned int max ;
texture_t * tex ;
vbo_t * vbo ;
mesh_t * * s ;
} shadowmeshbatch_t ;
typedef struct shadowmesh_s
{
enum
{
SMT_STENCILVOLUME , //build edges mesh (and surface list)
SMT_SHADOWMAP , //build front faces mesh (and surface list)
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SMT_ORTHO , //bounded by a box and with a single direction rather than an origin.
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SMT_SHADOWLESS , //build vis+surface list only
SMT_DEFERRED //build vis without caring about any surfaces at all.
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} type ;
unsigned int numindicies ;
unsigned int maxindicies ;
index_t * indicies ;
unsigned int numverts ;
unsigned int maxverts ;
vecV_t * verts ;
//we also have a list of all the surfaces that this light lights.
unsigned int numbatches ;
shadowmeshbatch_t * batches ;
unsigned int leafbytes ;
unsigned char * litleaves ;
# ifdef VKQUAKE
struct vk_shadowbuffer * vkbuffer ;
# endif
# ifdef GLQUAKE
GLuint vebo [ 2 ] ;
# endif
# ifdef D3D9QUAKE
IDirect3DVertexBuffer9 * d3d9_vbuffer ;
IDirect3DIndexBuffer9 * d3d9_ibuffer ;
# endif
# ifdef D3D11QUAKE
void * d3d11_vbuffer ;
void * d3d11_ibuffer ;
# endif
} shadowmesh_t ;
/*state of the current shadow mesh*/
# define inc 128
int sh_shadowframe ;
static int sh_firstindex ;
static int sh_vertnum ; //vertex number (set to 0 at SH_Begin)
static shadowmesh_t * sh_shmesh , sh_tempshmesh ;
/* functions to add geometry to the shadow mesh */
static void SHM_BeginQuads ( void )
{
sh_firstindex = sh_shmesh - > numverts ;
}
static void SHM_End ( void )
{
int i ;
i = ( sh_shmesh - > numindicies + ( sh_vertnum / 4 ) * 6 + inc + 5 ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxindicies ! = i )
{
sh_shmesh - > maxindicies = i ;
sh_shmesh - > indicies = BZ_Realloc ( sh_shmesh - > indicies , i * sizeof ( * sh_shmesh - > indicies ) ) ;
}
//add the extra triangles
for ( i = 0 ; i < sh_vertnum ; i + = 4 )
{
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 2 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 2 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = sh_firstindex + i + 3 ;
}
sh_vertnum = 0 ;
}
static void SHM_Vertex3fv ( const float * v )
{
int i ;
//add the verts as we go
i = ( sh_shmesh - > numverts + inc + 5 ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxverts < i )
{
sh_shmesh - > maxverts = i ;
sh_shmesh - > verts = BZ_Realloc ( sh_shmesh - > verts , i * sizeof ( * sh_shmesh - > verts ) ) ;
}
sh_shmesh - > verts [ sh_shmesh - > numverts ] [ 0 ] = v [ 0 ] ;
sh_shmesh - > verts [ sh_shmesh - > numverts ] [ 1 ] = v [ 1 ] ;
sh_shmesh - > verts [ sh_shmesh - > numverts ] [ 2 ] = v [ 2 ] ;
sh_vertnum + + ;
sh_shmesh - > numverts + + ;
if ( sh_vertnum = = 4 )
{
SHM_End ( ) ;
sh_firstindex = sh_shmesh - > numverts ;
}
}
static void SHM_MeshFrontOnly ( int numverts , vecV_t * verts , int numidx , index_t * idx )
{
int first = sh_shmesh - > numverts ;
int v , i ;
vecV_t * outv ;
index_t * outi ;
/*make sure there's space*/
v = ( sh_shmesh - > numverts + numverts + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxverts < v )
{
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v * = 2 ;
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v + = 1024 ;
sh_shmesh - > maxverts = v ;
sh_shmesh - > verts = BZ_Realloc ( sh_shmesh - > verts , v * sizeof ( * sh_shmesh - > verts ) ) ;
}
outv = sh_shmesh - > verts + sh_shmesh - > numverts ;
for ( v = 0 ; v < numverts ; v + + )
{
VectorCopy ( verts [ v ] , outv [ v ] ) ;
}
v = ( sh_shmesh - > numindicies + numidx + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxindicies < v )
{
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v * = 2 ;
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v + = 1024 ;
sh_shmesh - > maxindicies = v ;
sh_shmesh - > indicies = BZ_Realloc ( sh_shmesh - > indicies , v * sizeof ( * sh_shmesh - > indicies ) ) ;
}
outi = sh_shmesh - > indicies + sh_shmesh - > numindicies ;
for ( i = 0 ; i < numidx ; i + + )
{
outi [ i ] = first + idx [ i ] ;
}
sh_shmesh - > numverts + = numverts ;
sh_shmesh - > numindicies + = numidx ;
}
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#if 0
static void SHM_MeshBackOnly ( int numverts , vecV_t * verts , int numidx , index_t * idx )
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{
int first = sh_shmesh - > numverts ;
int v , i ;
vecV_t * outv ;
index_t * outi ;
/*make sure there's space*/
v = ( sh_shmesh - > numverts + numverts + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxverts < v )
{
v + = 1024 ;
sh_shmesh - > maxverts = v ;
sh_shmesh - > verts = BZ_Realloc ( sh_shmesh - > verts , v * sizeof ( * sh_shmesh - > verts ) ) ;
}
outv = sh_shmesh - > verts + sh_shmesh - > numverts ;
for ( v = 0 ; v < numverts ; v + + )
{
VectorCopy ( verts [ v ] , outv [ v ] ) ;
}
v = ( sh_shmesh - > numindicies + numidx + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxindicies < v )
{
v + = 1024 ;
sh_shmesh - > maxindicies = v ;
sh_shmesh - > indicies = BZ_Realloc ( sh_shmesh - > indicies , v * sizeof ( * sh_shmesh - > indicies ) ) ;
}
outi = sh_shmesh - > indicies + sh_shmesh - > numindicies ;
for ( i = 0 ; i < numidx ; i + = 3 )
{
outi [ i + 0 ] = first + idx [ i + 2 ] ;
outi [ i + 1 ] = first + idx [ i + 1 ] ;
outi [ i + 2 ] = first + idx [ i + 0 ] ;
}
sh_shmesh - > numverts + = numverts ;
sh_shmesh - > numindicies + = numidx ;
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}
# endif
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static void SHM_TriangleFan ( int numverts , vecV_t * verts , vec3_t lightorg , float pd )
{
int v , i , idxs ;
float * v1 ;
vec3_t v3 ;
vecV_t * outv ;
index_t * outi ;
/*make sure there's space*/
v = ( sh_shmesh - > numverts + numverts * 2 + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxverts < v )
{
v + = 1024 ;
sh_shmesh - > maxverts = v ;
sh_shmesh - > verts = BZ_Realloc ( sh_shmesh - > verts , v * sizeof ( * sh_shmesh - > verts ) ) ;
}
outv = sh_shmesh - > verts + sh_shmesh - > numverts ;
for ( v = 0 ; v < numverts ; v + + )
{
v1 = verts [ v ] ;
VectorCopy ( v1 , outv [ v ] ) ;
v3 [ 0 ] = ( v1 [ 0 ] - lightorg [ 0 ] ) * pd ;
v3 [ 1 ] = ( v1 [ 1 ] - lightorg [ 1 ] ) * pd ;
v3 [ 2 ] = ( v1 [ 2 ] - lightorg [ 2 ] ) * pd ;
outv [ v + numverts ] [ 0 ] = v1 [ 0 ] + v3 [ 0 ] ;
outv [ v + numverts ] [ 1 ] = v1 [ 1 ] + v3 [ 1 ] ;
outv [ v + numverts ] [ 2 ] = v1 [ 2 ] + v3 [ 2 ] ;
}
idxs = ( numverts - 2 ) * 3 ;
/*now add the verts in a fan*/
v = ( sh_shmesh - > numindicies + idxs * 2 + inc ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxindicies < v )
{
v + = 1024 ;
sh_shmesh - > maxindicies = v ;
sh_shmesh - > indicies = BZ_Realloc ( sh_shmesh - > indicies , v * sizeof ( * sh_shmesh - > indicies ) ) ;
}
outi = sh_shmesh - > indicies + sh_shmesh - > numindicies ;
for ( v = 2 , i = 0 ; v < numverts ; v + + , i + = 3 )
{
outi [ i + 0 ] = sh_shmesh - > numverts ;
outi [ i + 1 ] = sh_shmesh - > numverts + v - 1 ;
outi [ i + 2 ] = sh_shmesh - > numverts + v ;
outi [ i + 0 + idxs ] = sh_shmesh - > numverts + numverts + v ;
outi [ i + 1 + idxs ] = sh_shmesh - > numverts + numverts + v - 1 ;
outi [ i + 2 + idxs ] = sh_shmesh - > numverts + numverts ;
}
/*we added this many*/
sh_shmesh - > numverts + = numverts * 2 ;
sh_shmesh - > numindicies + = i * 2 ;
}
static void SHM_Shadow_Cache_Surface ( msurface_t * surf )
{
int i ;
i = surf - > sbatch - > shadowbatch ;
if ( i < 0 )
return ;
if ( sh_shmesh - > batches [ i ] . count = = sh_shmesh - > batches [ i ] . max )
{
sh_shmesh - > batches [ i ] . max + = 64 ;
sh_shmesh - > batches [ i ] . s = BZ_Realloc ( sh_shmesh - > batches [ i ] . s , sizeof ( void * ) * ( sh_shmesh - > batches [ i ] . max ) ) ;
}
sh_shmesh - > batches [ i ] . s [ sh_shmesh - > batches [ i ] . count ] = surf - > mesh ;
sh_shmesh - > batches [ i ] . count + + ;
}
static void SHM_Shadow_Cache_Leaf ( mleaf_t * leaf )
{
int i ;
i = ( leaf - cl . worldmodel - > leafs ) - 1 ;
sh_shmesh - > litleaves [ i > > 3 ] | = 1 < < ( i & 7 ) ;
}
static void SH_FreeShadowMesh_ ( shadowmesh_t * sm )
{
unsigned int i ;
for ( i = 0 ; i < sm - > numbatches ; i + + )
Z_Free ( sm - > batches [ i ] . s ) ;
sm - > numbatches = 0 ;
Z_Free ( sm - > batches ) ;
sm - > batches = NULL ;
Z_Free ( sm - > indicies ) ;
sm - > indicies = NULL ;
Z_Free ( sm - > verts ) ;
sm - > verts = NULL ;
sm - > numindicies = 0 ;
sm - > numverts = 0 ;
switch ( qrenderer )
{
case QR_NONE :
case QR_SOFTWARE :
default :
break ;
# ifdef GLQUAKE
case QR_OPENGL :
if ( qglDeleteBuffersARB )
qglDeleteBuffersARB ( 2 , sm - > vebo ) ;
sm - > vebo [ 0 ] = 0 ;
sm - > vebo [ 1 ] = 0 ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
VKBE_DestroyShadowBuffer ( sm - > vkbuffer ) ;
sm - > vkbuffer = NULL ;
break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
if ( sm - > d3d9_ibuffer )
IDirect3DIndexBuffer9_Release ( sm - > d3d9_ibuffer ) ;
sm - > d3d9_ibuffer = NULL ;
if ( sm - > d3d9_vbuffer )
IDirect3DVertexBuffer9_Release ( sm - > d3d9_vbuffer ) ;
sm - > d3d9_vbuffer = NULL ;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
D3D11_DestroyShadowBuffer ( sm - > d3d11_vbuffer , sm - > d3d11_ibuffer ) ;
sm - > d3d11_vbuffer = NULL ;
sm - > d3d11_ibuffer = NULL ;
break ;
# endif
}
}
void SH_FreeShadowMesh ( shadowmesh_t * sm )
{
SH_FreeShadowMesh_ ( sm ) ;
Z_Free ( sm ) ;
}
static void SH_CalcShadowBatches ( model_t * mod )
{
int s ;
batch_t * b ;
batch_t * l = NULL ;
int sb ;
l = NULL ;
for ( s = 0 ; s < SHADER_SORT_COUNT ; s + + )
{
for ( b = mod - > batches [ s ] ; b ; b = b - > next )
{
if ( ! l | | l - > vbo ! = b - > vbo | | l - > texture ! = b - > texture )
{
b - > shadowbatch = mod - > numshadowbatches + + ;
l = b ;
}
else
b - > shadowbatch = l - > shadowbatch ;
}
}
if ( ! mod - > numshadowbatches )
mod - > shadowbatches = NULL ;
else
{
l = NULL ;
sb = 0 ;
mod - > shadowbatches = BZ_Malloc ( sizeof ( * mod - > shadowbatches ) * mod - > numshadowbatches ) ;
for ( s = 0 ; s < SHADER_SORT_COUNT ; s + + )
{
for ( b = mod - > batches [ s ] ; b ; b = b - > next )
{
if ( ! l | | l - > vbo ! = b - > vbo | | l - > texture ! = b - > texture )
{
mod - > shadowbatches [ sb ] . tex = b - > texture ;
mod - > shadowbatches [ sb ] . vbo = b - > vbo ;
sb + + ;
l = b ;
}
}
}
}
}
static void SHM_BeginShadowMesh ( dlight_t * dl , int type )
{
unsigned int i ;
unsigned int lb ;
sh_vertnum = 0 ;
lb = ( cl . worldmodel - > numclusters + 7 ) / 8 ;
if ( ! dl - > die | | ! dl - > key )
{
sh_shmesh = dl - > worldshadowmesh ;
if ( ! sh_shmesh | | sh_shmesh - > leafbytes ! = lb )
{
/*this shouldn't happen too often*/
if ( sh_shmesh )
{ //FIXME: if the light is the same light, reuse the memory allocations where possible...
SH_FreeShadowMesh ( sh_shmesh ) ;
}
/*Create a new shadowmesh for this light*/
sh_shmesh = Z_Malloc ( sizeof ( * sh_shmesh ) + lb ) ;
sh_shmesh - > leafbytes = lb ;
sh_shmesh - > litleaves = ( unsigned char * ) ( sh_shmesh + 1 ) ;
dl - > worldshadowmesh = sh_shmesh ;
}
memset ( sh_shmesh - > litleaves , 0 , sh_shmesh - > leafbytes ) ;
dl - > rebuildcache = false ;
}
else
{
sh_shmesh = & sh_tempshmesh ;
if ( sh_shmesh - > leafbytes ! = lb )
{
/*this happens on map changes*/
sh_shmesh - > leafbytes = lb ;
Z_Free ( sh_shmesh - > litleaves ) ;
sh_shmesh - > litleaves = Z_Malloc ( lb ) ;
}
}
sh_shmesh - > maxverts = 0 ;
sh_shmesh - > numverts = 0 ;
sh_shmesh - > maxindicies = 0 ;
sh_shmesh - > numindicies = 0 ;
sh_shmesh - > type = type ;
if ( ! cl . worldmodel - > numshadowbatches )
{
SH_CalcShadowBatches ( cl . worldmodel ) ;
}
if ( sh_shmesh - > numbatches ! = cl . worldmodel - > numshadowbatches )
{
if ( sh_shmesh - > batches )
{
for ( i = 0 ; i < sh_shmesh - > numbatches ; i + + )
Z_Free ( sh_shmesh - > batches [ i ] . s ) ;
Z_Free ( sh_shmesh - > batches ) ;
}
sh_shmesh - > batches = Z_Malloc ( sizeof ( shadowmeshbatch_t ) * cl . worldmodel - > numshadowbatches ) ;
sh_shmesh - > numbatches = cl . worldmodel - > numshadowbatches ;
}
for ( i = 0 ; i < sh_shmesh - > numbatches ; i + + )
{
sh_shmesh - > batches [ i ] . count = 0 ;
}
}
static struct shadowmesh_s * SHM_FinishShadowMesh ( dlight_t * dl )
{
if ( sh_shmesh ! = & sh_tempshmesh | | 1 )
{
switch ( qrenderer )
{
case QR_NONE :
case QR_SOFTWARE :
default :
break ;
# ifdef GLQUAKE
case QR_OPENGL :
if ( ! qglGenBuffersARB )
return sh_shmesh ;
if ( ! sh_shmesh - > vebo [ 0 ] )
qglGenBuffersARB ( 2 , sh_shmesh - > vebo ) ;
GL_DeselectVAO ( ) ;
GL_SelectVBO ( sh_shmesh - > vebo [ 0 ] ) ;
qglBufferDataARB ( GL_ARRAY_BUFFER_ARB , sizeof ( * sh_shmesh - > verts ) * sh_shmesh - > numverts , sh_shmesh - > verts , GL_STATIC_DRAW_ARB ) ;
GL_SelectEBO ( sh_shmesh - > vebo [ 1 ] ) ;
qglBufferDataARB ( GL_ELEMENT_ARRAY_BUFFER_ARB , sizeof ( * sh_shmesh - > indicies ) * sh_shmesh - > numindicies , sh_shmesh - > indicies , GL_STATIC_DRAW_ARB ) ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
VKBE_DestroyShadowBuffer ( sh_shmesh - > vkbuffer ) ;
sh_shmesh - > vkbuffer = VKBE_GenerateShadowBuffer ( sh_shmesh - > verts , sh_shmesh - > numverts , sh_shmesh - > indicies , sh_shmesh - > numindicies , sh_shmesh = = & sh_tempshmesh ) ;
break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
if ( sh_shmesh - > numindicies & & sh_shmesh - > numverts )
{
void * map ;
IDirect3DDevice9_CreateIndexBuffer ( pD3DDev9 , sizeof ( index_t ) * sh_shmesh - > numindicies , 0 , D3DFMT_QINDEX , D3DPOOL_MANAGED , & sh_shmesh - > d3d9_ibuffer , NULL ) ;
IDirect3DIndexBuffer9_Lock ( sh_shmesh - > d3d9_ibuffer , 0 , sizeof ( index_t ) * sh_shmesh - > numindicies , & map , D3DLOCK_DISCARD ) ;
memcpy ( map , sh_shmesh - > indicies , sizeof ( index_t ) * sh_shmesh - > numindicies ) ;
IDirect3DIndexBuffer9_Unlock ( sh_shmesh - > d3d9_ibuffer ) ;
IDirect3DDevice9_CreateVertexBuffer ( pD3DDev9 , sizeof ( vecV_t ) * sh_shmesh - > numverts , D3DUSAGE_WRITEONLY , 0 , D3DPOOL_MANAGED , & sh_shmesh - > d3d9_vbuffer , NULL ) ;
IDirect3DVertexBuffer9_Lock ( sh_shmesh - > d3d9_vbuffer , 0 , sizeof ( vecV_t ) * sh_shmesh - > numverts , & map , D3DLOCK_DISCARD ) ;
memcpy ( map , sh_shmesh - > verts , sizeof ( vecV_t ) * sh_shmesh - > numverts ) ;
IDirect3DVertexBuffer9_Unlock ( sh_shmesh - > d3d9_vbuffer ) ;
}
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
D3D11BE_GenerateShadowBuffer ( & sh_shmesh - > d3d11_vbuffer , sh_shmesh - > verts , sh_shmesh - > numverts , & sh_shmesh - > d3d11_ibuffer , sh_shmesh - > indicies , sh_shmesh - > numindicies ) ;
break ;
# endif
}
Z_Free ( sh_shmesh - > verts ) ;
sh_shmesh - > verts = NULL ;
Z_Free ( sh_shmesh - > indicies ) ;
sh_shmesh - > indicies = NULL ;
}
return sh_shmesh ;
}
/*state of the world that is still to compile*/
static struct {
short count ;
short count2 ;
int next ;
int prev ;
} * edge ;
static int firstedge ;
static int maxedge ;
static void SHM_RecursiveWorldNodeQ1_r ( dlight_t * dl , mnode_t * node )
{
int c , side ;
mplane_t * plane ;
msurface_t * surf , * * mark ;
mleaf_t * pleaf ;
double dot ;
int v ;
float l , maxdist ;
int j , s , t ;
vec3_t impact ;
if ( node - > shadowframe ! = sh_shadowframe )
return ;
if ( node - > contents = = Q1CONTENTS_SOLID )
return ; // solid
//if light areabox is outside node, ignore node + children
for ( c = 0 ; c < 3 ; c + + )
{
if ( dl - > origin [ c ] + dl - > radius < node - > minmaxs [ c ] )
return ;
if ( dl - > origin [ c ] - dl - > radius > node - > minmaxs [ 3 + c ] )
return ;
}
// if a leaf node, draw stuff
if ( node - > contents < 0 )
{
pleaf = ( mleaf_t * ) node ;
SHM_Shadow_Cache_Leaf ( pleaf ) ;
2017-10-31 22:52:58 +00:00
if ( sh_shmesh - > type = = SMT_DEFERRED ) //such rtlights don't need ANY surface info, just a tight pvs
return ;
2016-07-12 00:40:13 +00:00
mark = pleaf - > firstmarksurface ;
c = pleaf - > nummarksurfaces ;
if ( c )
{
do
{
( * mark + + ) - > shadowframe = sh_shadowframe ;
} while ( - - c ) ;
}
return ;
}
// node is just a decision point, so go down the apropriate sides
// find which side of the node we are on
plane = node - > plane ;
switch ( plane - > type )
{
case PLANE_X :
dot = dl - > origin [ 0 ] - plane - > dist ;
break ;
case PLANE_Y :
dot = dl - > origin [ 1 ] - plane - > dist ;
break ;
case PLANE_Z :
dot = dl - > origin [ 2 ] - plane - > dist ;
break ;
default :
dot = DotProduct ( dl - > origin , plane - > normal ) - plane - > dist ;
break ;
}
if ( dot > = 0 )
side = 0 ;
else
side = 1 ;
// recurse down the children, front side first
SHM_RecursiveWorldNodeQ1_r ( dl , node - > children [ side ] ) ;
// draw stuff
c = node - > numsurfaces ;
if ( c )
{
surf = cl . worldmodel - > surfaces + node - > firstsurface ;
{
maxdist = dl - > radius * dl - > radius ;
for ( ; c ; c - - , surf + + )
{
if ( surf - > shadowframe ! = sh_shadowframe )
continue ;
// if ((dot < 0) ^ !!(surf->flags & SURF_PLANEBACK))
// continue; // wrong side
// if (surf->flags & SURF_PLANEBACK)
// continue;
if ( surf - > flags & ( SURF_DRAWALPHA | SURF_DRAWTILED ) )
{ // no shadows
continue ;
}
//is the light on the right side?
if ( surf - > flags & SURF_PLANEBACK )
{ //inverted normal.
if ( - DotProduct ( surf - > plane - > normal , dl - > origin ) + surf - > plane - > dist > = dl - > radius )
continue ;
}
else
{
if ( DotProduct ( surf - > plane - > normal , dl - > origin ) - surf - > plane - > dist > = dl - > radius )
continue ;
}
//Yeah, you can blame LordHavoc for this alternate code here.
for ( j = 0 ; j < 3 ; j + + )
impact [ j ] = dl - > origin [ j ] - surf - > plane - > normal [ j ] * dot ;
// clamp center of light to corner and check brightness
l = DotProduct ( impact , surf - > texinfo - > vecs [ 0 ] ) + surf - > texinfo - > vecs [ 0 ] [ 3 ] - surf - > texturemins [ 0 ] ;
s = l + 0.5 ; if ( s < 0 ) s = 0 ; else if ( s > surf - > extents [ 0 ] ) s = surf - > extents [ 0 ] ;
s = ( l - s ) * surf - > texinfo - > vecscale [ 0 ] ;
l = DotProduct ( impact , surf - > texinfo - > vecs [ 1 ] ) + surf - > texinfo - > vecs [ 1 ] [ 3 ] - surf - > texturemins [ 1 ] ;
t = l + 0.5 ; if ( t < 0 ) t = 0 ; else if ( t > surf - > extents [ 1 ] ) t = surf - > extents [ 1 ] ;
t = ( l - t ) * surf - > texinfo - > vecscale [ 1 ] ;
// compare to minimum light
if ( ( s * s + t * t + dot * dot ) < maxdist )
{
SHM_Shadow_Cache_Surface ( surf ) ;
if ( sh_shmesh - > type = = SMT_SHADOWMAP )
{
SHM_MeshFrontOnly ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , surf - > mesh - > numindexes , surf - > mesh - > indexes ) ;
continue ;
}
if ( sh_shmesh - > type ! = SMT_STENCILVOLUME )
continue ;
//build a list of the edges that are to be drawn.
for ( v = 0 ; v < surf - > numedges ; v + + )
{
int e , delta ;
e = cl . worldmodel - > surfedges [ surf - > firstedge + v ] ;
//negative edge means backwards edge.
if ( e < 0 )
{
e = - e ;
delta = - 1 ;
}
else
{
delta = 1 ;
}
if ( ! edge [ e ] . count )
{
if ( firstedge )
edge [ firstedge ] . prev = e ;
edge [ e ] . next = firstedge ;
edge [ e ] . prev = 0 ;
firstedge = e ;
edge [ e ] . count = delta ;
}
else
{
edge [ e ] . count + = delta ;
if ( ! edge [ e ] . count ) //unlink
{
if ( edge [ e ] . next )
{
edge [ edge [ e ] . next ] . prev = edge [ e ] . prev ;
}
if ( edge [ e ] . prev )
edge [ edge [ e ] . prev ] . next = edge [ e ] . next ;
else
firstedge = edge [ e ] . next ;
}
}
}
SHM_TriangleFan ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , dl - > origin , PROJECTION_DISTANCE ) ;
}
}
}
}
// recurse down the back side
SHM_RecursiveWorldNodeQ1_r ( dl , node - > children [ ! side ] ) ;
}
2018-07-22 11:49:37 +00:00
void CategorizePlane ( mplane_t * plane ) ;
static void SHM_OrthoWorldLeafsQ1 ( dlight_t * dl )
{
int c , i ;
msurface_t * surf , * * mark ;
mleaf_t * pleaf , * plastleaf ;
float dot ;
mplane_t orthoplanes [ 5 ] ;
sh_shadowframe + + ;
VectorCopy ( dl - > axis [ 0 ] , orthoplanes [ 0 ] . normal ) ;
VectorNegate ( dl - > axis [ 0 ] , orthoplanes [ 1 ] . normal ) ;
VectorCopy ( dl - > axis [ 1 ] , orthoplanes [ 2 ] . normal ) ;
VectorNegate ( dl - > axis [ 1 ] , orthoplanes [ 3 ] . normal ) ;
VectorNegate ( dl - > axis [ 0 ] , orthoplanes [ 4 ] . normal ) ;
for ( i = 0 ; i < countof ( orthoplanes ) ; i + + )
{
orthoplanes [ i ] . dist = DotProduct ( dl - > origin , orthoplanes [ i ] . normal ) - dl - > radius ;
CategorizePlane ( & orthoplanes [ i ] ) ;
}
for ( pleaf = cl . worldmodel - > leafs + 1 , plastleaf = cl . worldmodel - > leafs + cl . worldmodel - > submodels [ 0 ] . visleafs ; pleaf < = plastleaf ; pleaf + + )
{
for ( i = 0 ; i < countof ( orthoplanes ) ; i + + )
if ( BOX_ON_PLANE_SIDE ( pleaf - > minmaxs , pleaf - > minmaxs + 3 , & orthoplanes [ i ] ) = = 2 )
goto next ;
SHM_Shadow_Cache_Leaf ( pleaf ) ;
mark = pleaf - > firstmarksurface ;
c = pleaf - > nummarksurfaces ;
while ( c - - > 0 )
{
surf = * mark + + ;
if ( surf - > flags & ( SURF_DRAWALPHA | SURF_DRAWTILED | SURF_DRAWSKY ) )
continue ;
if ( surf - > shadowframe ! = sh_shadowframe )
{
surf - > shadowframe = sh_shadowframe ;
dot = DotProduct ( surf - > plane - > normal , dl - > axis [ 0 ] ) ;
if ( surf - > flags & SURF_PLANEBACK )
dot = - dot ;
if ( dot < 0 )
{
SHM_Shadow_Cache_Surface ( surf ) ;
}
// else
// SHM_MeshBackOnly(surf->mesh->numvertexes, surf->mesh->xyz_array, surf->mesh->numindexes, surf->mesh->indexes);
SHM_MeshFrontOnly ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , surf - > mesh - > numindexes , surf - > mesh - > indexes ) ;
}
}
next : ;
}
}
static void SHM_OrthoWorldLeafsQ3 ( dlight_t * dl )
{
int c , i ;
msurface_t * surf , * * mark ;
mleaf_t * pleaf , * plastleaf ;
mplane_t orthoplanes [ 5 ] ;
sh_shadowframe + + ;
VectorCopy ( dl - > axis [ 0 ] , orthoplanes [ 0 ] . normal ) ;
VectorNegate ( dl - > axis [ 0 ] , orthoplanes [ 1 ] . normal ) ;
VectorCopy ( dl - > axis [ 1 ] , orthoplanes [ 2 ] . normal ) ;
VectorNegate ( dl - > axis [ 1 ] , orthoplanes [ 3 ] . normal ) ;
VectorNegate ( dl - > axis [ 0 ] , orthoplanes [ 4 ] . normal ) ;
for ( i = 0 ; i < countof ( orthoplanes ) ; i + + )
{
orthoplanes [ i ] . dist = DotProduct ( dl - > origin , orthoplanes [ i ] . normal ) - dl - > radius ;
CategorizePlane ( & orthoplanes [ i ] ) ;
}
for ( pleaf = cl . worldmodel - > leafs + 1 , plastleaf = cl . worldmodel - > leafs + cl . worldmodel - > numleafs ; pleaf < = plastleaf ; pleaf + + )
{
for ( i = 0 ; i < countof ( orthoplanes ) ; i + + )
if ( BOX_ON_PLANE_SIDE ( pleaf - > minmaxs , pleaf - > minmaxs + 3 , & orthoplanes [ i ] ) = = 2 )
goto next ;
SHM_Shadow_Cache_Leaf ( pleaf ) ;
mark = pleaf - > firstmarksurface ;
c = pleaf - > nummarksurfaces ;
while ( c - - > 0 )
{
surf = * mark + + ;
if ( surf - > flags & ( SURF_DRAWALPHA | SURF_DRAWTILED | SURF_DRAWSKY ) )
continue ;
if ( surf - > shadowframe ! = sh_shadowframe )
{
surf - > shadowframe = sh_shadowframe ;
// if (dot < 0)
{
SHM_Shadow_Cache_Surface ( surf ) ;
}
// else
// SHM_MeshBackOnly(surf->mesh->numvertexes, surf->mesh->xyz_array, surf->mesh->numindexes, surf->mesh->indexes);
SHM_MeshFrontOnly ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , surf - > mesh - > numindexes , surf - > mesh - > indexes ) ;
}
}
next : ;
}
}
2016-07-12 00:40:13 +00:00
# ifdef Q2BSPS
static void SHM_RecursiveWorldNodeQ2_r ( dlight_t * dl , mnode_t * node )
{
int c , side ;
mplane_t * plane ;
msurface_t * surf , * * mark ;
mleaf_t * pleaf ;
double dot ;
int v ;
float l , maxdist ;
int j , s , t ;
vec3_t impact ;
if ( node - > shadowframe ! = sh_shadowframe )
return ;
if ( node - > contents = = Q2CONTENTS_SOLID )
return ; // solid
//if light areabox is outside node, ignore node + children
for ( c = 0 ; c < 3 ; c + + )
{
if ( dl - > origin [ c ] + dl - > radius < node - > minmaxs [ c ] )
return ;
if ( dl - > origin [ c ] - dl - > radius > node - > minmaxs [ 3 + c ] )
return ;
}
// if a leaf node, draw stuff
if ( node - > contents ! = - 1 )
{
pleaf = ( mleaf_t * ) node ;
if ( pleaf - > cluster > = 0 )
sh_shmesh - > litleaves [ pleaf - > cluster > > 3 ] | = 1 < < ( pleaf - > cluster & 7 ) ;
mark = pleaf - > firstmarksurface ;
c = pleaf - > nummarksurfaces ;
if ( c )
{
do
{
( * mark + + ) - > shadowframe = sh_shadowframe ;
} while ( - - c ) ;
}
return ;
}
// node is just a decision point, so go down the apropriate sides
// find which side of the node we are on
plane = node - > plane ;
switch ( plane - > type )
{
case PLANE_X :
dot = dl - > origin [ 0 ] - plane - > dist ;
break ;
case PLANE_Y :
dot = dl - > origin [ 1 ] - plane - > dist ;
break ;
case PLANE_Z :
dot = dl - > origin [ 2 ] - plane - > dist ;
break ;
default :
dot = DotProduct ( dl - > origin , plane - > normal ) - plane - > dist ;
break ;
}
if ( dot > = 0 )
side = 0 ;
else
side = 1 ;
// recurse down the children, front side first
SHM_RecursiveWorldNodeQ2_r ( dl , node - > children [ side ] ) ;
// draw stuff
c = node - > numsurfaces ;
if ( c )
{
surf = cl . worldmodel - > surfaces + node - > firstsurface ;
{
maxdist = dl - > radius * dl - > radius ;
for ( ; c ; c - - , surf + + )
{
if ( surf - > shadowframe ! = sh_shadowframe )
continue ;
// if ((dot < 0) ^ !!(surf->flags & SURF_PLANEBACK))
// continue; // wrong side
// if (surf->flags & SURF_PLANEBACK)
// continue;
if ( surf - > flags & ( SURF_DRAWALPHA | SURF_DRAWTILED ) )
{ // no shadows
continue ;
}
//is the light on the right side?
if ( surf - > flags & SURF_PLANEBACK )
{ //inverted normal.
if ( - DotProduct ( surf - > plane - > normal , dl - > origin ) + surf - > plane - > dist > = dl - > radius )
continue ;
}
else
{
if ( DotProduct ( surf - > plane - > normal , dl - > origin ) - surf - > plane - > dist > = dl - > radius )
continue ;
}
//Yeah, you can blame LordHavoc for this alternate code here.
for ( j = 0 ; j < 3 ; j + + )
impact [ j ] = dl - > origin [ j ] - surf - > plane - > normal [ j ] * dot ;
// clamp center of light to corner and check brightness
l = DotProduct ( impact , surf - > texinfo - > vecs [ 0 ] ) + surf - > texinfo - > vecs [ 0 ] [ 3 ] - surf - > texturemins [ 0 ] ;
s = l ; if ( s < 0 ) s = 0 ; else if ( s > surf - > extents [ 0 ] ) s = surf - > extents [ 0 ] ;
s = ( l - s ) * surf - > texinfo - > vecscale [ 0 ] ;
l = DotProduct ( impact , surf - > texinfo - > vecs [ 1 ] ) + surf - > texinfo - > vecs [ 1 ] [ 3 ] - surf - > texturemins [ 1 ] ;
t = l ; if ( t < 0 ) t = 0 ; else if ( t > surf - > extents [ 1 ] ) t = surf - > extents [ 1 ] ;
t = ( l - t ) * surf - > texinfo - > vecscale [ 1 ] ;
// compare to minimum light
if ( ( s * s + t * t + dot * dot ) < maxdist )
{
SHM_Shadow_Cache_Surface ( surf ) ;
if ( sh_shmesh - > type = = SMT_SHADOWMAP )
{
SHM_MeshFrontOnly ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , surf - > mesh - > numindexes , surf - > mesh - > indexes ) ;
continue ;
}
if ( sh_shmesh - > type ! = SMT_STENCILVOLUME )
continue ;
//build a list of the edges that are to be drawn.
for ( v = 0 ; v < surf - > numedges ; v + + )
{
int e , delta ;
e = cl . worldmodel - > surfedges [ surf - > firstedge + v ] ;
//negative edge means backwards edge.
if ( e < 0 )
{
e = - e ;
delta = - 1 ;
}
else
{
delta = 1 ;
}
if ( ! edge [ e ] . count )
{
if ( firstedge )
edge [ firstedge ] . prev = e ;
edge [ e ] . next = firstedge ;
edge [ e ] . prev = 0 ;
firstedge = e ;
edge [ e ] . count = delta ;
}
else
{
edge [ e ] . count + = delta ;
if ( ! edge [ e ] . count ) //unlink
{
if ( edge [ e ] . next )
{
edge [ edge [ e ] . next ] . prev = edge [ e ] . prev ;
}
if ( edge [ e ] . prev )
edge [ edge [ e ] . prev ] . next = edge [ e ] . next ;
else
firstedge = edge [ e ] . next ;
}
}
}
SHM_TriangleFan ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , dl - > origin , PROJECTION_DISTANCE ) ;
}
}
}
}
// recurse down the back side
SHM_RecursiveWorldNodeQ2_r ( dl , node - > children [ ! side ] ) ;
}
2017-10-31 22:52:58 +00:00
static void SHM_MarkLeavesQ2 ( dlight_t * dl , unsigned char * lvis )
2016-07-12 00:40:13 +00:00
{
mnode_t * node ;
int i ;
mleaf_t * leaf ;
int cluster ;
sh_shadowframe + + ;
if ( ! dl - > die )
{
//static
//variation on mark leaves
for ( i = 0 , leaf = cl . worldmodel - > leafs ; i < cl . worldmodel - > numleafs ; i + + , leaf + + )
{
cluster = leaf - > cluster ;
if ( cluster = = - 1 )
continue ;
2017-10-31 22:52:58 +00:00
if ( lvis [ cluster > > 3 ] & ( 1 < < ( cluster & 7 ) ) )
2016-07-12 00:40:13 +00:00
{
node = ( mnode_t * ) leaf ;
do
{
if ( node - > shadowframe = = sh_shadowframe )
break ;
node - > shadowframe = sh_shadowframe ;
node = node - > parent ;
} while ( node ) ;
}
}
}
else
{
//dynamic lights will be discarded after this frame anyway, so only include leafs that are visible
//variation on mark leaves
for ( i = 0 , leaf = cl . worldmodel - > leafs ; i < cl . worldmodel - > numleafs ; i + + , leaf + + )
{
cluster = leaf - > cluster ;
if ( cluster = = - 1 )
continue ;
2017-10-31 22:52:58 +00:00
if ( lvis [ cluster > > 3 ] & ( 1 < < ( cluster & 7 ) ) )
2016-07-12 00:40:13 +00:00
{
node = ( mnode_t * ) leaf ;
do
{
if ( node - > shadowframe = = sh_shadowframe )
break ;
node - > shadowframe = sh_shadowframe ;
node = node - > parent ;
} while ( node ) ;
}
}
}
}
# endif
static void SHM_MarkLeavesQ1 ( dlight_t * dl , unsigned char * lvis )
{
mnode_t * node ;
int i ;
sh_shadowframe + + ;
if ( ! lvis )
return ;
//variation on mark leaves
for ( i = 0 ; i < cl . worldmodel - > numclusters ; i + + )
{
if ( lvis [ i > > 3 ] & ( 1 < < ( i & 7 ) ) )
{
node = ( mnode_t * ) & cl . worldmodel - > leafs [ i + 1 ] ;
do
{
if ( node - > shadowframe = = sh_shadowframe )
break ;
node - > shadowframe = sh_shadowframe ;
node = node - > parent ;
} while ( node ) ;
}
}
}
# ifdef Q3BSPS
static void SHM_RecursiveWorldNodeQ3_r ( dlight_t * dl , mnode_t * node )
{
mplane_t * splitplane ;
float dist ;
msurface_t * * msurf ;
msurface_t * surf ;
mleaf_t * leaf ;
int i ;
if ( node - > contents ! = - 1 )
{
leaf = ( mleaf_t * ) node ;
if ( leaf - > cluster > = 0 )
sh_shmesh - > litleaves [ leaf - > cluster > > 3 ] | = 1 < < ( leaf - > cluster & 7 ) ;
// mark the polygons
msurf = leaf - > firstmarksurface ;
for ( i = 0 ; i < leaf - > nummarksurfaces ; i + + , msurf + + )
{
surf = * msurf ;
//only check each surface once. it can appear in multiple leafs.
if ( surf - > shadowframe = = sh_shadowframe )
continue ;
surf - > shadowframe = sh_shadowframe ;
//FIXME: radius check
SHM_Shadow_Cache_Surface ( surf ) ;
if ( sh_shmesh - > type = = SMT_SHADOWMAP )
SHM_MeshFrontOnly ( surf - > mesh - > numvertexes , surf - > mesh - > xyz_array , surf - > mesh - > numindexes , surf - > mesh - > indexes ) ;
}
return ;
}
splitplane = node - > plane ;
dist = DotProduct ( dl - > origin , splitplane - > normal ) - splitplane - > dist ;
if ( dist > dl - > radius )
{
SHM_RecursiveWorldNodeQ3_r ( dl , node - > children [ 0 ] ) ;
return ;
}
if ( dist < - dl - > radius )
{
SHM_RecursiveWorldNodeQ3_r ( dl , node - > children [ 1 ] ) ;
return ;
}
SHM_RecursiveWorldNodeQ3_r ( dl , node - > children [ 0 ] ) ;
SHM_RecursiveWorldNodeQ3_r ( dl , node - > children [ 1 ] ) ;
}
# endif
static struct {
unsigned int numtris ;
unsigned int maxtris ;
struct {
signed int edge [ 3 ] ;
} * tris ; /*negative for reverse edge*/
unsigned int numedges ;
unsigned int maxedges ;
struct {
unsigned int vert [ 2 ] ;
} * edges ;
unsigned int numpoints ;
unsigned int maxpoints ;
vec3_t * points ;
unsigned int maxedgeuses ;
int * edgeuses ; /*negative for back sides, so 0 means unused or used equally on both sides*/
} cv ;
static void SHM_Shutdown ( void )
{
SH_FreeShadowMesh_ ( & sh_tempshmesh ) ;
BZ_Free ( sh_tempshmesh . litleaves ) ;
sh_tempshmesh . litleaves = NULL ;
sh_tempshmesh . leafbytes = 0 ;
free ( cv . tris ) ;
free ( cv . edges ) ;
free ( cv . points ) ;
memset ( & cv , 0 , sizeof ( cv ) ) ;
}
2017-02-19 00:15:42 +00:00
# ifdef Q3BSPS
2016-07-12 00:40:13 +00:00
# define VERT_POS_EPSILON (1.0f / 32)
static int SHM_ComposeVolume_FindVert ( float * vert )
{
int i ;
for ( i = 0 ; i < cv . numpoints ; i + + )
{
# if 1
if ( cv . points [ i ] [ 0 ] = = vert [ 0 ] & &
cv . points [ i ] [ 1 ] = = vert [ 1 ] & &
cv . points [ i ] [ 2 ] = = vert [ 2 ] )
# else
vec3_t d ;
d [ 0 ] = cv . points [ i ] [ 0 ] - vert [ 0 ] ;
d [ 1 ] = cv . points [ i ] [ 1 ] - vert [ 1 ] ;
d [ 2 ] = cv . points [ i ] [ 2 ] - vert [ 2 ] ;
if ( d [ 0 ] * d [ 0 ] < VERT_POS_EPSILON & &
d [ 1 ] * d [ 1 ] < VERT_POS_EPSILON & &
d [ 2 ] * d [ 2 ] < VERT_POS_EPSILON )
# endif
return i ;
}
VectorCopy ( vert , cv . points [ i ] ) ;
cv . numpoints + + ;
return i ;
}
static int SHM_ComposeVolume_FindEdge ( int v1 , int v2 )
{
int i ;
for ( i = 0 ; i < cv . numedges ; i + + )
{
if ( cv . edges [ i ] . vert [ 0 ] = = v1 & & cv . edges [ i ] . vert [ 1 ] = = v2 )
return i ;
if ( cv . edges [ i ] . vert [ 0 ] = = v2 & & cv . edges [ i ] . vert [ 1 ] = = v1 )
return - ( i + 1 ) ;
}
cv . edges [ i ] . vert [ 0 ] = v1 ;
cv . edges [ i ] . vert [ 1 ] = v2 ;
cv . numedges + + ;
return i ;
}
/*each triangle is coplanar, and all face the light, and its a triangle fan. this is a special case that provides a slight speedup*/
static void SHM_ComposeVolume_Fan ( vecV_t * points , int numpoints )
{
int newmax ;
int lastedge ;
int i ;
# define MAX_ARRAY_VERTS 65535
static index_t pointidx [ MAX_ARRAY_VERTS ] ;
/*make sure there's space*/
newmax = ( cv . numpoints + numpoints + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxpoints < newmax )
{
cv . maxpoints = newmax ;
cv . points = BZ_Realloc ( cv . points , newmax * sizeof ( * cv . points ) ) ;
}
newmax = ( cv . numedges + ( numpoints - 2 ) * 3 + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxedges < newmax )
{
cv . maxedges = newmax ;
cv . edges = BZ_Realloc ( cv . edges , newmax * sizeof ( * cv . edges ) ) ;
}
newmax = ( cv . numtris + ( numpoints - 2 ) + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxtris < newmax )
{
cv . maxtris = newmax ;
cv . tris = BZ_Realloc ( cv . tris , newmax * sizeof ( * cv . tris ) ) ;
}
for ( i = 0 ; i < numpoints ; i + + )
{
pointidx [ i ] = SHM_ComposeVolume_FindVert ( points [ i ] ) ;
}
lastedge = SHM_ComposeVolume_FindEdge ( pointidx [ 0 ] , pointidx [ 1 ] ) ;
for ( i = 2 ; i < numpoints ; i + + )
{
cv . tris [ cv . numtris ] . edge [ 0 ] = lastedge ;
cv . tris [ cv . numtris ] . edge [ 1 ] = SHM_ComposeVolume_FindEdge ( pointidx [ i - 1 ] , pointidx [ i ] ) ;
lastedge = SHM_ComposeVolume_FindEdge ( pointidx [ i ] , pointidx [ 0 ] ) ;
cv . tris [ cv . numtris ] . edge [ 2 ] = lastedge ;
lastedge = - ( lastedge + 1 ) ;
cv . numtris + + ;
}
}
static void SHM_ComposeVolume_Soup ( vecV_t * points , int numpoints , index_t * idx , int numidx )
{
int newmax ;
int i ;
# define MAX_ARRAY_VERTS 65535
static index_t pointidx [ MAX_ARRAY_VERTS ] ;
/*make sure there's space*/
newmax = ( cv . numpoints + numpoints + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxpoints < newmax )
{
cv . maxpoints = newmax ;
cv . points = BZ_Realloc ( cv . points , newmax * sizeof ( * cv . points ) ) ;
}
newmax = ( cv . numedges + numidx + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxedges < newmax )
{
cv . maxedges = newmax ;
cv . edges = BZ_Realloc ( cv . edges , newmax * sizeof ( * cv . edges ) ) ;
}
newmax = ( cv . numtris + numidx / 3 + inc ) & ~ ( inc - 1 ) ;
if ( cv . maxtris < newmax )
{
cv . maxtris = newmax ;
cv . tris = BZ_Realloc ( cv . tris , newmax * sizeof ( * cv . tris ) ) ;
}
for ( i = 0 ; i < numpoints ; i + + )
{
pointidx [ i ] = SHM_ComposeVolume_FindVert ( points [ i ] ) ;
}
for ( i = 0 ; i < numidx ; i + = 3 , idx + = 3 )
{
cv . tris [ cv . numtris ] . edge [ 0 ] = SHM_ComposeVolume_FindEdge ( pointidx [ idx [ 0 ] ] , pointidx [ idx [ 1 ] ] ) ;
cv . tris [ cv . numtris ] . edge [ 1 ] = SHM_ComposeVolume_FindEdge ( pointidx [ idx [ 1 ] ] , pointidx [ idx [ 2 ] ] ) ;
cv . tris [ cv . numtris ] . edge [ 2 ] = SHM_ComposeVolume_FindEdge ( pointidx [ idx [ 2 ] ] , pointidx [ idx [ 0 ] ] ) ;
cv . numtris + + ;
}
}
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/*call this function after generating litsurfs meshes*/
static void SHM_ComposeVolume_BruteForce ( dlight_t * dl )
{
shadowmeshbatch_t * sms ;
unsigned int tno ;
unsigned int sno ;
int i , e ;
mesh_t * sm ;
vec3_t ext ;
float sc ;
cv . numedges = 0 ;
cv . numpoints = 0 ;
cv . numtris = 0 ;
for ( tno = 0 ; tno < sh_shmesh - > numbatches ; tno + + )
{
sms = & sh_shmesh - > batches [ tno ] ;
if ( ! sms - > count )
continue ;
if ( ( cl . worldmodel - > shadowbatches [ tno ] . tex - > shader - > flags & ( SHADER_BLEND | SHADER_NODRAW ) ) )
continue ;
for ( sno = 0 ; sno < sms - > count ; sno + + )
{
sm = sms - > s [ sno ] ;
if ( sm - > istrifan )
SHM_ComposeVolume_Fan ( sm - > xyz_array , sm - > numvertexes ) ;
else
SHM_ComposeVolume_Soup ( sm - > xyz_array , sm - > numvertexes , sm - > indexes , sm - > numindexes ) ;
}
}
/*FIXME: clip away overlapping triangles*/
if ( cv . maxedgeuses < cv . numedges )
{
BZ_Free ( cv . edgeuses ) ;
cv . maxedgeuses = cv . numedges ;
cv . edgeuses = Z_Malloc ( cv . maxedgeuses * sizeof ( * cv . edgeuses ) ) ;
}
else
memset ( cv . edgeuses , 0 , cv . numedges * sizeof ( * cv . edgeuses ) ) ;
i = ( sh_shmesh - > numverts + cv . numpoints * 6 + inc + 5 ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxverts < i )
{
sh_shmesh - > maxverts = i ;
sh_shmesh - > verts = BZ_Realloc ( sh_shmesh - > verts , i * sizeof ( * sh_shmesh - > verts ) ) ;
}
for ( i = 0 ; i < cv . numpoints ; i + + )
{
/*front face*/
sh_shmesh - > verts [ ( i * 2 ) + 0 ] [ 0 ] = cv . points [ i ] [ 0 ] ;
sh_shmesh - > verts [ ( i * 2 ) + 0 ] [ 1 ] = cv . points [ i ] [ 1 ] ;
sh_shmesh - > verts [ ( i * 2 ) + 0 ] [ 2 ] = cv . points [ i ] [ 2 ] ;
/*shadow direction*/
ext [ 0 ] = cv . points [ i ] [ 0 ] - dl - > origin [ 0 ] ;
ext [ 1 ] = cv . points [ i ] [ 1 ] - dl - > origin [ 1 ] ;
ext [ 2 ] = cv . points [ i ] [ 2 ] - dl - > origin [ 2 ] ;
sc = dl - > radius * VectorNormalize ( ext ) ;
/*back face*/
sh_shmesh - > verts [ ( i * 2 ) + 1 ] [ 0 ] = cv . points [ i ] [ 0 ] + ext [ 0 ] * sc ;
sh_shmesh - > verts [ ( i * 2 ) + 1 ] [ 1 ] = cv . points [ i ] [ 1 ] + ext [ 1 ] * sc ;
sh_shmesh - > verts [ ( i * 2 ) + 1 ] [ 2 ] = cv . points [ i ] [ 2 ] + ext [ 2 ] * sc ;
}
sh_shmesh - > numverts = i * 2 ;
i = ( sh_shmesh - > numindicies + cv . numtris * 6 + cv . numedges * 6 + inc + 5 ) & ~ ( inc - 1 ) ; //and a bit of padding
if ( sh_shmesh - > maxindicies < i )
{
sh_shmesh - > maxindicies = i ;
sh_shmesh - > indicies = BZ_Realloc ( sh_shmesh - > indicies , i * sizeof ( * sh_shmesh - > indicies ) ) ;
}
for ( tno = 0 ; tno < cv . numtris ; tno + + )
{
for ( i = 0 ; i < 3 ; i + + )
{
e = cv . tris [ tno ] . edge [ i ] ;
if ( e < 0 )
{
e = - ( e + 1 ) ;
cv . edgeuses [ e ] - - ;
e = cv . edges [ e ] . vert [ 1 ] ;
}
else
{
cv . edgeuses [ e ] + + ;
e = cv . edges [ e ] . vert [ 0 ] ;
}
sh_shmesh - > indicies [ sh_shmesh - > numindicies + i ] = e * 2 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + 5 - i ] = e * 2 + 1 ;
}
sh_shmesh - > numindicies + = 6 ;
}
for ( i = 0 ; i < cv . numedges ; i + + )
{
if ( cv . edgeuses [ i ] > 0 )
{
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 0 ;
}
else if ( cv . edgeuses [ i ] < 0 )
{
//generally should not happen...
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 0 ] * 2 + 1 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 0 ;
sh_shmesh - > indicies [ sh_shmesh - > numindicies + + ] = cv . edges [ i ] . vert [ 1 ] * 2 + 1 ;
}
}
}
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# endif
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static struct shadowmesh_s * SHM_BuildShadowMesh ( dlight_t * dl , unsigned char * lvis , int type )
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{
float * v1 , * v2 ;
vec3_t v3 , v4 ;
if ( dl - > worldshadowmesh & & ! dl - > rebuildcache & & dl - > worldshadowmesh - > type = = type )
return dl - > worldshadowmesh ;
if ( ! lvis )
{
int clus ;
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if ( type = = SMT_ORTHO )
;
else if ( ( type = = SMT_SHADOWLESS | | dl - > lightcolourscales [ 0 ] ) & & cl . worldmodel - > funcs . ClustersInSphere )
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//shadowless lights don't cast shadows, so they're seen through everything - their vis must reflect that.
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lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , dl - > origin , dl - > radius , & lvisb , NULL ) ;
else
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{
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
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if ( cl . worldmodel - > funcs . ClustersInSphere )
lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , dl - > origin , dl - > radius , & lvisb2 , lvis ) ;
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}
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}
firstedge = 0 ;
if ( maxedge < cl . worldmodel - > numedges )
{
maxedge = cl . worldmodel - > numedges ;
Z_Free ( edge ) ;
edge = Z_Malloc ( sizeof ( * edge ) * maxedge ) ;
}
if ( cl . worldmodel - > type = = mod_brush )
{
switch ( cl . worldmodel - > fromgame )
{
case fg_quake :
case fg_halflife :
/*if (!dl->die)
{
SHM_BeginShadowMesh ( dl , true ) ;
SHM_MarkLeavesQ1 ( dl , lvis ) ;
SHM_RecursiveWorldNodeQ1_r ( dl , cl . worldmodel - > nodes ) ;
if ( ! surfonly )
SHM_ComposeVolume_BruteForce ( dl ) ;
}
else */
{
SHM_BeginShadowMesh ( dl , type ) ;
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if ( type = = SMT_ORTHO )
SHM_OrthoWorldLeafsQ1 ( dl ) ;
else
{
SHM_MarkLeavesQ1 ( dl , lvis ) ;
SHM_RecursiveWorldNodeQ1_r ( dl , cl . worldmodel - > nodes ) ;
}
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}
break ;
# ifdef Q2BSPS
case fg_quake2 :
SHM_BeginShadowMesh ( dl , type ) ;
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SHM_MarkLeavesQ2 ( dl , lvis ) ;
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SHM_RecursiveWorldNodeQ2_r ( dl , cl . worldmodel - > nodes ) ;
break ;
# endif
# ifdef Q3BSPS
case fg_quake3 :
/*q3 doesn't have edge info*/
SHM_BeginShadowMesh ( dl , type ) ;
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if ( type = = SMT_ORTHO )
SHM_OrthoWorldLeafsQ3 ( dl ) ;
else
{
sh_shadowframe + + ;
SHM_RecursiveWorldNodeQ3_r ( dl , cl . worldmodel - > nodes ) ;
}
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if ( type = = SMT_STENCILVOLUME )
SHM_ComposeVolume_BruteForce ( dl ) ;
break ;
# endif
default :
SHM_BeginShadowMesh ( dl , type ) ;
sh_shadowframe + + ;
{
int cluster = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
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if ( cluster > = 0 )
sh_shmesh - > litleaves [ cluster > > 3 ] | = 1 < < ( cluster & 7 ) ;
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}
break ;
}
}
else
{
SHM_BeginShadowMesh ( dl , type ) ;
sh_shadowframe + + ;
}
/*generate edge polys for map types that need it (q1/q2)*/
switch ( type )
{
case SMT_STENCILVOLUME :
SHM_BeginQuads ( ) ;
while ( firstedge )
{
//border
v1 = cl . worldmodel - > vertexes [ cl . worldmodel - > edges [ firstedge ] . v [ 0 ] ] . position ;
v2 = cl . worldmodel - > vertexes [ cl . worldmodel - > edges [ firstedge ] . v [ 1 ] ] . position ;
//get positions of v3 and v4 based on the light position
v3 [ 0 ] = v1 [ 0 ] + ( v1 [ 0 ] - dl - > origin [ 0 ] ) * PROJECTION_DISTANCE ;
v3 [ 1 ] = v1 [ 1 ] + ( v1 [ 1 ] - dl - > origin [ 1 ] ) * PROJECTION_DISTANCE ;
v3 [ 2 ] = v1 [ 2 ] + ( v1 [ 2 ] - dl - > origin [ 2 ] ) * PROJECTION_DISTANCE ;
v4 [ 0 ] = v2 [ 0 ] + ( v2 [ 0 ] - dl - > origin [ 0 ] ) * PROJECTION_DISTANCE ;
v4 [ 1 ] = v2 [ 1 ] + ( v2 [ 1 ] - dl - > origin [ 1 ] ) * PROJECTION_DISTANCE ;
v4 [ 2 ] = v2 [ 2 ] + ( v2 [ 2 ] - dl - > origin [ 2 ] ) * PROJECTION_DISTANCE ;
if ( edge [ firstedge ] . count > 0 )
{
SHM_Vertex3fv ( v3 ) ;
SHM_Vertex3fv ( v4 ) ;
SHM_Vertex3fv ( v2 ) ;
SHM_Vertex3fv ( v1 ) ;
}
else
{
SHM_Vertex3fv ( v1 ) ;
SHM_Vertex3fv ( v2 ) ;
SHM_Vertex3fv ( v4 ) ;
SHM_Vertex3fv ( v3 ) ;
}
edge [ firstedge ] . count = 0 ;
firstedge = edge [ firstedge ] . next ;
}
SHM_End ( ) ;
break ;
}
return SHM_FinishShadowMesh ( dl ) ;
}
static qboolean Sh_VisOverlaps ( qbyte * v1 , qbyte * v2 )
{
int i , m ;
if ( ! v2 | | ! v1 )
return true ;
m = ( cl . worldmodel - > numclusters + 7 ) > > 3 ;
for ( i = ( m & ~ 3 ) ; i < m ; i + + )
{
if ( v1 [ i ] & v2 [ i ] )
return true ;
}
m > > = 2 ;
for ( i = 0 ; i < m ; i + + )
{
if ( ( ( unsigned int * ) v1 ) [ i ] & ( ( unsigned int * ) v2 ) [ i ] )
return true ;
}
return false ;
}
# if 1
# define Sh_LeafInView Sh_VisOverlaps
# else
static qboolean Sh_LeafInView ( qbyte * lightvis , qbyte * vvis )
{
int i ;
int m = ( cl . worldmodel - > numvisleafs ) ;
mleaf_t * wl = cl . worldmodel - > leafs ;
unsigned char lv ;
/*we can potentially walk off the end of the leafs, but lightvis shouldn't be set for those*/
for ( i = 0 ; i < m ; i + = 1 < < 3 )
{
lv = lightvis [ i > > 3 ] ; // & vvis[i>>3];
if ( ! lv )
continue ;
if ( ( lv & 0x01 ) & & wl [ i + 0 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x02 ) & & wl [ i + 1 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x04 ) & & wl [ i + 2 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x08 ) & & wl [ i + 3 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x10 ) & & wl [ i + 4 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x20 ) & & wl [ i + 5 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x40 ) & & wl [ i + 6 ] . visframe = = r_visframecount ) return true ;
if ( ( lv & 0x80 ) & & wl [ i + 7 ] . visframe = = r_visframecount ) return true ;
}
return false ;
}
# endif
/*
static void Sh_Scissor ( srect_t * r )
{
//float xs = vid.pixelwidth / (float)vid.width, ys = vid.pixelheight / (float)vid.height;
switch ( qrenderer )
{
case QR_NONE :
case QR_SOFTWARE :
case QR_DIRECT3D11 :
default :
break ;
case QR_OPENGL :
# ifdef GLQUAKE
qglScissor (
floor ( r_refdef . pxrect . x + r - > x * r_refdef . pxrect . width ) ,
floor ( ( r_refdef . pxrect . y + r - > y * r_refdef . pxrect . height ) - r_refdef . pxrect . height ) ,
ceil ( r - > width * r_refdef . pxrect . width ) ,
ceil ( r - > height * r_refdef . pxrect . height ) ) ;
qglEnable ( GL_SCISSOR_TEST ) ;
if ( qglDepthBoundsEXT )
{
qglDepthBoundsEXT ( r - > dmin , r - > dmax ) ;
qglEnable ( GL_DEPTH_BOUNDS_TEST_EXT ) ;
}
# endif
break ;
case QR_DIRECT3D9 :
# ifdef D3D9QUAKE
{
RECT rect ;
rect . left = r - > x ;
rect . right = r - > x + r - > width ;
rect . top = r - > y ;
rect . bottom = r - > y + r - > height ;
IDirect3DDevice9_SetScissorRect ( pD3DDev9 , & rect ) ;
}
# endif
break ;
}
}
static void Sh_ScissorOff ( void )
{
switch ( qrenderer )
{
default :
break ;
case QR_OPENGL :
# ifdef GLQUAKE
qglDisable ( GL_SCISSOR_TEST ) ;
if ( qglDepthBoundsEXT )
qglDisable ( GL_DEPTH_BOUNDS_TEST_EXT ) ;
# endif
break ;
case QR_DIRECT3D9 :
# ifdef D3D9QUAKE
# endif
break ;
}
}
*/
#if 0
static qboolean Sh_ScissorForSphere ( vec3_t center , float radius , vrect_t * rect )
{
/*return false to say that its fully offscreen*/
float v [ 4 ] , tempv [ 4 ] ;
int i ;
vrect_t r ;
rect - > x = 0 ;
rect - > y = 0 ;
rect - > width = vid . pixelwidth ;
rect - > height = vid . pixelheight ;
/*
for ( i = 0 ; i < 4 ; i + + )
{
v [ 3 ] = 1 ;
VectorMA ( center , radius , frustum [ i ] . normal , v ) ;
tempv [ 0 ] = r_refdef . m_view [ 0 ] * v [ 0 ] + r_refdef . m_view [ 4 ] * v [ 1 ] + r_refdef . m_view [ 8 ] * v [ 2 ] + r_refdef . m_view [ 12 ] * v [ 3 ] ;
tempv [ 1 ] = r_refdef . m_view [ 1 ] * v [ 0 ] + r_refdef . m_view [ 5 ] * v [ 1 ] + r_refdef . m_view [ 9 ] * v [ 2 ] + r_refdef . m_view [ 13 ] * v [ 3 ] ;
tempv [ 2 ] = r_refdef . m_view [ 2 ] * v [ 0 ] + r_refdef . m_view [ 6 ] * v [ 1 ] + r_refdef . m_view [ 10 ] * v [ 2 ] + r_refdef . m_view [ 14 ] * v [ 3 ] ;
tempv [ 3 ] = r_refdef . m_view [ 3 ] * v [ 0 ] + r_refdef . m_view [ 7 ] * v [ 1 ] + r_refdef . m_view [ 11 ] * v [ 2 ] + r_refdef . m_view [ 15 ] * v [ 3 ] ;
product [ 0 ] = r_refdef . m_projection [ 0 ] * tempv [ 0 ] + r_refdef . m_projection [ 4 ] * tempv [ 1 ] + r_refdef . m_projection [ 8 ] * tempv [ 2 ] + r_refdef . m_projection [ 12 ] * tempv [ 3 ] ;
product [ 1 ] = r_refdef . m_projection [ 1 ] * tempv [ 0 ] + r_refdef . m_projection [ 5 ] * tempv [ 1 ] + r_refdef . m_projection [ 9 ] * tempv [ 2 ] + r_refdef . m_projection [ 13 ] * tempv [ 3 ] ;
product [ 2 ] = r_refdef . m_projection [ 2 ] * tempv [ 0 ] + r_refdef . m_projection [ 6 ] * tempv [ 1 ] + r_refdef . m_projection [ 10 ] * tempv [ 2 ] + r_refdef . m_projection [ 14 ] * tempv [ 3 ] ;
product [ 3 ] = r_refdef . m_projection [ 3 ] * tempv [ 0 ] + r_refdef . m_projection [ 7 ] * tempv [ 1 ] + r_refdef . m_projection [ 11 ] * tempv [ 2 ] + r_refdef . m_projection [ 15 ] * tempv [ 3 ] ;
v [ 0 ] / = v [ 3 ] ;
v [ 1 ] / = v [ 3 ] ;
v [ 2 ] / = v [ 3 ] ;
out [ 0 ] = ( 1 + v [ 0 ] ) / 2 ;
out [ 1 ] = ( 1 + v [ 1 ] ) / 2 ;
out [ 2 ] = ( 1 + v [ 2 ] ) / 2 ;
r . x
}
*/
return false ;
}
# endif
# define BoxesOverlap(a,b,c,d) ((a)[0] <= (d)[0] && (b)[0] >= (c)[0] && (a)[1] <= (d)[1] && (b)[1] >= (c)[1] && (a)[2] <= (d)[2] && (b)[2] >= (c)[2])
static qboolean Sh_ScissorForBox ( vec3_t mins , vec3_t maxs , srect_t * r )
{
static const int edge [ 12 ] [ 2 ] =
{
{ 0 , 1 } , { 0 , 2 } , { 1 , 3 } , { 2 , 3 } ,
{ 4 , 5 } , { 4 , 6 } , { 5 , 7 } , { 6 , 7 } ,
{ 0 , 4 } , { 1 , 5 } , { 2 , 6 } , { 3 , 7 }
} ;
//the box is a simple cube.
//clip each vert to the near clip plane
//insert a replacement vertex for edges that cross the nearclip plane where it crosses
//calc the scissor rect from projecting the verts that survived, plus the clipped edge ones.
float ncpdist ;
float dist [ 8 ] ;
int sign [ 8 ] ;
vec4_t vert [ 20 ] ;
vec3_t p [ 8 ] ;
int numverts = 0 , i , v1 , v2 ;
vec4_t v , tv ;
float frac ;
float x , x1 , x2 , y , y1 , y2 ;
double z , z1 , z2 ;
r - > x = 0 ;
r - > y = 0 ;
r - > width = 1 ;
r - > height = 1 ;
r - > dmin = 0 ;
r - > dmax = 1 ;
if ( ! r_shadow_scissor . ival )
{
r - > x = 0 ;
r - > y = 0 ;
r - > width = 1 ;
r - > height = 1 ;
return false ;
}
/*if view is inside the box, then skip this maths*/
// if (BoxesOverlap(r_refdef.vieworg, r_refdef.vieworg, mins, maxs))
// {
// return false;
// }
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ncpdist = DotProduct ( r_refdef . vieworg , vpn ) + r_refdef . mindist ;
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for ( i = 0 ; i < 8 ; i + + )
{
p [ i ] [ 0 ] = ( i & 1 ) ? mins [ 0 ] : maxs [ 0 ] ;
p [ i ] [ 1 ] = ( i & 2 ) ? mins [ 1 ] : maxs [ 1 ] ;
p [ i ] [ 2 ] = ( i & 4 ) ? mins [ 2 ] : maxs [ 2 ] ;
dist [ i ] = ncpdist - DotProduct ( p [ i ] , vpn ) ;
sign [ i ] = ( dist [ i ] > 0 ) ;
if ( ! sign [ i ] )
{
VectorCopy ( p [ i ] , vert [ numverts ] ) ;
numverts + + ;
}
}
/*fully clipped by near plane*/
if ( ! numverts )
return true ;
if ( numverts ! = 8 )
{
/*crosses near clip plane somewhere*/
for ( i = 0 ; i < 12 ; i + + )
{
v1 = edge [ i ] [ 0 ] ;
v2 = edge [ i ] [ 1 ] ;
if ( sign [ v1 ] ! = sign [ v2 ] )
{
frac = dist [ v1 ] / ( dist [ v1 ] - dist [ v2 ] ) ;
VectorInterpolate ( p [ v1 ] , frac , p [ v2 ] , vert [ numverts ] ) ;
numverts + + ;
}
}
}
x1 = y1 = z1 = 1 ;
x2 = y2 = z2 = - 1 ;
/*transform each vert to get the screen pos*/
for ( i = 0 ; i < numverts ; i + + )
{
vert [ i ] [ 3 ] = 1 ;
Matrix4x4_CM_Transform4 ( r_refdef . m_view , vert [ i ] , tv ) ;
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Matrix4x4_CM_Transform4 ( r_refdef . m_projection_std , tv , v ) ;
2016-07-12 00:40:13 +00:00
x = v [ 0 ] / v [ 3 ] ;
y = v [ 1 ] / v [ 3 ] ;
z = ( double ) v [ 2 ] / v [ 3 ] ;
if ( x < x1 ) x1 = x ;
if ( x > x2 ) x2 = x ;
if ( y < y1 ) y1 = y ;
if ( y > y2 ) y2 = y ;
if ( z < z1 ) z1 = z ;
if ( z > z2 ) z2 = z ;
}
x1 = ( 1 + x1 ) / 2 ;
x2 = ( 1 + x2 ) / 2 ;
y1 = ( 1 + y1 ) / 2 ;
y2 = ( 1 + y2 ) / 2 ;
z1 = ( 1 + z1 ) / 2 ;
z2 = ( 1 + z2 ) / 2 ;
if ( x1 < 0 )
x1 = 0 ;
if ( y1 < 0 )
y1 = 0 ;
if ( x2 < 0 )
x2 = 0 ;
if ( y2 < 0 )
y2 = 0 ;
if ( x1 > 1 )
x1 = 1 ;
if ( y1 > 1 )
y1 = 1 ;
if ( x2 > 1 )
x2 = 1 ;
if ( y2 > 1 )
y2 = 1 ;
r - > x = x1 ;
r - > y = y1 ;
r - > width = x2 - r - > x ;
r - > height = y2 - r - > y ;
if ( r - > width = = 0 | | r - > height = = 0 )
return true ; //meh
r - > dmin = z1 ;
r - > dmax = z2 ;
return false ;
}
#if 0
static qboolean Sh_ScissorForBox ( vec3_t mins , vec3_t maxs , vrect_t * r )
{
int i , ix1 , iy1 , ix2 , iy2 ;
float x1 , y1 , x2 , y2 , x , y , f ;
vec3_t smins , smaxs ;
vec4_t v , v2 ;
r - > x = 0 ;
r - > y = 0 ;
r - > width = vid . pixelwidth ;
r - > height = vid . pixelheight ;
if ( 0 ) //!r_shadow_scissor.integer)
{
return false ;
}
// if view is inside the box, just say yes it's fully visible
if ( BoxesOverlap ( r_refdef . vieworg , r_refdef . vieworg , mins , maxs ) )
{
return false ;
}
for ( i = 0 ; i < 3 ; i + + )
{
if ( vpn [ i ] > = 0 )
{
v [ i ] = mins [ i ] ;
v2 [ i ] = maxs [ i ] ;
}
else
{
v [ i ] = maxs [ i ] ;
v2 [ i ] = mins [ i ] ;
}
}
f = DotProduct ( vpn , r_refdef . vieworg ) ;
if ( DotProduct ( vpn , v2 ) < = f )
{
// entirely behind nearclip plane, entirely obscured
return true ;
}
if ( DotProduct ( vpn , v ) > = f )
{
// entirely infront of nearclip plane
x1 = y1 = x2 = y2 = 0 ;
for ( i = 0 ; i < 8 ; i + + )
{
v [ 0 ] = ( i & 1 ) ? mins [ 0 ] : maxs [ 0 ] ;
v [ 1 ] = ( i & 2 ) ? mins [ 1 ] : maxs [ 1 ] ;
v [ 2 ] = ( i & 4 ) ? mins [ 2 ] : maxs [ 2 ] ;
v [ 3 ] = 1.0f ;
Matrix4x4_CM_Project ( v , v2 , r_refdef . viewangles , r_refdef . vieworg , r_refdef . fov_x , r_refdef . fov_y ) ;
v2 [ 0 ] * = vid . pixelwidth ;
v2 [ 1 ] * = vid . pixelheight ;
// GL_TransformToScreen(v, v2);
//Con_Printf("%.3f %.3f %.3f %.3f transformed to %.3f %.3f %.3f %.3f\n", v[0], v[1], v[2], v[3], v2[0], v2[1], v2[2], v2[3]);
x = v2 [ 0 ] ;
y = v2 [ 1 ] ;
if ( i )
{
if ( x1 > x ) x1 = x ;
if ( x2 < x ) x2 = x ;
if ( y1 > y ) y1 = y ;
if ( y2 < y ) y2 = y ;
}
else
{
x1 = x2 = x ;
y1 = y2 = y ;
}
}
}
else
{
// clipped by nearclip plane
// this is nasty and crude...
// create viewspace bbox
i = 0 ;
/*unrolled the first iteration to avoid warnings*/
v [ 0 ] = ( ( i & 1 ) ? mins [ 0 ] : maxs [ 0 ] ) - r_refdef . vieworg [ 0 ] ;
v [ 1 ] = ( ( i & 2 ) ? mins [ 1 ] : maxs [ 1 ] ) - r_refdef . vieworg [ 1 ] ;
v [ 2 ] = ( ( i & 4 ) ? mins [ 2 ] : maxs [ 2 ] ) - r_refdef . vieworg [ 2 ] ;
v2 [ 0 ] = DotProduct ( v , vright ) ;
v2 [ 1 ] = DotProduct ( v , vup ) ;
v2 [ 2 ] = DotProduct ( v , vpn ) ;
smins [ 0 ] = smaxs [ 0 ] = v2 [ 0 ] ;
smins [ 1 ] = smaxs [ 1 ] = v2 [ 1 ] ;
smins [ 2 ] = smaxs [ 2 ] = v2 [ 2 ] ;
for ( i = 1 ; i < 8 ; i + + )
{
v [ 0 ] = ( ( i & 1 ) ? mins [ 0 ] : maxs [ 0 ] ) - r_refdef . vieworg [ 0 ] ;
v [ 1 ] = ( ( i & 2 ) ? mins [ 1 ] : maxs [ 1 ] ) - r_refdef . vieworg [ 1 ] ;
v [ 2 ] = ( ( i & 4 ) ? mins [ 2 ] : maxs [ 2 ] ) - r_refdef . vieworg [ 2 ] ;
v2 [ 0 ] = DotProduct ( v , vright ) ;
v2 [ 1 ] = DotProduct ( v , vup ) ;
v2 [ 2 ] = DotProduct ( v , vpn ) ;
if ( smins [ 0 ] > v2 [ 0 ] ) smins [ 0 ] = v2 [ 0 ] ;
if ( smaxs [ 0 ] < v2 [ 0 ] ) smaxs [ 0 ] = v2 [ 0 ] ;
if ( smins [ 1 ] > v2 [ 1 ] ) smins [ 1 ] = v2 [ 1 ] ;
if ( smaxs [ 1 ] < v2 [ 1 ] ) smaxs [ 1 ] = v2 [ 1 ] ;
if ( smins [ 2 ] > v2 [ 2 ] ) smins [ 2 ] = v2 [ 2 ] ;
if ( smaxs [ 2 ] < v2 [ 2 ] ) smaxs [ 2 ] = v2 [ 2 ] ;
}
// now we have a bbox in viewspace
// clip it to the view plane
if ( smins [ 2 ] < 1 )
smins [ 2 ] = 1 ;
// return true if that culled the box
if ( smins [ 2 ] > = smaxs [ 2 ] )
return true ;
// ok some of it is infront of the view, transform each corner back to
// worldspace and then to screenspace and make screen rect
// initialize these variables just to avoid compiler warnings
x1 = y1 = x2 = y2 = 0 ;
for ( i = 0 ; i < 8 ; i + + )
{
v2 [ 0 ] = ( i & 1 ) ? smins [ 0 ] : smaxs [ 0 ] ;
v2 [ 1 ] = ( i & 2 ) ? smins [ 1 ] : smaxs [ 1 ] ;
v2 [ 2 ] = ( i & 4 ) ? smins [ 2 ] : smaxs [ 2 ] ;
v [ 0 ] = v2 [ 0 ] * vright [ 0 ] + v2 [ 1 ] * vup [ 0 ] + v2 [ 2 ] * vpn [ 0 ] + r_refdef . vieworg [ 0 ] ;
v [ 1 ] = v2 [ 0 ] * vright [ 1 ] + v2 [ 1 ] * vup [ 1 ] + v2 [ 2 ] * vpn [ 1 ] + r_refdef . vieworg [ 1 ] ;
v [ 2 ] = v2 [ 0 ] * vright [ 2 ] + v2 [ 1 ] * vup [ 2 ] + v2 [ 2 ] * vpn [ 2 ] + r_refdef . vieworg [ 2 ] ;
v [ 3 ] = 1.0f ;
Matrix4x4_CM_Project ( v , v2 , r_refdef . viewangles , r_refdef . vieworg , r_refdef . fov_x , r_refdef . fov_y ) ;
v2 [ 0 ] * = vid . pixelwidth ;
v2 [ 1 ] * = vid . pixelheight ;
//Con_Printf("%.3f %.3f %.3f %.3f transformed to %.3f %.3f %.3f %.3f\n", v[0], v[1], v[2], v[3], v2[0], v2[1], v2[2], v2[3]);
x = v2 [ 0 ] ;
y = v2 [ 1 ] ;
if ( i )
{
if ( x1 > x ) x1 = x ;
if ( x2 < x ) x2 = x ;
if ( y1 > y ) y1 = y ;
if ( y2 < y ) y2 = y ;
}
else
{
x1 = x2 = x ;
y1 = y2 = y ;
}
}
# if 1
// this code doesn't handle boxes with any points behind view properly
x1 = 1000 ; x2 = - 1000 ;
y1 = 1000 ; y2 = - 1000 ;
for ( i = 0 ; i < 8 ; i + + )
{
v [ 0 ] = ( i & 1 ) ? mins [ 0 ] : maxs [ 0 ] ;
v [ 1 ] = ( i & 2 ) ? mins [ 1 ] : maxs [ 1 ] ;
v [ 2 ] = ( i & 4 ) ? mins [ 2 ] : maxs [ 2 ] ;
v [ 3 ] = 1.0f ;
Matrix4x4_CM_Project ( v , v2 , r_refdef . viewangles , r_refdef . vieworg , r_refdef . fov_x , r_refdef . fov_y ) ;
v2 [ 0 ] * = vid . pixelwidth ;
v2 [ 1 ] * = vid . pixelheight ;
//Con_Printf("%.3f %.3f %.3f %.3f transformed to %.3f %.3f %.3f %.3f\n", v[0], v[1], v[2], v[3], v2[0], v2[1], v2[2], v2[3]);
if ( v2 [ 2 ] > 0 )
{
x = v2 [ 0 ] ;
y = v2 [ 1 ] ;
if ( x1 > x ) x1 = x ;
if ( x2 < x ) x2 = x ;
if ( y1 > y ) y1 = y ;
if ( y2 < y ) y2 = y ;
}
}
# endif
}
ix1 = x1 - 1.0f ;
iy1 = y1 - 1.0f ;
ix2 = x2 + 1.0f ;
iy2 = y2 + 1.0f ;
//Con_Printf("%f %f %f %f\n", x1, y1, x2, y2);
if ( ix1 < r - > x ) ix1 = r - > x ;
if ( iy1 < r - > y ) iy1 = r - > y ;
if ( ix2 > r - > x + r - > width ) ix2 = r - > x + r - > width ;
if ( iy2 > r - > y + r - > height ) iy2 = r - > y + r - > height ;
if ( ix2 < = ix1 | | iy2 < = iy1 )
return true ;
// set up the scissor rectangle
r - > x = ix1 ;
r - > y = iy1 ;
r - > width = ix2 - ix1 ;
r - > height = iy2 - iy1 ;
return false ;
}
# endif
void D3D11BE_BeginShadowmapFace ( void ) ;
//determine the 5 bounding points of a shadowmap light projection side
//needs to match Sh_GenShadowFace
static void Sh_LightFrustumPlanes ( dlight_t * l , vec3_t axis [ 3 ] , vec4_t * planes , int face )
{
vec3_t tmp ;
int axis0 , axis1 , axis2 ;
int dir ;
int i ;
//+x,+y,+z,-x,-y,-z
axis0 = ( face + 0 ) % 3 ; //our major axis
axis1 = ( face + 1 ) % 3 ;
axis2 = ( face + 2 ) % 3 ;
dir = ( face > = 3 ) ? - 1 : 1 ;
//center point is always the same
VectorCopy ( l - > origin , planes [ 4 ] ) ;
VectorScale ( axis [ axis0 ] , dir , planes [ 4 ] ) ;
VectorNormalize ( planes [ 4 ] ) ;
planes [ 4 ] [ 3 ] = r_shadow_shadowmapping_nearclip . value + DotProduct ( planes [ 4 ] , l - > origin ) ;
for ( i = 0 ; i < 4 ; i + + )
{
VectorScale ( axis [ axis0 ] , dir , tmp ) ;
VectorMA ( tmp , ( ( i & 1 ) ? 1 : - 1 ) , axis [ axis1 ] , tmp ) ;
VectorMA ( tmp , ( ( i & 2 ) ? 1 : - 1 ) , axis [ axis2 ] , planes [ i ] ) ;
VectorNormalize ( planes [ i ] ) ;
planes [ i ] [ 3 ] = DotProduct ( planes [ i ] , l - > origin ) ;
}
}
//culling for the face happens in the caller.
//these faces should thus match Sh_LightFrustumPlanes
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static void Sh_GenShadowFace ( dlight_t * l , vec3_t axis [ 3 ] , int lighttype , shadowmesh_t * smesh , int face , int smsize , float proj [ 16 ] )
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{
vec3_t t1 , t2 , t3 ;
texture_t * tex ;
int tno ;
/* if (face >= 3)
face - = 3 ;
else
face + = 3 ;
*/
switch ( face )
{
case 0 :
//down
VectorCopy ( axis [ 0 ] , t1 ) ;
VectorCopy ( axis [ 1 ] , t2 ) ;
VectorCopy ( axis [ 2 ] , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = 0 ;
break ;
case 1 :
//back
VectorCopy ( axis [ 2 ] , t1 ) ;
VectorCopy ( axis [ 1 ] , t2 ) ;
VectorCopy ( axis [ 0 ] , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = SHADER_CULL_FLIP ;
break ;
case 2 :
//right
VectorCopy ( axis [ 0 ] , t1 ) ;
VectorCopy ( axis [ 2 ] , t2 ) ;
VectorCopy ( axis [ 1 ] , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = SHADER_CULL_FLIP ;
break ;
case 3 :
//up
VectorCopy ( axis [ 0 ] , t1 ) ;
VectorCopy ( axis [ 1 ] , t2 ) ;
VectorCopy ( axis [ 2 ] , t3 ) ;
VectorNegate ( t3 , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = SHADER_CULL_FLIP ;
break ;
case 4 :
//forward
VectorCopy ( axis [ 2 ] , t1 ) ;
VectorCopy ( axis [ 1 ] , t2 ) ;
VectorCopy ( axis [ 0 ] , t3 ) ;
VectorNegate ( t3 , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = 0 ;
break ;
case 5 :
//left
VectorCopy ( axis [ 0 ] , t1 ) ;
VectorCopy ( axis [ 2 ] , t2 ) ;
VectorCopy ( axis [ 1 ] , t3 ) ;
VectorNegate ( t3 , t3 ) ;
Matrix4x4_CM_LightMatrixFromAxis ( r_refdef . m_view , t1 , t2 , t3 , l - > origin ) ;
r_refdef . flipcull = 0 ;
break ;
}
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if ( lighttype & ( LSHADER_SPOT | LSHADER_ORTHO ) )
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{
r_refdef . pxrect . x = ( SHADOWMAP_SIZE - smsize ) / 2 ;
r_refdef . pxrect . width = smsize ;
r_refdef . pxrect . height = smsize ;
r_refdef . pxrect . y = ( SHADOWMAP_SIZE - smsize ) / 2 ;
r_refdef . pxrect . maxheight = SHADOWMAP_SIZE ;
}
else
{
r_refdef . pxrect . x = ( face % 3 * SHADOWMAP_SIZE ) + ( SHADOWMAP_SIZE - smsize ) / 2 ;
r_refdef . pxrect . width = smsize ;
r_refdef . pxrect . height = smsize ;
r_refdef . pxrect . y = ( ( ( face < 3 ) * SHADOWMAP_SIZE ) + ( SHADOWMAP_SIZE - smsize ) / 2 ) ;
r_refdef . pxrect . maxheight = SHADOWMAP_SIZE * 2 ;
}
R_SetFrustum ( proj , r_refdef . m_view ) ;
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if ( lighttype & LSHADER_ORTHO )
r_refdef . frustum_numplanes = 4 ; //kill the near clip plane - we allow ANYTHING nearer through.
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# ifdef SHADOWDBG_COLOURNOTDEPTH
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BE_SelectMode ( BEM_STANDARD ) ;
# else
BE_SelectMode ( BEM_DEPTHONLY ) ;
# endif
BE_SelectEntity ( & r_worldentity ) ;
switch ( qrenderer )
{
# ifdef GLQUAKE
case QR_OPENGL :
GL_ViewportUpdate ( ) ;
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if ( lighttype & LSHADER_ORTHO )
qglEnable ( GL_DEPTH_CLAMP_ARB ) ;
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GL_CullFace ( SHADER_CULL_FRONT ) ;
GLBE_RenderShadowBuffer ( smesh - > numverts , smesh - > vebo [ 0 ] , smesh - > verts , smesh - > numindicies , smesh - > vebo [ 1 ] , smesh - > indicies ) ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
//FIXME: generate a single commandbuffer (requires full separation of viewprojection matrix)
VKBE_BeginShadowmapFace ( ) ;
VKBE_RenderShadowBuffer ( smesh - > vkbuffer ) ;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
//opengl render targets are upside down - our code kinda assumes gl
r_refdef . pxrect . y = r_refdef . pxrect . maxheight - ( r_refdef . pxrect . y + r_refdef . pxrect . height ) ;
D3D11BE_BeginShadowmapFace ( ) ;
D3D11BE_RenderShadowBuffer ( smesh - > numverts , smesh - > d3d11_vbuffer , smesh - > numindicies , smesh - > d3d11_ibuffer ) ;
break ;
# endif
default :
//FIXME: should be able to merge batches between textures+lightmaps.
for ( tno = 0 ; tno < smesh - > numbatches ; tno + + )
{
if ( ! smesh - > batches [ tno ] . count )
continue ;
tex = cl . worldmodel - > shadowbatches [ tno ] . tex ;
if ( tex - > shader - > flags & ( SHADER_NOSHADOWS | SHADER_NODRAW ) ) //FIXME: shadows not lights
continue ;
BE_DrawMesh_List ( tex - > shader , smesh - > batches [ tno ] . count , smesh - > batches [ tno ] . s , cl . worldmodel - > shadowbatches [ tno ] . vbo , NULL , 0 ) ;
}
break ;
}
//fixme: this walks through the entity lists up to 6 times per frame per entity.
switch ( qrenderer )
{
default :
break ;
# ifdef GLQUAKE
case QR_OPENGL :
GLBE_BaseEntTextures ( ) ;
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if ( lighttype & LSHADER_ORTHO )
qglDisable ( GL_DEPTH_CLAMP_ARB ) ;
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break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
D3D9BE_BaseEntTextures ( ) ;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
D3D11BE_BaseEntTextures ( ) ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
VKBE_BaseEntTextures ( ) ;
break ;
# endif
}
/*
{
int i ;
static float depth [ SHADOWMAP_SIZE * SHADOWMAP_SIZE ] ;
qglReadPixels ( 0 , 0 , smsize , smsize ,
GL_DEPTH_COMPONENT , GL_FLOAT , depth ) ;
for ( i = SHADOWMAP_SIZE * SHADOWMAP_SIZE ; i - - > 0 ; )
{
if ( depth [ i ] = = 1 )
* ( ( unsigned int * ) depth + i ) = 0 ;
else
* ( ( unsigned int * ) depth + i ) = 0xff000000 | ( ( ( ( unsigned char ) ( int ) ( depth [ i ] * 128 ) ) ) * 0x10101 ) ;
}
qglTexImage2D ( GL_TEXTURE_2D , 0 , GL_RGBA ,
smsize , smsize , 0 ,
GL_RGBA , GL_UNSIGNED_BYTE , depth ) ;
qglTexParameteri ( GL_TEXTURE_2D , GL_TEXTURE_MAG_FILTER , GL_LINEAR ) ;
qglTexParameteri ( GL_TEXTURE_2D , GL_TEXTURE_MIN_FILTER , GL_LINEAR ) ;
qglTexParameteri ( GL_TEXTURE_2D , GL_TEXTURE_WRAP_S , GL_CLAMP ) ;
qglTexParameteri ( GL_TEXTURE_2D , GL_TEXTURE_WRAP_T , GL_CLAMP ) ;
}
*/
}
2018-01-22 19:18:04 +00:00
qboolean Sh_GenShadowMap ( dlight_t * l , int lighttype , vec3_t axis [ 3 ] , qbyte * lvis , int smsize )
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{
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int restorefbo = 0 ;
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int f , lf ;
float oprojs [ 16 ] , oprojv [ 16 ] , oview [ 16 ] ;
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pxrect_t oprect ;
shadowmesh_t * smesh ;
2018-01-22 19:18:04 +00:00
qboolean isspot = ! ! ( lighttype & ( LSHADER_SPOT | LSHADER_ORTHO ) ) ;
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int sidevisible ;
int oldflip = r_refdef . flipcull ;
int oldexternalview = r_refdef . externalview ;
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if ( isspot )
{ //spotlights only face forwards. which is side 4. which is annoying.
f = 4 ;
lf = f + 1 ;
sidevisible = 1 < < f ;
}
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else
{
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f = 0 ;
lf = 6 ;
sidevisible = ( 1 < < 6 ) - 1 ;
}
if ( R_CullSphere ( l - > origin , 0 ) )
{ //if the light's center isn't onscreen, cull individual faces
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//FIXME: if the fov is < 90, we need to clip by the near lightplane first
2018-01-22 19:18:04 +00:00
for ( ; f < lf ; f + + )
2016-07-12 00:40:13 +00:00
{
vec4_t planes [ 5 ] ;
float dist ;
int fp , lp ;
Sh_LightFrustumPlanes ( l , axis , planes , f ) ;
for ( fp = 0 ; fp < r_refdef . frustum_numplanes ; fp + + )
{
vec3_t nearest ;
//make a guess based upon the frustum plane
VectorMA ( l - > origin , l - > radius , r_refdef . frustum [ fp ] . normal , nearest ) ;
//clip that point to the various planes
for ( lp = 0 ; lp < 5 ; lp + + )
{
dist = DotProduct ( nearest , planes [ lp ] ) - planes [ lp ] [ 3 ] ;
if ( dist < 0 )
VectorMA ( nearest , dist , planes [ lp ] , nearest ) ;
}
// P_RunParticleEffect(nearest, vec3_origin, 15, 1);
//give up if the best point for any frustum plane is offscreen
dist = DotProduct ( r_refdef . frustum [ fp ] . normal , nearest ) - r_refdef . frustum [ fp ] . dist ;
if ( dist < = 0 )
break ;
}
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if ( fp ! = r_refdef . frustum_numplanes )
sidevisible & = ~ ( 1u < < f ) ;
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}
}
//if nothing is visible, then there's no point generating any shadowmaps at all...
if ( ! sidevisible )
return false ;
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memcpy ( oprojs , r_refdef . m_projection_std , sizeof ( oprojs ) ) ;
memcpy ( oprojv , r_refdef . m_projection_view , sizeof ( oprojv ) ) ;
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memcpy ( oview , r_refdef . m_view , sizeof ( oview ) ) ;
oprect = r_refdef . pxrect ;
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smesh = SHM_BuildShadowMesh ( l , lvis , ( lighttype & LSHADER_ORTHO ) ? SMT_ORTHO : SMT_SHADOWMAP ) ;
2016-07-12 00:40:13 +00:00
2018-01-22 19:18:04 +00:00
if ( lighttype & LSHADER_SPOT )
Matrix4x4_CM_Projection_Far ( r_refdef . m_projection_std , l - > fov , l - > fov , r_shadow_shadowmapping_nearclip . value , l - > radius , false ) ;
else if ( lighttype & LSHADER_ORTHO )
{
float xmin = - l - > radius ;
float ymin = - l - > radius ;
float znear = - l - > radius ;
float xmax = l - > radius ;
float ymax = l - > radius ;
float zfar = l - > radius ;
Matrix4x4_CM_Orthographic ( r_refdef . m_projection_std , xmin , xmax , ymax , ymin , znear , zfar ) ;
}
else
Matrix4x4_CM_Projection_Far ( r_refdef . m_projection_std , 90 , 90 , r_shadow_shadowmapping_nearclip . value , l - > radius , false ) ;
memcpy ( r_refdef . m_projection_view , r_refdef . m_projection_std , sizeof ( r_refdef . m_projection_view ) ) ;
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switch ( qrenderer )
{
default :
return false ;
# ifdef GLQUAKE
case QR_OPENGL :
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if ( ! GLBE_BeginShadowMap ( isspot , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 3 ) ) , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 2 ) ) , & restorefbo ) )
return false ;
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break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
if ( ! D3D11_BeginShadowMap ( isspot , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 3 ) ) , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 2 ) ) ) )
return false ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
if ( ! VKBE_BeginShadowmap ( isspot , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 3 ) ) , ( isspot ? SHADOWMAP_SIZE : ( SHADOWMAP_SIZE * 2 ) ) ) )
return false ;
break ;
# endif
}
r_refdef . externalview = true ; //never any viewmodels
/*generate faces*/
for ( f = 0 ; f < 6 ; f + + )
{
if ( sidevisible & ( 1u < < f ) )
{
RQuantAdd ( RQUANT_SHADOWSIDES , 1 ) ;
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Sh_GenShadowFace ( l , axis , lighttype , smesh , f , smsize , r_refdef . m_projection_std ) ;
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}
}
memcpy ( r_refdef . m_view , oview , sizeof ( r_refdef . m_view ) ) ;
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memcpy ( r_refdef . m_projection_std , oprojs , sizeof ( r_refdef . m_projection_std ) ) ;
memcpy ( r_refdef . m_projection_view , oprojv , sizeof ( r_refdef . m_projection_view ) ) ;
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r_refdef . pxrect = oprect ;
r_refdef . flipcull = oldflip ;
r_refdef . externalview = oldexternalview ;
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R_SetFrustum ( r_refdef . m_projection_std , r_refdef . m_view ) ;
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switch ( qrenderer )
{
# ifdef GLQUAKE
case QR_OPENGL :
/*end framebuffer*/
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GLBE_EndShadowMap ( restorefbo ) ;
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GL_ViewportUpdate ( ) ;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
D3D11_EndShadowMap ( ) ;
D3D11BE_DoneShadows ( ) ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
VKBE_DoneShadows ( ) ;
break ;
# endif
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default :
( void ) restorefbo ;
break ;
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}
return true ;
}
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qboolean Sh_GenerateShadowMap ( dlight_t * l , int lighttype )
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{
int smsize ;
qbyte * vvis = r_refdef . scenevis ;
qbyte * lvis ;
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int texwidth , texheight ;
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/* if (Sh_ScissorForBox(mins, maxs, &rect))
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_SCISSOR , 1 ) ;
return ;
} */
if ( vvis )
{
if ( ! l - > rebuildcache & & l - > worldshadowmesh )
{
lvis = l - > worldshadowmesh - > litleaves ;
//fixme: check head node first?
if ( ! Sh_LeafInView ( l - > worldshadowmesh - > litleaves , vvis ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return false ;
}
}
else
{
int clus ;
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , l - > origin ) ;
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lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
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//FIXME: surely we can use the phs for this?
if ( ! Sh_VisOverlaps ( lvis , vvis ) ) //The two viewing areas do not intersect.
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return false ;
}
}
}
else
lvis = NULL ;
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if ( lighttype & ( LSHADER_SPOT | LSHADER_ORTHO ) )
texwidth = texheight = smsize = SHADOWMAP_SIZE ;
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else
{
//Stolen from DP. Actually, LH pasted it to me in IRC.
vec3_t nearestpoint ;
vec3_t d ;
float distance , lodlinear ;
nearestpoint [ 0 ] = bound ( l - > origin [ 0 ] - l - > radius , r_origin [ 0 ] , l - > origin [ 0 ] + l - > radius ) ;
nearestpoint [ 1 ] = bound ( l - > origin [ 1 ] - l - > radius , r_origin [ 1 ] , l - > origin [ 1 ] + l - > radius ) ;
nearestpoint [ 2 ] = bound ( l - > origin [ 2 ] - l - > radius , r_origin [ 2 ] , l - > origin [ 2 ] + l - > radius ) ;
VectorSubtract ( nearestpoint , r_origin , d ) ;
distance = VectorLength ( d ) ;
lodlinear = ( l - > radius * r_shadow_shadowmapping_precision . value ) / sqrt ( max ( 1.0f , distance / l - > radius ) ) ;
smsize = bound ( 16 , lodlinear , SHADOWMAP_SIZE ) ;
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texwidth = smsize * 3 ;
texheight = smsize * 2 ;
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}
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switch ( qrenderer )
{
# ifdef GLQUAKE
case QR_OPENGL :
GLBE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
# endif
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# ifdef D3D11QUAKE
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case QR_DIRECT3D11 :
D3D11BE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
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# endif
# ifdef VKQUAKE
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case QR_VULKAN :
VKBE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
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# endif
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default :
( void ) texwidth ;
( void ) texheight ;
break ;
}
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//fixme: light rotation
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if ( ! Sh_GenShadowMap ( l , lighttype , l - > axis , lvis , smsize ) )
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return false ; //didn't need to do anything
return true ;
}
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static void Sh_DrawShadowMapLight ( dlight_t * l , vec3_t colour , vec3_t axis [ 3 ] , qbyte * vvis )
{
vec3_t mins , maxs ;
qbyte * lvis ;
srect_t rect ;
int smsize ;
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int lighttype ;
int texwidth , texheight ;
if ( l - > fov ! = 0 )
lighttype = LSHADER_SMAP | LSHADER_SPOT ;
# ifdef LFLAG_ORTHO
else if ( l - > flags & LFLAG_ORTHO )
lighttype = LSHADER_SMAP | LSHADER_ORTHO ;
# endif
else
lighttype = LSHADER_SMAP ;
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if ( R_CullSphere ( l - > origin , l - > radius ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_FRUSTUM , 1 ) ;
return ; //this should be the more common case
}
mins [ 0 ] = l - > origin [ 0 ] - l - > radius ;
mins [ 1 ] = l - > origin [ 1 ] - l - > radius ;
mins [ 2 ] = l - > origin [ 2 ] - l - > radius ;
maxs [ 0 ] = l - > origin [ 0 ] + l - > radius ;
maxs [ 1 ] = l - > origin [ 1 ] + l - > radius ;
maxs [ 2 ] = l - > origin [ 2 ] + l - > radius ;
if ( Sh_ScissorForBox ( mins , maxs , & rect ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_SCISSOR , 1 ) ;
return ;
}
if ( vvis )
{
if ( ! l - > rebuildcache & & l - > worldshadowmesh )
{
lvis = l - > worldshadowmesh - > litleaves ;
//fixme: check head node first?
if ( ! Sh_LeafInView ( l - > worldshadowmesh - > litleaves , vvis ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return ;
}
}
else
{
int clus ;
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , l - > origin ) ;
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lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
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//FIXME: surely we can use the phs for this?
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if ( cl . worldmodel - > funcs . ClustersInSphere )
lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , l - > origin , l - > radius , & lvisb2 , lvis ) ;
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if ( ! Sh_VisOverlaps ( lvis , vvis ) ) //The two viewing areas do not intersect.
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return ;
}
}
}
else
lvis = NULL ;
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if ( lighttype & LSHADER_SPOT )
{
smsize = SHADOWMAP_SIZE ; //spot lights or ortho lights can just use the full thing.
texwidth = smsize ;
texheight = smsize ;
}
else if ( lighttype & LSHADER_ORTHO )
{
smsize = SHADOWMAP_SIZE ; //spot lights or ortho lights can just use the full thing.
texwidth = smsize ;
texheight = smsize ;
}
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else
{
//Stolen from DP. Actually, LH pasted it to me in IRC.
vec3_t nearestpoint ;
vec3_t d ;
float distance , lodlinear ;
nearestpoint [ 0 ] = bound ( l - > origin [ 0 ] - l - > radius , r_origin [ 0 ] , l - > origin [ 0 ] + l - > radius ) ;
nearestpoint [ 1 ] = bound ( l - > origin [ 1 ] - l - > radius , r_origin [ 1 ] , l - > origin [ 1 ] + l - > radius ) ;
nearestpoint [ 2 ] = bound ( l - > origin [ 2 ] - l - > radius , r_origin [ 2 ] , l - > origin [ 2 ] + l - > radius ) ;
VectorSubtract ( nearestpoint , r_origin , d ) ;
distance = VectorLength ( d ) ;
lodlinear = ( l - > radius * r_shadow_shadowmapping_precision . value ) / sqrt ( max ( 1.0f , distance / l - > radius ) ) ;
smsize = bound ( 16 , lodlinear , SHADOWMAP_SIZE ) ;
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texwidth = smsize * 3 ;
texheight = smsize * 2 ;
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}
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switch ( qrenderer )
{
# ifdef GLQUAKE
case QR_OPENGL :
GLBE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
# endif
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# ifdef D3D11QUAKE
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case QR_DIRECT3D11 :
D3D11BE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
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# endif
# ifdef VKQUAKE
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case QR_VULKAN :
VKBE_SetupForShadowMap ( l , texwidth , texheight , ( smsize - 4 ) / ( float ) SHADOWMAP_SIZE ) ;
break ;
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# endif
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default :
( void ) texwidth ;
( void ) texheight ;
break ;
}
2016-07-12 00:40:13 +00:00
2018-01-22 19:18:04 +00:00
if ( ! BE_SelectDLight ( l , colour , axis , lighttype ) )
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return ;
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if ( ! Sh_GenShadowMap ( l , lighttype , axis , lvis , smsize ) )
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return ;
RQuantAdd ( RQUANT_RTLIGHT_DRAWN , 1 ) ;
//may as well use scissors
BE_Scissor ( & rect ) ;
BE_SelectEntity ( & r_worldentity ) ;
BE_SelectMode ( BEM_LIGHT ) ;
Sh_DrawEntLighting ( l , colour ) ;
}
/*
draws faces facing the light
Note : Backend mode must have been selected in advance , as must the light to light from
*/
static void Sh_DrawEntLighting ( dlight_t * light , vec3_t colour )
{
int tno ;
texture_t * tex ;
shader_t * shader ;
shadowmesh_t * sm ;
sm = light - > worldshadowmesh ;
if ( light - > rebuildcache )
sm = & sh_tempshmesh ;
if ( sm )
{
for ( tno = 0 ; tno < sm - > numbatches ; tno + + )
{
if ( ! sm - > batches [ tno ] . count )
continue ;
tex = cl . worldmodel - > shadowbatches [ tno ] . tex ;
if ( cl . worldmodel - > fromgame = = fg_quake2 )
shader = R_TextureAnimation_Q2 ( tex ) - > shader ;
else
shader = R_TextureAnimation ( false , tex ) - > shader ;
if ( shader - > flags & ( SHADER_NODLIGHT | SHADER_NODRAW | SHADER_SKY ) )
continue ;
//FIXME: it should be worth building a dedicated ebo, for static ones
BE_DrawMesh_List ( shader , sm - > batches [ tno ] . count , sm - > batches [ tno ] . s , cl . worldmodel - > shadowbatches [ tno ] . vbo , NULL , 0 ) ;
RQuantAdd ( RQUANT_LITFACES , sm - > batches [ tno ] . count ) ;
}
switch ( qrenderer )
{
default :
break ;
# ifdef GLQUAKE
case QR_OPENGL :
GLBE_BaseEntTextures ( ) ;
break ;
# endif
# ifdef VKQUAKE
case QR_VULKAN :
VKBE_BaseEntTextures ( ) ;
break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
D3D9BE_BaseEntTextures ( ) ;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
D3D11BE_BaseEntTextures ( ) ;
break ;
# endif
}
}
}
# ifdef GLQUAKE
/*Fixme: this is brute forced*/
# ifdef warningmsg
# pragma warningmsg("brush shadows are bruteforced")
# endif
static void Sh_DrawBrushModelShadow ( dlight_t * dl , entity_t * e )
{
int v ;
float * v1 , * v2 ;
vec3_t v3 , v4 ;
vec3_t lightorg ;
int i ;
model_t * model ;
msurface_t * surf ;
if ( qrenderer ! = QR_OPENGL )
return ;
if ( BE_LightCullModel ( e - > origin , e - > model ) )
return ;
RotateLightVector ( ( void * ) e - > axis , e - > origin , dl - > origin , lightorg ) ;
BE_SelectEntity ( e ) ;
GL_DeselectVAO ( ) ;
GL_SelectVBO ( 0 ) ;
GL_SelectEBO ( 0 ) ;
qglEnableClientState ( GL_VERTEX_ARRAY ) ;
2017-10-13 17:50:28 +00:00
# ifdef BEF_PUSHDEPTH
GLBE_PolyOffsetStencilShadow ( r_pushdepth ) ;
# else
GLBE_PolyOffsetStencilShadow ( ) ;
# endif
2016-07-12 00:40:13 +00:00
model = e - > model ;
surf = model - > surfaces + model - > firstmodelsurface ;
for ( i = 0 ; i < model - > nummodelsurfaces ; i + + , surf + + )
{
if ( surf - > flags & SURF_PLANEBACK )
{ //inverted normal.
if ( DotProduct ( surf - > plane - > normal , lightorg ) - surf - > plane - > dist > = - 0.1 )
continue ;
}
else
{
if ( DotProduct ( surf - > plane - > normal , lightorg ) - surf - > plane - > dist < = 0.1 )
continue ;
}
if ( surf - > flags & ( SURF_DRAWALPHA | SURF_DRAWTILED ) )
{ // no shadows
continue ;
}
if ( ! surf - > mesh )
continue ;
//front face
qglVertexPointer ( 3 , GL_FLOAT , sizeof ( vecV_t ) , surf - > mesh - > xyz_array ) ;
qglDrawArrays ( GL_POLYGON , 0 , surf - > mesh - > numvertexes ) ;
// qglDrawRangeElements(GL_TRIANGLES, 0, surf->mesh->numvertexes, surf->mesh->numindexes, GL_INDEX_TYPE, surf->mesh->indexes);
RQuantAdd ( RQUANT_SHADOWINDICIES , surf - > mesh - > numvertexes ) ;
for ( v = 0 ; v < surf - > mesh - > numvertexes ; v + + )
{
//border
v1 = surf - > mesh - > xyz_array [ v ] ;
v2 = surf - > mesh - > xyz_array [ ( v + 1 ) % surf - > mesh - > numvertexes ] ;
//get positions of v3 and v4 based on the light position
v3 [ 0 ] = ( v1 [ 0 ] - lightorg [ 0 ] ) ;
v3 [ 1 ] = ( v1 [ 1 ] - lightorg [ 1 ] ) ;
v3 [ 2 ] = ( v1 [ 2 ] - lightorg [ 2 ] ) ;
VectorNormalizeFast ( v3 ) ;
VectorScale ( v3 , PROJECTION_DISTANCE , v3 ) ;
v4 [ 0 ] = ( v2 [ 0 ] - lightorg [ 0 ] ) ;
v4 [ 1 ] = ( v2 [ 1 ] - lightorg [ 1 ] ) ;
v4 [ 2 ] = ( v2 [ 2 ] - lightorg [ 2 ] ) ;
VectorNormalizeFast ( v4 ) ;
VectorScale ( v4 , PROJECTION_DISTANCE , v4 ) ;
//Now draw the quad from the two verts to the projected light
//verts
qglBegin ( GL_QUAD_STRIP ) ;
qglVertex3fv ( v1 ) ;
qglVertex3f ( v1 [ 0 ] + v3 [ 0 ] , v1 [ 1 ] + v3 [ 1 ] , v1 [ 2 ] + v3 [ 2 ] ) ;
qglVertex3fv ( v2 ) ;
qglVertex3f ( v2 [ 0 ] + v4 [ 0 ] , v2 [ 1 ] + v4 [ 1 ] , v2 [ 2 ] + v4 [ 2 ] ) ;
qglEnd ( ) ;
}
//back
//the same applies as earlier
qglBegin ( GL_POLYGON ) ;
for ( v = surf - > mesh - > numvertexes - 1 ; v > = 0 ; v - - )
{
v1 = surf - > mesh - > xyz_array [ v ] ;
v3 [ 0 ] = ( v1 [ 0 ] - lightorg [ 0 ] ) ;
v3 [ 1 ] = ( v1 [ 1 ] - lightorg [ 1 ] ) ;
v3 [ 2 ] = ( v1 [ 2 ] - lightorg [ 2 ] ) ;
VectorNormalizeFast ( v3 ) ;
VectorScale ( v3 , PROJECTION_DISTANCE , v3 ) ;
qglVertex3f ( v1 [ 0 ] + v3 [ 0 ] , v1 [ 1 ] + v3 [ 1 ] , v1 [ 2 ] + v3 [ 2 ] ) ;
}
qglEnd ( ) ;
}
2017-10-31 22:52:58 +00:00
# ifdef BEF_PUSHDEPTH
2016-07-12 00:40:13 +00:00
GLBE_PolyOffsetStencilShadow ( false ) ;
2017-10-31 22:52:58 +00:00
# else
GLBE_PolyOffsetStencilShadow ( ) ;
# endif
2016-07-12 00:40:13 +00:00
}
# endif
# if defined(GLQUAKE) || defined(D3D9QUAKE)
/*when this is called, the gl state has been set up to draw the stencil volumes using whatever extensions we have
if secondside is set , then the gpu sucks and we ' re drawing stuff the slow 2 - pass way , and this is the second pass .
*/
static void Sh_DrawStencilLightShadows ( dlight_t * dl , qbyte * lvis , qbyte * vvis , qboolean secondside )
{
struct shadowmesh_s * sm ;
# ifdef GLQUAKE
extern cvar_t gl_part_flame ;
int i ;
entity_t * ent ;
model_t * emodel ;
# endif
2017-10-31 22:52:58 +00:00
sm = SHM_BuildShadowMesh ( dl , lvis , SMT_STENCILVOLUME ) ;
2016-07-12 00:40:13 +00:00
if ( ! sm )
{
# ifdef GLQUAKE
Sh_DrawBrushModelShadow ( dl , & r_worldentity ) ;
# endif
}
else
{
switch ( qrenderer )
{
case QR_NONE :
case QR_SOFTWARE :
default :
break ;
# ifdef D3D11QUAKE
// case QR_DIRECT3D11:
// D3D11BE_RenderShadowBuffer(sm->numverts, sm->d3d11_vbuffer, sm->numindicies, sm->d3d11_ibuffer);
// break;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
D3D9BE_RenderShadowBuffer ( sm - > numverts , sm - > d3d9_vbuffer , sm - > numindicies , sm - > d3d9_ibuffer ) ;
break ;
# endif
# ifdef GLQUAKE
case QR_OPENGL :
GLBE_RenderShadowBuffer ( sm - > numverts , sm - > vebo [ 0 ] , sm - > verts , sm - > numindicies , sm - > vebo [ 1 ] , sm - > indicies ) ;
break ;
# endif
# ifdef VKQUAKE
// case QR_VULKAN:
// VKBE_RenderShadowBuffer(sm->numverts, sm->vebo[0], sm->verts, sm->numindicies, sm->vebo[1], sm->indicies);
// break;
# endif
}
}
if ( ! r_drawentities . value )
return ;
# ifdef GLQUAKE
if ( qrenderer ! = QR_OPENGL )
return ; //FIXME: still uses glBegin specifics.
if ( gl_config_nofixedfunc )
return ; /*too lazy to use shaders*/
if ( gl_config_gles )
return ; //FIXME: uses glBegin
// draw sprites seperately, because of alpha blending
for ( i = 0 ; i < cl_numvisedicts ; i + + )
{
ent = & cl_visedicts [ i ] ;
if ( ent - > rtype ! = RT_MODEL )
continue ;
if ( ent - > flags & ( RF_NOSHADOW | Q2RF_BEAM ) )
continue ;
if ( ent - > keynum = = dl - > key & & ent - > keynum )
continue ;
emodel = ent - > model ;
if ( ! emodel )
continue ;
if ( cls . allow_anyparticles ) //allowed or static
{
2016-10-22 07:06:51 +00:00
if ( emodel - > engineflags & MDLF_EMITREPLACE )
2016-07-12 00:40:13 +00:00
{
if ( gl_part_flame . value )
continue ;
}
}
if ( emodel - > loadstate = = MLS_NOTLOADED )
{
if ( ! Mod_LoadModel ( emodel , MLV_WARN ) )
continue ;
}
if ( emodel - > loadstate ! = MLS_LOADED )
continue ;
switch ( emodel - > type )
{
case mod_alias :
2018-09-23 19:35:24 +00:00
if ( r_drawentities . ival = = 3 )
continue ;
2016-07-12 00:40:13 +00:00
R_DrawGAliasShadowVolume ( ent , dl - > origin , dl - > radius ) ;
break ;
case mod_brush :
2018-09-23 19:35:24 +00:00
if ( r_drawentities . ival = = 2 )
continue ;
2016-07-12 00:40:13 +00:00
Sh_DrawBrushModelShadow ( dl , ent ) ;
break ;
case mod_sprite : //never any shadows on sprites, it doesn't really make sense.
break ;
default :
break ;
}
}
BE_SelectEntity ( & r_worldentity ) ;
# endif
}
//draws a light using stencil shadows.
//redraws world geometry up to 3 times per light...
static qboolean Sh_DrawStencilLight ( dlight_t * dl , vec3_t colour , vec3_t axis [ 3 ] , qbyte * vvis )
{
int sref ;
int clus ;
qbyte * lvis ;
srect_t rect ;
vec3_t mins ;
vec3_t maxs ;
if ( R_CullSphere ( dl - > origin , dl - > radius ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_FRUSTUM , 1 ) ;
return false ; //this should be the more common case
}
mins [ 0 ] = dl - > origin [ 0 ] - dl - > radius ;
mins [ 1 ] = dl - > origin [ 1 ] - dl - > radius ;
mins [ 2 ] = dl - > origin [ 2 ] - dl - > radius ;
maxs [ 0 ] = dl - > origin [ 0 ] + dl - > radius ;
maxs [ 1 ] = dl - > origin [ 1 ] + dl - > radius ;
maxs [ 2 ] = dl - > origin [ 2 ] + dl - > radius ;
if ( ! dl - > rebuildcache )
{
//fixme: check head node first?
if ( ! Sh_LeafInView ( dl - > worldshadowmesh - > litleaves , vvis ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return false ;
}
lvis = NULL ;
}
else
{
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
2017-06-21 01:24:25 +00:00
lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
2017-10-31 22:52:58 +00:00
// if (cl.worldmodel->funcs.ClustersInSphere)
// lvis = cl.worldmodel->funcs.ClustersInSphere(cl.worldmodel, dl->origin, dl->radius, &lvisb2, lvis);
2016-07-12 00:40:13 +00:00
if ( ! Sh_VisOverlaps ( lvis , vvis ) ) //The two viewing areas do not intersect.
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return false ;
}
}
//sets up the gl scissor (and culls to view)
if ( Sh_ScissorForBox ( mins , maxs , & rect ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_SCISSOR , 1 ) ;
return false ; //this doesn't cull often.
}
RQuantAdd ( RQUANT_RTLIGHT_DRAWN , 1 ) ;
BE_SelectDLight ( dl , colour , axis , LSHADER_STANDARD ) ;
BE_SelectMode ( BEM_STENCIL ) ;
//The backend doesn't maintain scissor state.
//The backend doesn't maintain stencil test state either - it needs to be active for more than just stencils, or disabled. its awkward.
BE_Scissor ( & rect ) ;
switch ( qrenderer )
{
default :
( void ) sref ;
break ;
# ifdef GLQUAKE
case QR_OPENGL :
{
int sfrontfail ;
int sbackfail ;
qglEnable ( GL_STENCIL_TEST ) ;
//FIXME: is it practical to test to see if scissors allow not clearing the stencil buffer?
/*we don't need all that much stencil buffer depth, and if we don't get enough or have dodgy volumes, wrap if we can*/
# ifdef I_LIVE_IN_A_FREE_COUNTRY
sref = 0 ;
sbackfail = GL_INCR ;
sfrontfail = GL_DECR ;
if ( gl_config . ext_stencil_wrap )
{ //minimise damage...
sbackfail = GL_INCR_WRAP_EXT ;
sfrontfail = GL_DECR_WRAP_EXT ;
}
# else
sref = ( 1 < < gl_stencilbits ) - 1 ; /*this is halved for two-sided stencil support, just in case there's no wrap support*/
sbackfail = GL_DECR ;
sfrontfail = GL_INCR ;
if ( gl_config . ext_stencil_wrap )
{ //minimise damage...
sbackfail = GL_DECR_WRAP_EXT ;
sfrontfail = GL_INCR_WRAP_EXT ;
}
# endif
//our stencil writes.
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if ( gl_config . arb_depth_clamp & & r_refdef . maxdist ! = 0 )
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qglEnable ( GL_DEPTH_CLAMP_ARB ) ;
#if 0 //def _DEBUG
// if (r_shadows.value == 666) //testing (visible shadow volumes)
{
qglColorMask ( GL_TRUE , GL_TRUE , GL_TRUE , GL_TRUE ) ;
qglColor4f ( dl - > color [ 0 ] , dl - > color [ 1 ] , dl - > color [ 2 ] , 1 ) ;
qglDisable ( GL_STENCIL_TEST ) ;
// qglEnable(GL_POLYGON_OFFSET_FILL);
// qglPolygonOffset(-1, -1);
// qglPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
Sh_DrawStencilLightShadows ( dl , lvis , vvis , false ) ;
// qglDisable(GL_POLYGON_OFFSET_FILL);
// qglPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
}
# endif
if ( qglStencilOpSeparateATI )
{
//ATI/GLES/ARB method
sref / = 2 ;
qglClearStencil ( sref ) ;
qglClear ( GL_STENCIL_BUFFER_BIT ) ;
GL_CullFace ( 0 ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
qglStencilOpSeparateATI ( GL_BACK , GL_KEEP , sbackfail , GL_KEEP ) ;
qglStencilOpSeparateATI ( GL_FRONT , GL_KEEP , sfrontfail , GL_KEEP ) ;
Sh_DrawStencilLightShadows ( dl , lvis , vvis , false ) ;
qglStencilOpSeparateATI ( GL_FRONT_AND_BACK , GL_KEEP , GL_KEEP , GL_KEEP ) ;
GL_CullFace ( SHADER_CULL_FRONT ) ;
qglStencilFunc ( GL_EQUAL , sref , ~ 0 ) ;
}
else if ( qglActiveStencilFaceEXT )
{
//Nvidia-specific method.
sref / = 2 ;
qglClearStencil ( sref ) ;
qglClear ( GL_STENCIL_BUFFER_BIT ) ;
GL_CullFace ( 0 ) ;
qglEnable ( GL_STENCIL_TEST_TWO_SIDE_EXT ) ;
qglActiveStencilFaceEXT ( GL_BACK ) ;
qglStencilOp ( GL_KEEP , sbackfail , GL_KEEP ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
qglActiveStencilFaceEXT ( GL_FRONT ) ;
qglStencilOp ( GL_KEEP , sfrontfail , GL_KEEP ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
Sh_DrawStencilLightShadows ( dl , lvis , vvis , false ) ;
qglActiveStencilFaceEXT ( GL_BACK ) ;
qglStencilOp ( GL_KEEP , GL_KEEP , GL_KEEP ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
qglActiveStencilFaceEXT ( GL_FRONT ) ;
qglStencilOp ( GL_KEEP , GL_KEEP , GL_KEEP ) ;
qglStencilFunc ( GL_EQUAL , sref , ~ 0 ) ;
qglDisable ( GL_STENCIL_TEST_TWO_SIDE_EXT ) ;
}
else //your graphics card sucks and lacks efficient stencil shadow techniques.
{ //centered around 0. Will only be increased then decreased less.
qglClearStencil ( sref ) ;
qglClear ( GL_STENCIL_BUFFER_BIT ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
GL_CullFace ( SHADER_CULL_BACK ) ;
qglStencilOp ( GL_KEEP , sbackfail , GL_KEEP ) ;
Sh_DrawStencilLightShadows ( dl , lvis , vvis , false ) ;
GL_CullFace ( SHADER_CULL_FRONT ) ;
qglStencilOp ( GL_KEEP , sfrontfail , GL_KEEP ) ;
Sh_DrawStencilLightShadows ( dl , lvis , vvis , true ) ;
qglStencilOp ( GL_KEEP , GL_KEEP , GL_KEEP ) ;
qglStencilFunc ( GL_EQUAL , sref , ~ 0 ) ;
}
if ( gl_config . arb_depth_clamp )
qglDisable ( GL_DEPTH_CLAMP_ARB ) ;
//end stencil writing.
BE_SelectMode ( BEM_LIGHT ) ;
Sh_DrawEntLighting ( dl , colour ) ;
qglDisable ( GL_STENCIL_TEST ) ;
qglStencilFunc ( GL_ALWAYS , 0 , ~ 0 ) ;
}
break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
sref = ( 1 < < 8 ) - 1 ;
sref / = 2 ;
/*clear the stencil buffer*/
IDirect3DDevice9_Clear ( pD3DDev9 , 0 , NULL , D3DCLEAR_STENCIL , D3DCOLOR_XRGB ( 0 , 0 , 0 ) , 1.0f , sref ) ;
/*set up 2-sided stenciling*/
D3D9BE_Cull ( 0 ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILENABLE , true ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILFUNC , D3DCMP_ALWAYS ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_TWOSIDEDSTENCILMODE , true ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILFAIL , D3DSTENCILOP_KEEP ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILZFAIL , D3DSTENCILOP_DECR ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILPASS , D3DSTENCILOP_KEEP ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILFUNC , D3DCMP_ALWAYS ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_CCW_STENCILFAIL , D3DSTENCILOP_KEEP ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_CCW_STENCILZFAIL , D3DSTENCILOP_INCR ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_CCW_STENCILPASS , D3DSTENCILOP_KEEP ) ;
/*draw the shadows*/
Sh_DrawStencilLightShadows ( dl , lvis , vvis , false ) ;
//disable stencil writing
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILZFAIL , D3DSTENCILOP_KEEP ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_TWOSIDEDSTENCILMODE , false ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILFUNC , D3DCMP_EQUAL ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILREF , sref ) ;
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILMASK , ~ 0 ) ;
/*draw the light*/
BE_SelectMode ( BEM_LIGHT ) ;
Sh_DrawEntLighting ( dl , colour ) ;
/*okay, no more stencil stuff*/
IDirect3DDevice9_SetRenderState ( pD3DDev9 , D3DRS_STENCILENABLE , false ) ;
break ;
# endif
}
return true ;
}
# else
# define Sh_DrawStencilLight Sh_DrawShadowlessLight
# endif
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qboolean Sh_CullLight ( dlight_t * dl , qbyte * vvis )
{
if ( R_CullSphere ( dl - > origin , dl - > radius ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_FRUSTUM , 1 ) ;
return true ; //this should be the more common case
}
if ( ! dl - > rebuildcache )
{
//fixme: check head node first?
if ( ! Sh_LeafInView ( dl - > worldshadowmesh - > litleaves , vvis ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return true ;
}
}
else
{
int clus ;
qbyte * lvis ;
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
// if (cl.worldmodel->funcs.ClustersInSphere)
// lvis = cl.worldmodel->funcs.ClustersInSphere(cl.worldmodel, dl->origin, dl->radius, &lvisb2, lvis);
SHM_BuildShadowMesh ( dl , lvis , SMT_DEFERRED ) ;
if ( ! Sh_VisOverlaps ( lvis , vvis ) ) //The two viewing areas do not intersect.
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return true ;
}
}
return false ; //please draw this...
}
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static void Sh_DrawShadowlessLight ( dlight_t * dl , vec3_t colour , vec3_t axis [ 3 ] , qbyte * vvis )
{
vec3_t mins , maxs ;
srect_t rect ;
if ( R_CullSphere ( dl - > origin , dl - > radius ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_FRUSTUM , 1 ) ;
return ; //this should be the more common case
}
if ( ! dl - > rebuildcache )
{
//fixme: check head node first?
if ( ! Sh_LeafInView ( dl - > worldshadowmesh - > litleaves , vvis ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return ;
}
}
else
{
int clus ;
qbyte * lvis ;
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if ( cl . worldmodel - > funcs . ClustersInSphere )
lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , dl - > origin , dl - > radius , & lvisb2 , NULL ) ;
else
{
clus = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , clus , & lvisb , PVM_FAST ) ;
}
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SHM_BuildShadowMesh ( dl , lvis , SMT_SHADOWLESS ) ;
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if ( ! Sh_VisOverlaps ( lvis , vvis ) ) //The two viewing areas do not intersect.
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_PVS , 1 ) ;
return ;
}
}
mins [ 0 ] = dl - > origin [ 0 ] - dl - > radius ;
mins [ 1 ] = dl - > origin [ 1 ] - dl - > radius ;
mins [ 2 ] = dl - > origin [ 2 ] - dl - > radius ;
maxs [ 0 ] = dl - > origin [ 0 ] + dl - > radius ;
maxs [ 1 ] = dl - > origin [ 1 ] + dl - > radius ;
maxs [ 2 ] = dl - > origin [ 2 ] + dl - > radius ;
//sets up the gl scissor (actually just culls to view)
if ( Sh_ScissorForBox ( mins , maxs , & rect ) )
{
RQuantAdd ( RQUANT_RTLIGHT_CULL_SCISSOR , 1 ) ;
return ; //was culled.
}
//should we actually scissor here? there's not really much point I suppose.
BE_Scissor ( NULL ) ;
RQuantAdd ( RQUANT_RTLIGHT_DRAWN , 1 ) ;
BE_SelectDLight ( dl , colour , axis , dl - > fov ? LSHADER_SPOT : LSHADER_STANDARD ) ;
BE_SelectMode ( BEM_LIGHT ) ;
Sh_DrawEntLighting ( dl , colour ) ;
}
void Sh_DrawCrepuscularLight ( dlight_t * dl , float * colours )
{
# ifdef GLQUAKE
int oldfbo ;
static mesh_t mesh ;
image_t * oldsrccol ;
static vecV_t xyz [ 4 ] =
{
{ - 1 , - 1 , - 1 } ,
{ - 1 , 1 , - 1 } ,
{ 1 , 1 , - 1 } ,
{ 1 , - 1 , - 1 }
} ;
static vec2_t tc [ 4 ] =
{
{ 0 , 0 } ,
{ 0 , 1 } ,
{ 1 , 1 } ,
{ 1 , 0 }
} ;
static index_t idx [ 6 ] =
{
0 , 1 , 2 ,
0 , 2 , 3
} ;
if ( qrenderer ! = QR_OPENGL )
return ;
mesh . numindexes = 6 ;
mesh . numvertexes = 4 ;
mesh . xyz_array = xyz ;
mesh . st_array = tc ;
mesh . indexes = idx ;
/*
a crepuscular light ( seriously , that ' s the correct spelling ) is one that gives ' god rays ' , rather than regular light .
our implementation doesn ' t cast shadows . this allows it to actually be outside the map , and to shine through cloud layers in the sky .
we could cast shadows if the light was actually inside , I suppose .
Anyway , its done using an FBO , where everything but the sky is black ( stuff that occludes the sky is black too ) .
which is then blitted onto the screen in 2 d - space .
*/
/*requires an FBO, as stated above*/
if ( ! gl_config . ext_framebuffer_objects )
return ;
//fixme: we should add an extra few pixels each side to the fbo, to avoid too much weirdness at screen edges.
if ( ! crepuscular_texture_id )
{
/*FIXME: requires npot*/
crepuscular_shader = R_RegisterShader ( " crepuscular_screen " , SUF_NONE ,
" { \n "
" program crepuscular_rays \n "
" { \n "
" map $sourcecolour \n "
" blend add \n "
" } \n "
" } \n "
) ;
crepuscular_texture_id = Image_CreateTexture ( " ***crepusculartexture*** " , NULL , IF_LINEAR | IF_NOMIPMAP | IF_CLAMP | IF_NOGAMMA ) ;
Image_Upload ( crepuscular_texture_id , TF_RGBA32 , NULL , NULL , vid . pixelwidth , vid . pixelheight , IF_LINEAR | IF_NOMIPMAP | IF_CLAMP | IF_NOGAMMA ) ;
}
BE_Scissor ( NULL ) ;
oldfbo = GLBE_FBO_Update ( & crepuscular_fbo , FBO_RB_DEPTH , & crepuscular_texture_id , 1 , r_nulltex , vid . pixelwidth , vid . pixelheight , 0 ) ;
GL_ForceDepthWritable ( ) ;
// qglClearColor(0, 0, 0, 1);
qglClear ( GL_DEPTH_BUFFER_BIT ) ;
BE_SelectMode ( BEM_CREPUSCULAR ) ;
BE_SelectDLight ( dl , colours , dl - > axis , LSHADER_STANDARD ) ;
GLBE_SubmitMeshes ( cl . worldmodel - > batches , SHADER_SORT_PORTAL , SHADER_SORT_BLEND ) ;
GLBE_FBO_Pop ( oldfbo ) ;
oldsrccol = NULL ; //shaderstate.tex_sourcecol;
GLBE_FBO_Sources ( crepuscular_texture_id , NULL ) ;
// crepuscular_shader->defaulttextures.base = crepuscular_texture_id;
//shaderstate.tex_sourcecol = oldsrccol;
BE_SelectMode ( BEM_STANDARD ) ;
BE_DrawMesh_Single ( crepuscular_shader , & mesh , NULL , 0 ) ;
GLBE_FBO_Sources ( oldsrccol , NULL ) ;
# endif
}
void Sh_PurgeShadowMeshes ( void )
{
dlight_t * dl ;
int i ;
for ( dl = cl_dlights , i = 0 ; i < cl_maxdlights ; i + + , dl + + )
{
if ( dl - > worldshadowmesh )
{
SH_FreeShadowMesh ( dl - > worldshadowmesh ) ;
dl - > worldshadowmesh = NULL ;
dl - > rebuildcache = true ;
}
}
Z_Free ( edge ) ;
edge = NULL ;
maxedge = 0 ;
}
void R_StaticEntityToRTLight ( int i ) ;
void Sh_PreGenerateLights ( void )
{
unsigned int ignoreflags ;
dlight_t * dl ;
int shadowtype ;
int leaf ;
qbyte * lvis ;
int i ;
r_shadow_realtime_world_lightmaps . value = atof ( r_shadow_realtime_world_lightmaps . string ) ;
if ( ( r_shadow_realtime_dlight . ival | | r_shadow_realtime_world . ival ) & & rtlights_max = = RTL_FIRST )
{
qboolean okay = false ;
if ( ! okay )
okay | = R_LoadRTLights ( ) ;
if ( ! okay )
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okay | = R_ImportRTLights ( Mod_GetEntitiesString ( cl . worldmodel ) ) ;
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if ( ! okay & & r_shadow_realtime_world . ival & & r_shadow_realtime_world_lightmaps . value ! = 1 )
{
r_shadow_realtime_world_lightmaps . value = 1 ;
Con_Printf ( CON_WARNING " No lights detected in map. \n " ) ;
}
for ( i = 0 ; i < cl . num_statics ; i + + )
{
R_StaticEntityToRTLight ( i ) ;
}
}
ignoreflags = ( r_shadow_realtime_world . value ? LFLAG_REALTIMEMODE : LFLAG_NORMALMODE ) ;
for ( dl = cl_dlights + rtlights_first , i = rtlights_first ; i < rtlights_max ; i + + , dl + + )
{
dl - > rebuildcache = true ;
if ( dl - > radius )
{
if ( dl - > flags & ignoreflags )
{
if ( dl - > flags & LFLAG_CREPUSCULAR )
continue ;
if ( ( ( ! dl - > die ) ? ! r_shadow_realtime_world_shadows . ival : ! r_shadow_realtime_dlight_shadows . ival ) | | ( dl - > flags & LFLAG_NOSHADOWS ) )
shadowtype = SMT_SHADOWLESS ;
else if ( dl - > flags & LFLAG_SHADOWMAP | | r_shadow_shadowmapping . ival )
shadowtype = SMT_SHADOWMAP ;
else
shadowtype = SMT_STENCILVOLUME ;
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//shadowless and lights with an ambient term pass through walls, so need to affect EVERY leaf withing the sphere.
2018-03-04 14:41:16 +00:00
if ( ( shadowtype = = SMT_SHADOWLESS | | dl - > lightcolourscales [ 0 ] ) & & cl . worldmodel - > funcs . ClustersInSphere )
2017-12-15 06:56:40 +00:00
lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , dl - > origin , dl - > radius , & lvisb2 , NULL ) ;
else
{ //other lights only want to use the source leaf's pvs (clamped by the sphere)
leaf = cl . worldmodel - > funcs . ClusterForPoint ( cl . worldmodel , dl - > origin ) ;
lvis = cl . worldmodel - > funcs . ClusterPVS ( cl . worldmodel , leaf , & lvisb , PVM_FAST ) ;
if ( cl . worldmodel - > funcs . ClustersInSphere )
lvis = cl . worldmodel - > funcs . ClustersInSphere ( cl . worldmodel , dl - > origin , dl - > radius , & lvisb2 , lvis ) ;
}
2016-07-12 00:40:13 +00:00
2017-10-31 22:52:58 +00:00
SHM_BuildShadowMesh ( dl , lvis , shadowtype ) ;
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continue ;
}
}
if ( dl - > worldshadowmesh )
{
SH_FreeShadowMesh ( dl - > worldshadowmesh ) ;
dl - > worldshadowmesh = NULL ;
dl - > rebuildcache = true ;
}
}
}
void Com_ParseVector ( char * str , vec3_t out )
{
str = COM_Parse ( str ) ;
out [ 0 ] = atof ( com_token ) ;
str = COM_Parse ( str ) ;
out [ 1 ] = atof ( com_token ) ;
str = COM_Parse ( str ) ;
out [ 2 ] = atof ( com_token ) ;
}
void Sh_CheckSettings ( void )
{
qboolean canstencil = false , cansmap = false , canshadowless = false ;
r_shadow_shadowmapping . ival = r_shadow_shadowmapping . value ;
r_shadow_realtime_world . ival = r_shadow_realtime_world . value ;
r_shadow_realtime_dlight . ival = r_shadow_realtime_dlight . value ;
r_shadow_realtime_world_shadows . ival = r_shadow_realtime_world_shadows . value ;
r_shadow_realtime_dlight_shadows . ival = r_shadow_realtime_dlight_shadows . value ;
switch ( qrenderer )
{
# ifdef VKQUAKE
case QR_VULKAN :
canshadowless = true ;
cansmap = true ;
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canstencil = false ;
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break ;
# endif
# ifdef GLQUAKE
case QR_OPENGL :
canshadowless = gl_config . arb_shader_objects | | ! gl_config_nofixedfunc ; //falls back to crappy texture env
if ( gl_config . arb_shader_objects & & gl_config . ext_framebuffer_objects & & gl_config . arb_depth_texture ) // && gl_config.arb_shadow)
cansmap = true ;
2018-01-22 19:18:04 +00:00
else if ( ( r_shadow_realtime_world_shadows . ival | | r_shadow_realtime_dlight_shadows . ival ) & & r_shadow_shadowmapping . ival )
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{
if ( ! gl_config . arb_shader_objects )
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Con_DPrintf ( " Shadowmapping unsupported: No arb_shader_objects \n " ) ;
else if ( ! gl_config . ext_framebuffer_objects )
Con_DPrintf ( " Shadowmapping unsupported: No ext_framebuffer_objects \n " ) ;
else if ( ! gl_config . arb_depth_texture )
Con_DPrintf ( " Shadowmapping unsupported: No arb_depth_texture \n " ) ;
2016-07-12 00:40:13 +00:00
}
if ( gl_stencilbits )
canstencil = true ;
break ;
# endif
# ifdef D3D9QUAKE
case QR_DIRECT3D9 :
canshadowless = true ;
//the code still has a lot of ifdefs, so will crash if you try it in a merged build.
//its not really usable in d3d-only builds either, so no great loss.
// canstencil = true;
break ;
# endif
# ifdef D3D11QUAKE
case QR_DIRECT3D11 :
canshadowless = true ; //all feature levels
/* shadows are buggy right now. tbh they've always been buggy... rendering seems fine, its just the shadowmaps that are bad
if ( D3D11_BeginShadowMap ( 0 , SHADOWMAP_SIZE * 3 , SHADOWMAP_SIZE * 2 ) )
{
D3D11_EndShadowMap ( ) ;
cansmap = true ; //tends to not work properly until feature level 10 for one error or another.
}
*/
break ;
# endif
default :
break ;
}
if ( ! canstencil & & ! cansmap & & ! canshadowless )
{
//can't even do lighting
if ( r_shadow_realtime_world . ival | | r_shadow_realtime_dlight . ival )
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Con_Printf ( " Missing rendering features: realtime lighting is not possible. \n " ) ;
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r_shadow_realtime_world . ival = 0 ;
r_shadow_realtime_dlight . ival = 0 ;
}
else if ( ! canstencil & & ! cansmap )
{
//no shadow methods available at all.
if ( ( r_shadow_realtime_world . ival & & r_shadow_realtime_world_shadows . ival ) | | ( r_shadow_realtime_dlight . ival & & r_shadow_realtime_dlight_shadows . ival ) )
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Con_Printf ( " Missing rendering features: realtime shadows are not possible. \n " ) ;
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r_shadow_realtime_world_shadows . ival = 0 ;
r_shadow_realtime_dlight_shadows . ival = 0 ;
}
else if ( ! canstencil | | ! cansmap )
{
//only one shadow method
if ( ! ! r_shadow_shadowmapping . ival ! = cansmap )
{
if ( r_shadow_shadowmapping . ival & & ( ( r_shadow_realtime_world . ival & & r_shadow_realtime_world_shadows . ival ) | | ( r_shadow_realtime_dlight . ival & & r_shadow_realtime_dlight_shadows . ival ) ) )
2018-01-22 19:18:04 +00:00
Con_Printf ( " Missing rendering features: forcing shadowmapping %s. \n " , cansmap ? " on " : " off " ) ;
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r_shadow_shadowmapping . ival = cansmap ;
}
}
else
{
//both shadow methods available.
}
}
void Sh_CalcPointLight ( vec3_t point , vec3_t light )
{
vec3_t colour ;
dlight_t * dl ;
vec3_t disp ;
float dist ;
float frac ;
int i ;
unsigned int ignoreflags ;
vec3_t norm , impact ;
ignoreflags = ( r_shadow_realtime_world . value ? LFLAG_REALTIMEMODE : LFLAG_NORMALMODE ) ;
VectorClear ( light ) ;
if ( ignoreflags )
for ( dl = cl_dlights + rtlights_first , i = rtlights_first ; i < rtlights_max ; i + + , dl + + )
{
if ( ! ( dl - > flags & ignoreflags ) )
continue ;
if ( dl - > key = = cl . playerview [ 0 ] . viewentity ) //ignore the light if its emitting from the player. generally the player can't *SEE* that light so it still counts.
continue ; //disable this check if this function gets used for anything other than iris adaptation
colour [ 0 ] = dl - > color [ 0 ] ;
colour [ 1 ] = dl - > color [ 1 ] ;
colour [ 2 ] = dl - > color [ 2 ] ;
if ( dl - > style )
{
colour [ 0 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 0 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
colour [ 1 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 1 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
colour [ 2 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 2 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
}
else
{
colour [ 0 ] * = r_lightstylescale . value ;
colour [ 1 ] * = r_lightstylescale . value ;
colour [ 2 ] * = r_lightstylescale . value ;
}
if ( colour [ 0 ] < 0.001 & & colour [ 1 ] < 0.001 & & colour [ 2 ] < 0.001 )
continue ; //just switch these off.
VectorSubtract ( dl - > origin , point , disp ) ;
dist = VectorLength ( disp ) ;
frac = dist / dl - > radius ;
if ( frac > = 1 )
continue ;
//FIXME: this should be affected by the direction.
if ( CL_TraceLine ( point , dl - > origin , impact , norm , NULL ) > = 1 )
VectorMA ( light , 1 - frac , colour , light ) ;
}
}
int drawdlightnum ;
void Sh_DrawLights ( qbyte * vis )
{
vec3_t rotated [ 3 ] ;
vec3_t * axis ;
vec3_t colour ;
dlight_t * dl ;
int i ;
unsigned int ignoreflags ;
if ( r_shadow_realtime_world . modified | |
r_shadow_realtime_world_shadows . modified | |
r_shadow_realtime_dlight . modified | |
r_shadow_realtime_dlight_shadows . modified | |
r_shadow_shadowmapping . modified )
{
r_shadow_realtime_world . modified =
r_shadow_realtime_world_shadows . modified =
r_shadow_realtime_dlight . modified =
r_shadow_realtime_dlight_shadows . modified =
r_shadow_shadowmapping . modified =
false ;
Sh_CheckSettings ( ) ;
//make sure the lighting is reloaded
Sh_PreGenerateLights ( ) ;
}
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if ( r_lightprepass )
return ;
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if ( ! r_shadow_realtime_world . ival & & ! r_shadow_realtime_dlight . ival )
{
return ;
}
ignoreflags = ( r_shadow_realtime_world . value ? LFLAG_REALTIMEMODE : LFLAG_NORMALMODE ) ;
// if (r_refdef.recurse)
for ( dl = cl_dlights + rtlights_first , i = rtlights_first ; i < rtlights_max ; i + + , dl + + )
{
if ( ! dl - > radius )
continue ; //dead
if ( ! ( dl - > flags & ignoreflags ) )
continue ;
colour [ 0 ] = dl - > color [ 0 ] ;
colour [ 1 ] = dl - > color [ 1 ] ;
colour [ 2 ] = dl - > color [ 2 ] ;
if ( dl - > style )
{
colour [ 0 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 0 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
colour [ 1 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 1 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
colour [ 2 ] * = cl_lightstyle [ dl - > style - 1 ] . colours [ 2 ] * d_lightstylevalue [ dl - > style - 1 ] / 255.0f ;
}
else
{
colour [ 0 ] * = r_lightstylescale . value ;
colour [ 1 ] * = r_lightstylescale . value ;
colour [ 2 ] * = r_lightstylescale . value ;
}
colour [ 0 ] * = r_refdef . hdr_value ;
colour [ 1 ] * = r_refdef . hdr_value ;
colour [ 2 ] * = r_refdef . hdr_value ;
if ( colour [ 0 ] < 0.001 & & colour [ 1 ] < 0.001 & & colour [ 2 ] < 0.001 )
continue ; //just switch these off.
if ( ! dl - > lightcolourscales [ 0 ] & & ! dl - > lightcolourscales [ 1 ] & & ! dl - > lightcolourscales [ 2 ] )
continue ; //these lights are just coronas.
if ( dl - > rotation [ 0 ] | | dl - > rotation [ 1 ] | | dl - > rotation [ 2 ] )
{ //auto-rotating (static) rtlights
vec3_t rot ;
vec3_t rotationaxis [ 3 ] ;
VectorScale ( dl - > rotation , cl . time , rot ) ;
AngleVectorsFLU ( rot , rotationaxis [ 0 ] , rotationaxis [ 1 ] , rotationaxis [ 2 ] ) ;
Matrix3_Multiply ( dl - > axis , rotationaxis , rotated ) ;
axis = rotated ;
}
else
axis = dl - > axis ;
drawdlightnum + + ;
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if ( dl - > flags & LFLAG_ORTHO )
{
vec3_t saveorg = { dl - > origin [ 0 ] , dl - > origin [ 1 ] , dl - > origin [ 2 ] } , neworg ;
vec3_t saveaxis [ 3 ] ;
memcpy ( saveaxis , dl - > axis , sizeof ( saveaxis ) ) ;
memcpy ( dl - > axis , axis , sizeof ( saveaxis ) ) ;
VectorMA ( r_origin , dl - > radius / 3 , vpn , neworg ) ;
VectorCopy ( neworg , dl - > origin ) ;
dl - > rebuildcache = true ;
Sh_DrawShadowMapLight ( dl , colour , axis , NULL ) ;
VectorCopy ( saveorg , dl - > origin ) ;
memcpy ( dl - > axis , saveaxis , sizeof ( saveaxis ) ) ;
}
else if ( dl - > flags & LFLAG_CREPUSCULAR )
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Sh_DrawCrepuscularLight ( dl , colour ) ;
else if ( ( ( i > = RTL_FIRST ) ? ! r_shadow_realtime_world_shadows . ival : ! r_shadow_realtime_dlight_shadows . ival ) | | dl - > flags & LFLAG_NOSHADOWS )
{
Sh_DrawShadowlessLight ( dl , colour , axis , vis ) ;
}
else if ( ( dl - > flags & LFLAG_SHADOWMAP ) | | r_shadow_shadowmapping . ival )
{
Sh_DrawShadowMapLight ( dl , colour , axis , vis ) ;
}
else
{
Sh_DrawStencilLight ( dl , colour , axis , vis ) ;
}
}
# ifdef GLQUAKE
if ( gl_config . arb_shader_objects )
{
dlight_t sun = { 0 } ;
vec3_t sundir ;
float dot ;
Com_ParseVector ( r_sun_dir . string , sundir ) ;
Com_ParseVector ( r_sun_colour . string , colour ) ;
//fade it out if we're looking at an angle parallel to it (to avoid nasty visible graduations or backwards rays!)
dot = DotProduct ( vpn , sundir ) ;
dot = 1 - dot ;
dot * = dot ;
dot = 1 - dot ;
VectorScale ( colour , dot , colour ) ;
if ( colour [ 0 ] > 0.001 | | colour [ 1 ] > 0.001 | | colour [ 2 ] > 0.001 )
{
//only do this if we can see some sky surfaces. pointless otherwise
batch_t * b ;
for ( b = cl . worldmodel - > batches [ SHADER_SORT_SKY ] ; b ; b = b - > next )
{
if ( b - > meshes )
break ;
}
if ( b )
{
VectorNormalize ( sundir ) ;
VectorMA ( r_origin , 1000 , sundir , sun . origin ) ;
Sh_DrawCrepuscularLight ( & sun , colour ) ;
}
}
}
# endif
BE_Scissor ( NULL ) ;
BE_SelectMode ( BEM_STANDARD ) ;
// if (developer.value)
// Con_Printf("%i lights drawn, %i frustum culled, %i pvs culled, %i scissor culled\n", bench.numlights, bench.numfrustumculled, bench.numpvsculled, bench.numscissorculled);
// memset(&bench, 0, sizeof(bench));
drawdlightnum = - 1 ;
}
# endif
//stencil shadows generally require that the farclip distance is really really far away
//so this little function is used to check if its needed or not.
qboolean Sh_StencilShadowsActive ( void )
{
# if defined(RTLIGHTS) && !defined(SERVERONLY)
//if shadowmapping is forced on all lights then we don't need special depth stuff
// if (r_shadow_shadowmapping.ival)
// return false;
if ( isDedicated )
return false ;
return ( r_shadow_realtime_dlight . ival & & r_shadow_realtime_dlight_shadows . ival ) | |
( r_shadow_realtime_world . ival & & r_shadow_realtime_world_shadows . ival ) ;
# else
return false ;
# endif
}
void Sh_RegisterCvars ( void )
{
# if defined(RTLIGHTS) && !defined(SERVERONLY)
# define REALTIMELIGHTING "Realtime Lighting"
Cvar_Register ( & r_shadow_scissor , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_world , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_world_shadows , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_dlight , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_dlight_ambient , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_dlight_diffuse , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_dlight_specular , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_dlight_shadows , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_realtime_world_lightmaps , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_playershadows , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_shadowmapping , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_shadowmapping_precision , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_shadowmapping_nearclip , REALTIMELIGHTING ) ;
Cvar_Register ( & r_shadow_shadowmapping_bias , REALTIMELIGHTING ) ;
Cvar_Register ( & r_sun_dir , REALTIMELIGHTING ) ;
Cvar_Register ( & r_sun_colour , REALTIMELIGHTING ) ;
# endif
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}