ioq3/code/renderergl2/tr_flares.c
Zack Middleton 39e2113c73 OpenGL2: Misc fixes and cleanup
Fix two constants in GLSL shaders. Remove f suffix from float and fix
int to float assignment. They were causing shader compile errors in
OpenGL ES 2 context.

Remove disabling clip plane. Clip plane is unused and never enabled in
the opengl2 renderer. Remove disabling it to avoid causing a GL error
when using OpenGL 3.2 core profile or OpenGL ES.

Make VAO cache vertex stride be size of srfVert_t since that is what
is uploaded to the GPU. No behavior change. There is a disabled debug
id in srfVert_t though which if enabled changes srfVert_t size.
2018-07-20 23:40:35 -05:00

553 lines
15 KiB
C

/*
===========================================================================
Copyright (C) 1999-2005 Id Software, Inc.
This file is part of Quake III Arena source code.
Quake III Arena source code is free software; you can redistribute it
and/or modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the License,
or (at your option) any later version.
Quake III Arena source code is distributed in the hope that it will be
useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Quake III Arena source code; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
===========================================================================
*/
// tr_flares.c
#include "tr_local.h"
/*
=============================================================================
LIGHT FLARES
A light flare is an effect that takes place inside the eye when bright light
sources are visible. The size of the flare reletive to the screen is nearly
constant, irrespective of distance, but the intensity should be proportional to the
projected area of the light source.
A surface that has been flagged as having a light flare will calculate the depth
buffer value that its midpoint should have when the surface is added.
After all opaque surfaces have been rendered, the depth buffer is read back for
each flare in view. If the point has not been obscured by a closer surface, the
flare should be drawn.
Surfaces that have a repeated texture should never be flagged as flaring, because
there will only be a single flare added at the midpoint of the polygon.
To prevent abrupt popping, the intensity of the flare is interpolated up and
down as it changes visibility. This involves scene to scene state, unlike almost
all other aspects of the renderer, and is complicated by the fact that a single
frame may have multiple scenes.
RB_RenderFlares() will be called once per view (twice in a mirrored scene, potentially
up to five or more times in a frame with 3D status bar icons).
=============================================================================
*/
// flare states maintain visibility over multiple frames for fading
// layers: view, mirror, menu
typedef struct flare_s {
struct flare_s *next; // for active chain
int addedFrame;
qboolean inPortal; // true if in a portal view of the scene
int frameSceneNum;
void *surface;
int fogNum;
int fadeTime;
qboolean visible; // state of last test
float drawIntensity; // may be non 0 even if !visible due to fading
int windowX, windowY;
float eyeZ;
vec3_t origin;
vec3_t color;
} flare_t;
#define MAX_FLARES 128
flare_t r_flareStructs[MAX_FLARES];
flare_t *r_activeFlares, *r_inactiveFlares;
int flareCoeff;
/*
==================
R_SetFlareCoeff
==================
*/
static void R_SetFlareCoeff( void ) {
if(r_flareCoeff->value == 0.0f)
flareCoeff = atof(FLARE_STDCOEFF);
else
flareCoeff = r_flareCoeff->value;
}
/*
==================
R_ClearFlares
==================
*/
void R_ClearFlares( void ) {
int i;
Com_Memset( r_flareStructs, 0, sizeof( r_flareStructs ) );
r_activeFlares = NULL;
r_inactiveFlares = NULL;
for ( i = 0 ; i < MAX_FLARES ; i++ ) {
r_flareStructs[i].next = r_inactiveFlares;
r_inactiveFlares = &r_flareStructs[i];
}
R_SetFlareCoeff();
}
/*
==================
RB_AddFlare
This is called at surface tesselation time
==================
*/
void RB_AddFlare( void *surface, int fogNum, vec3_t point, vec3_t color, vec3_t normal ) {
int i;
flare_t *f;
vec3_t local;
float d = 1;
vec4_t eye, clip, normalized, window;
backEnd.pc.c_flareAdds++;
if(normal && (normal[0] || normal[1] || normal[2]))
{
VectorSubtract( backEnd.viewParms.or.origin, point, local );
VectorNormalizeFast(local);
d = DotProduct(local, normal);
// If the viewer is behind the flare don't add it.
if(d < 0)
return;
}
// if the point is off the screen, don't bother adding it
// calculate screen coordinates and depth
R_TransformModelToClip( point, backEnd.or.modelMatrix,
backEnd.viewParms.projectionMatrix, eye, clip );
// check to see if the point is completely off screen
for ( i = 0 ; i < 3 ; i++ ) {
if ( clip[i] >= clip[3] || clip[i] <= -clip[3] ) {
return;
}
}
R_TransformClipToWindow( clip, &backEnd.viewParms, normalized, window );
if ( window[0] < 0 || window[0] >= backEnd.viewParms.viewportWidth
|| window[1] < 0 || window[1] >= backEnd.viewParms.viewportHeight ) {
return; // shouldn't happen, since we check the clip[] above, except for FP rounding
}
// see if a flare with a matching surface, scene, and view exists
for ( f = r_activeFlares ; f ; f = f->next ) {
if ( f->surface == surface && f->frameSceneNum == backEnd.viewParms.frameSceneNum
&& f->inPortal == backEnd.viewParms.isPortal ) {
break;
}
}
// allocate a new one
if (!f ) {
if ( !r_inactiveFlares ) {
// the list is completely full
return;
}
f = r_inactiveFlares;
r_inactiveFlares = r_inactiveFlares->next;
f->next = r_activeFlares;
r_activeFlares = f;
f->surface = surface;
f->frameSceneNum = backEnd.viewParms.frameSceneNum;
f->inPortal = backEnd.viewParms.isPortal;
f->addedFrame = -1;
}
if ( f->addedFrame != backEnd.viewParms.frameCount - 1 ) {
f->visible = qfalse;
f->fadeTime = backEnd.refdef.time - 2000;
}
f->addedFrame = backEnd.viewParms.frameCount;
f->fogNum = fogNum;
VectorCopy(point, f->origin);
VectorCopy( color, f->color );
// fade the intensity of the flare down as the
// light surface turns away from the viewer
VectorScale( f->color, d, f->color );
// save info needed to test
f->windowX = backEnd.viewParms.viewportX + window[0];
f->windowY = backEnd.viewParms.viewportY + window[1];
f->eyeZ = eye[2];
}
/*
==================
RB_AddDlightFlares
==================
*/
void RB_AddDlightFlares( void ) {
dlight_t *l;
int i, j, k;
fog_t *fog = NULL;
if ( !r_flares->integer ) {
return;
}
l = backEnd.refdef.dlights;
if(tr.world)
fog = tr.world->fogs;
for (i=0 ; i<backEnd.refdef.num_dlights ; i++, l++) {
if(fog)
{
// find which fog volume the light is in
for ( j = 1 ; j < tr.world->numfogs ; j++ ) {
fog = &tr.world->fogs[j];
for ( k = 0 ; k < 3 ; k++ ) {
if ( l->origin[k] < fog->bounds[0][k] || l->origin[k] > fog->bounds[1][k] ) {
break;
}
}
if ( k == 3 ) {
break;
}
}
if ( j == tr.world->numfogs ) {
j = 0;
}
}
else
j = 0;
RB_AddFlare( (void *)l, j, l->origin, l->color, NULL );
}
}
/*
===============================================================================
FLARE BACK END
===============================================================================
*/
/*
==================
RB_TestFlare
==================
*/
void RB_TestFlare( flare_t *f ) {
float depth;
qboolean visible;
float fade;
float screenZ;
FBO_t *oldFbo;
backEnd.pc.c_flareTests++;
// doing a readpixels is as good as doing a glFinish(), so
// don't bother with another sync
glState.finishCalled = qfalse;
// if we're doing multisample rendering, read from the correct FBO
oldFbo = glState.currentFBO;
if (tr.msaaResolveFbo)
{
FBO_Bind(tr.msaaResolveFbo);
}
// read back the z buffer contents
qglReadPixels( f->windowX, f->windowY, 1, 1, GL_DEPTH_COMPONENT, GL_FLOAT, &depth );
// if we're doing multisample rendering, switch to the old FBO
if (tr.msaaResolveFbo)
{
FBO_Bind(oldFbo);
}
screenZ = backEnd.viewParms.projectionMatrix[14] /
( ( 2*depth - 1 ) * backEnd.viewParms.projectionMatrix[11] - backEnd.viewParms.projectionMatrix[10] );
visible = ( -f->eyeZ - -screenZ ) < 24;
if ( visible ) {
if ( !f->visible ) {
f->visible = qtrue;
f->fadeTime = backEnd.refdef.time - 1;
}
fade = ( ( backEnd.refdef.time - f->fadeTime ) /1000.0f ) * r_flareFade->value;
} else {
if ( f->visible ) {
f->visible = qfalse;
f->fadeTime = backEnd.refdef.time - 1;
}
fade = 1.0f - ( ( backEnd.refdef.time - f->fadeTime ) / 1000.0f ) * r_flareFade->value;
}
if ( fade < 0 ) {
fade = 0;
}
if ( fade > 1 ) {
fade = 1;
}
f->drawIntensity = fade;
}
/*
==================
RB_RenderFlare
==================
*/
void RB_RenderFlare( flare_t *f ) {
float size;
vec3_t color;
int iColor[3];
float distance, intensity, factor;
byte fogFactors[3] = {255, 255, 255};
backEnd.pc.c_flareRenders++;
// We don't want too big values anyways when dividing by distance.
if(f->eyeZ > -1.0f)
distance = 1.0f;
else
distance = -f->eyeZ;
// calculate the flare size..
size = backEnd.viewParms.viewportWidth * ( r_flareSize->value/640.0f + 8 / distance );
/*
* This is an alternative to intensity scaling. It changes the size of the flare on screen instead
* with growing distance. See in the description at the top why this is not the way to go.
// size will change ~ 1/r.
size = backEnd.viewParms.viewportWidth * (r_flareSize->value / (distance * -2.0f));
*/
/*
* As flare sizes stay nearly constant with increasing distance we must decrease the intensity
* to achieve a reasonable visual result. The intensity is ~ (size^2 / distance^2) which can be
* got by considering the ratio of
* (flaresurface on screen) : (Surface of sphere defined by flare origin and distance from flare)
* An important requirement is:
* intensity <= 1 for all distances.
*
* The formula used here to compute the intensity is as follows:
* intensity = flareCoeff * size^2 / (distance + size*sqrt(flareCoeff))^2
* As you can see, the intensity will have a max. of 1 when the distance is 0.
* The coefficient flareCoeff will determine the falloff speed with increasing distance.
*/
factor = distance + size * sqrt(flareCoeff);
intensity = flareCoeff * size * size / (factor * factor);
VectorScale(f->color, f->drawIntensity * intensity, color);
// Calculations for fogging
if(tr.world && f->fogNum > 0 && f->fogNum < tr.world->numfogs)
{
tess.numVertexes = 1;
VectorCopy(f->origin, tess.xyz[0]);
tess.fogNum = f->fogNum;
RB_CalcModulateColorsByFog(fogFactors);
// We don't need to render the flare if colors are 0 anyways.
if(!(fogFactors[0] || fogFactors[1] || fogFactors[2]))
return;
}
iColor[0] = color[0] * fogFactors[0] * 257;
iColor[1] = color[1] * fogFactors[1] * 257;
iColor[2] = color[2] * fogFactors[2] * 257;
RB_BeginSurface( tr.flareShader, f->fogNum, 0 );
// FIXME: use quadstamp?
tess.xyz[tess.numVertexes][0] = f->windowX - size;
tess.xyz[tess.numVertexes][1] = f->windowY - size;
tess.texCoords[tess.numVertexes][0] = 0;
tess.texCoords[tess.numVertexes][1] = 0;
tess.color[tess.numVertexes][0] = iColor[0];
tess.color[tess.numVertexes][1] = iColor[1];
tess.color[tess.numVertexes][2] = iColor[2];
tess.color[tess.numVertexes][3] = 65535;
tess.numVertexes++;
tess.xyz[tess.numVertexes][0] = f->windowX - size;
tess.xyz[tess.numVertexes][1] = f->windowY + size;
tess.texCoords[tess.numVertexes][0] = 0;
tess.texCoords[tess.numVertexes][1] = 1;
tess.color[tess.numVertexes][0] = iColor[0];
tess.color[tess.numVertexes][1] = iColor[1];
tess.color[tess.numVertexes][2] = iColor[2];
tess.color[tess.numVertexes][3] = 65535;
tess.numVertexes++;
tess.xyz[tess.numVertexes][0] = f->windowX + size;
tess.xyz[tess.numVertexes][1] = f->windowY + size;
tess.texCoords[tess.numVertexes][0] = 1;
tess.texCoords[tess.numVertexes][1] = 1;
tess.color[tess.numVertexes][0] = iColor[0];
tess.color[tess.numVertexes][1] = iColor[1];
tess.color[tess.numVertexes][2] = iColor[2];
tess.color[tess.numVertexes][3] = 65535;
tess.numVertexes++;
tess.xyz[tess.numVertexes][0] = f->windowX + size;
tess.xyz[tess.numVertexes][1] = f->windowY - size;
tess.texCoords[tess.numVertexes][0] = 1;
tess.texCoords[tess.numVertexes][1] = 0;
tess.color[tess.numVertexes][0] = iColor[0];
tess.color[tess.numVertexes][1] = iColor[1];
tess.color[tess.numVertexes][2] = iColor[2];
tess.color[tess.numVertexes][3] = 65535;
tess.numVertexes++;
tess.indexes[tess.numIndexes++] = 0;
tess.indexes[tess.numIndexes++] = 1;
tess.indexes[tess.numIndexes++] = 2;
tess.indexes[tess.numIndexes++] = 0;
tess.indexes[tess.numIndexes++] = 2;
tess.indexes[tess.numIndexes++] = 3;
RB_EndSurface();
}
/*
==================
RB_RenderFlares
Because flares are simulating an occular effect, they should be drawn after
everything (all views) in the entire frame has been drawn.
Because of the way portals use the depth buffer to mark off areas, the
needed information would be lost after each view, so we are forced to draw
flares after each view.
The resulting artifact is that flares in mirrors or portals don't dim properly
when occluded by something in the main view, and portal flares that should
extend past the portal edge will be overwritten.
==================
*/
void RB_RenderFlares (void) {
flare_t *f;
flare_t **prev;
qboolean draw;
mat4_t oldmodelview, oldprojection, matrix;
if ( !r_flares->integer ) {
return;
}
if(r_flareCoeff->modified)
{
R_SetFlareCoeff();
r_flareCoeff->modified = qfalse;
}
// Reset currentEntity to world so that any previously referenced entities
// don't have influence on the rendering of these flares (i.e. RF_ renderer flags).
backEnd.currentEntity = &tr.worldEntity;
backEnd.or = backEnd.viewParms.world;
// RB_AddDlightFlares();
// perform z buffer readback on each flare in this view
draw = qfalse;
prev = &r_activeFlares;
while ( ( f = *prev ) != NULL ) {
// throw out any flares that weren't added last frame
if ( f->addedFrame < backEnd.viewParms.frameCount - 1 ) {
*prev = f->next;
f->next = r_inactiveFlares;
r_inactiveFlares = f;
continue;
}
// don't draw any here that aren't from this scene / portal
f->drawIntensity = 0;
if ( f->frameSceneNum == backEnd.viewParms.frameSceneNum
&& f->inPortal == backEnd.viewParms.isPortal ) {
RB_TestFlare( f );
if ( f->drawIntensity ) {
draw = qtrue;
} else {
// this flare has completely faded out, so remove it from the chain
*prev = f->next;
f->next = r_inactiveFlares;
r_inactiveFlares = f;
continue;
}
}
prev = &f->next;
}
if ( !draw ) {
return; // none visible
}
Mat4Copy(glState.projection, oldprojection);
Mat4Copy(glState.modelview, oldmodelview);
Mat4Identity(matrix);
GL_SetModelviewMatrix(matrix);
Mat4Ortho( backEnd.viewParms.viewportX, backEnd.viewParms.viewportX + backEnd.viewParms.viewportWidth,
backEnd.viewParms.viewportY, backEnd.viewParms.viewportY + backEnd.viewParms.viewportHeight,
-99999, 99999, matrix );
GL_SetProjectionMatrix(matrix);
for ( f = r_activeFlares ; f ; f = f->next ) {
if ( f->frameSceneNum == backEnd.viewParms.frameSceneNum
&& f->inPortal == backEnd.viewParms.isPortal
&& f->drawIntensity ) {
RB_RenderFlare( f );
}
}
GL_SetProjectionMatrix(oldprojection);
GL_SetModelviewMatrix(oldmodelview);
}