xash3d-fwgs/ref_vk/vk_sprite.c
Ivan Avdeev 973ef4c677 separate buffer space allocation from buffer uploading
Now each geometry is first allocated a slot with VK_RenderBufferAlloc,
and then VK_RenderBufferLock/Unlock are used to upload buffer contents.

This allow for two things:
1. Uploading buffer data to GPU memory on/after Unlock.
2. (Re)building BLAS for RTX on/after Unlock.

These buffers are now directly referenced by render_draw_t, which also
will be helpful in the future for both renderers.
2021-02-22 18:57:46 -08:00

997 lines
28 KiB
C

#include "vk_sprite.h"
#include "vk_textures.h"
#include "vk_global.h"
#include "vk_render.h"
#include "sprite.h"
#include "xash3d_mathlib.h"
#include "com_strings.h"
#include "pmtrace.h"
#include "pm_defs.h"
#include <memory.h>
// it's a Valve default value for LoadMapSprite (probably must be power of two)
#define MAPSPRITE_SIZE 128
#define GLARE_FALLOFF 19000.0f
static mspriteframe_t *R_GetSpriteFrame( const model_t *pModel, int frame, float yaw )
{
msprite_t *psprite;
mspritegroup_t *pspritegroup;
mspriteframe_t *pspriteframe = NULL;
float *pintervals, fullinterval;
int i, numframes;
float targettime;
ASSERT( pModel != NULL );
psprite = pModel->cache.data;
if( frame < 0 )
{
frame = 0;
}
else if( frame >= psprite->numframes )
{
if( frame > psprite->numframes )
gEngine.Con_Printf( S_WARN "R_GetSpriteFrame: no such frame %d (%s)\n", frame, pModel->name );
frame = psprite->numframes - 1;
}
if( psprite->frames[frame].type == SPR_SINGLE )
{
pspriteframe = psprite->frames[frame].frameptr;
}
else if( psprite->frames[frame].type == SPR_GROUP )
{
pspritegroup = (mspritegroup_t *)psprite->frames[frame].frameptr;
pintervals = pspritegroup->intervals;
numframes = pspritegroup->numframes;
fullinterval = pintervals[numframes-1];
// when loading in Mod_LoadSpriteGroup, we guaranteed all interval values
// are positive, so we don't have to worry about division by zero
targettime = gpGlobals->time - ((int)( gpGlobals->time / fullinterval )) * fullinterval;
for( i = 0; i < (numframes - 1); i++ )
{
if( pintervals[i] > targettime )
break;
}
pspriteframe = pspritegroup->frames[i];
}
else if( psprite->frames[frame].type == FRAME_ANGLED )
{
//int angleframe = (int)(Q_rint(( g_camera.viewangles[1] - yaw + 45.0f ) / 360 * 8) - 4) & 7;
const int angleframe = (int)(Q_rint(( 0 - yaw + 45.0f ) / 360 * 8) - 4) & 7;
gEngine.Con_Printf(S_WARN "VK FIXME: %s doesn't know about viewangles\n", __FUNCTION__);
// e.g. doom-style sprite monsters
pspritegroup = (mspritegroup_t *)psprite->frames[frame].frameptr;
pspriteframe = pspritegroup->frames[angleframe];
}
return pspriteframe;
}
void R_GetSpriteParms( int *frameWidth, int *frameHeight, int *numFrames, int currentFrame, const model_t *pSprite )
{
mspriteframe_t *pFrame;
if( !pSprite || pSprite->type != mod_sprite ) return; // bad model ?
pFrame = R_GetSpriteFrame( pSprite, currentFrame, 0.0f );
if( frameWidth ) *frameWidth = pFrame->width;
if( frameHeight ) *frameHeight = pFrame->height;
if( numFrames ) *numFrames = pSprite->numframes;
}
typedef struct {
char sprite_name[MAX_QPATH];
char group_suffix[8];
uint r_texFlags;
int sprite_version;
float sprite_radius;
} SpriteLoadContext;
static const dframetype_t *VK_SpriteLoadFrame( model_t *mod, const void *pin, mspriteframe_t **ppframe, int num, const SpriteLoadContext *ctx )
{
dspriteframe_t pinframe;
mspriteframe_t *pspriteframe;
int gl_texturenum = 0;
char texname[128];
int bytes = 1;
memcpy( &pinframe, pin, sizeof(dspriteframe_t));
if( ctx->sprite_version == SPRITE_VERSION_32 )
bytes = 4;
// build uinque frame name
if( FBitSet( mod->flags, MODEL_CLIENT )) // it's a HUD sprite
{
Q_snprintf( texname, sizeof( texname ), "#HUD/%s(%s:%i%i).spr", ctx->sprite_name, ctx->group_suffix, num / 10, num % 10 );
gl_texturenum = VK_LoadTexture( texname, pin, pinframe.width * pinframe.height * bytes, ctx->r_texFlags );
}
else
{
Q_snprintf( texname, sizeof( texname ), "#%s(%s:%i%i).spr", ctx->sprite_name, ctx->group_suffix, num / 10, num % 10 );
gl_texturenum = VK_LoadTexture( texname, pin, pinframe.width * pinframe.height * bytes, ctx->r_texFlags );
}
// setup frame description
pspriteframe = Mem_Malloc( mod->mempool, sizeof( mspriteframe_t ));
pspriteframe->width = pinframe.width;
pspriteframe->height = pinframe.height;
pspriteframe->up = pinframe.origin[1];
pspriteframe->left = pinframe.origin[0];
pspriteframe->down = pinframe.origin[1] - pinframe.height;
pspriteframe->right = pinframe.width + pinframe.origin[0];
pspriteframe->gl_texturenum = gl_texturenum;
*ppframe = pspriteframe;
return ( const dframetype_t* )(( const byte* )pin + sizeof( dspriteframe_t ) + pinframe.width * pinframe.height * bytes );
}
static const dframetype_t *VK_SpriteLoadGroup( model_t *mod, const void *pin, mspriteframe_t **ppframe, int framenum, const SpriteLoadContext *ctx )
{
const dspritegroup_t *pingroup;
mspritegroup_t *pspritegroup;
const dspriteinterval_t *pin_intervals;
float *poutintervals;
int i, groupsize, numframes;
const void *ptemp;
pingroup = (const dspritegroup_t *)pin;
numframes = pingroup->numframes;
groupsize = sizeof( mspritegroup_t ) + (numframes - 1) * sizeof( pspritegroup->frames[0] );
pspritegroup = Mem_Calloc( mod->mempool, groupsize );
pspritegroup->numframes = numframes;
*ppframe = (mspriteframe_t *)pspritegroup;
pin_intervals = (const dspriteinterval_t *)(pingroup + 1);
poutintervals = Mem_Calloc( mod->mempool, numframes * sizeof( float ));
pspritegroup->intervals = poutintervals;
for( i = 0; i < numframes; i++ )
{
*poutintervals = pin_intervals->interval;
if( *poutintervals <= 0.0f )
*poutintervals = 1.0f; // set error value
poutintervals++;
pin_intervals++;
}
ptemp = (const void *)pin_intervals;
for( i = 0; i < numframes; i++ )
{
ptemp = VK_SpriteLoadFrame( mod, ptemp, &pspritegroup->frames[i], framenum * 10 + i, ctx );
}
return (const dframetype_t *)ptemp;
}
void Mod_LoadSpriteModel( model_t *mod, const void *buffer, qboolean *loaded, uint texFlags )
{
const dsprite_t *pin;
const short *numi = NULL;
const dframetype_t *pframetype;
msprite_t *psprite;
int i;
SpriteLoadContext ctx = {0};
pin = buffer;
psprite = mod->cache.data;
if( pin->version == SPRITE_VERSION_Q1 || pin->version == SPRITE_VERSION_32 )
numi = NULL;
else if( pin->version == SPRITE_VERSION_HL )
numi = (const short *)(void *)((const byte*)buffer + sizeof( dsprite_hl_t ));
ctx.r_texFlags = texFlags;
ctx.sprite_version = pin->version;
Q_strncpy( ctx.sprite_name, mod->name, sizeof( ctx.sprite_name ));
COM_StripExtension( ctx.sprite_name );
if( numi == NULL )
{
rgbdata_t *pal;
pal = gEngine.FS_LoadImage( "#id.pal", (byte *)&i, 768 );
pframetype = (const dframetype_t *)(void *)((const byte*)buffer + sizeof( dsprite_q1_t )); // pinq1 + 1
gEngine.FS_FreeImage( pal ); // palette installed, no reason to keep this data
}
else if( *numi == 256 )
{
const byte *src = (const byte *)(numi+1);
rgbdata_t *pal;
// install palette
switch( psprite->texFormat )
{
case SPR_INDEXALPHA:
pal = gEngine.FS_LoadImage( "#gradient.pal", src, 768 );
break;
case SPR_ALPHTEST:
pal = gEngine.FS_LoadImage( "#masked.pal", src, 768 );
break;
default:
pal = gEngine.FS_LoadImage( "#normal.pal", src, 768 );
break;
}
pframetype = (const dframetype_t *)(void *)(src + 768);
gEngine.FS_FreeImage( pal ); // palette installed, no reason to keep this data
}
else
{
gEngine.Con_DPrintf( S_ERROR "%s has wrong number of palette colors %i (should be 256)\n", mod->name, *numi );
return;
}
if( mod->numframes < 1 )
return;
for( i = 0; i < mod->numframes; i++ )
{
frametype_t frametype = pframetype->type;
psprite->frames[i].type = (spriteframetype_t)frametype;
switch( frametype )
{
case FRAME_SINGLE:
Q_strncpy( ctx.group_suffix, "frame", sizeof( ctx.group_suffix ));
pframetype = VK_SpriteLoadFrame( mod, pframetype + 1, &psprite->frames[i].frameptr, i, &ctx );
break;
case FRAME_GROUP:
Q_strncpy( ctx.group_suffix, "group", sizeof( ctx.group_suffix ));
pframetype = VK_SpriteLoadGroup( mod, pframetype + 1, &psprite->frames[i].frameptr, i, &ctx );
break;
case FRAME_ANGLED:
Q_strncpy( ctx.group_suffix, "angle", sizeof( ctx.group_suffix ));
pframetype = VK_SpriteLoadGroup( mod, pframetype + 1, &psprite->frames[i].frameptr, i, &ctx );
break;
}
if( pframetype == NULL ) break; // technically an error
}
if( loaded ) *loaded = true; // done
}
int R_GetSpriteTexture( const model_t *m_pSpriteModel, int frame )
{
if( !m_pSpriteModel || m_pSpriteModel->type != mod_sprite || !m_pSpriteModel->cache.data )
return 0;
return R_GetSpriteFrame( m_pSpriteModel, frame, 0.0f )->gl_texturenum;
}
/*
====================
Mod_LoadMapSprite
Loading a bitmap image as sprite with multiple frames
as pieces of input image
====================
*/
void Mod_LoadMapSprite( model_t *mod, const void *buffer, size_t size, qboolean *loaded )
{
byte *src, *dst;
rgbdata_t *pix, temp;
char texname[128];
int i, j, x, y, w, h;
int xl, yl, xh, yh;
int linedelta, numframes;
mspriteframe_t *pspriteframe;
msprite_t *psprite;
SpriteLoadContext ctx = {0};
if( loaded ) *loaded = false;
Q_snprintf( texname, sizeof( texname ), "#%s", mod->name );
gEngine.Image_SetForceFlags( IL_OVERVIEW );
pix = gEngine.FS_LoadImage( texname, buffer, size );
gEngine.Image_ClearForceFlags();
if( !pix ) return; // bad image or something else
mod->type = mod_sprite;
ctx.r_texFlags = 0; // no custom flags for map sprites
if( pix->width % MAPSPRITE_SIZE )
w = pix->width - ( pix->width % MAPSPRITE_SIZE );
else w = pix->width;
if( pix->height % MAPSPRITE_SIZE )
h = pix->height - ( pix->height % MAPSPRITE_SIZE );
else h = pix->height;
if( w < MAPSPRITE_SIZE ) w = MAPSPRITE_SIZE;
if( h < MAPSPRITE_SIZE ) h = MAPSPRITE_SIZE;
// resample image if needed
gEngine.Image_Process( &pix, w, h, IMAGE_FORCE_RGBA|IMAGE_RESAMPLE, 0.0f );
w = h = MAPSPRITE_SIZE;
// check range
if( w > pix->width ) w = pix->width;
if( h > pix->height ) h = pix->height;
// determine how many frames we needs
numframes = (pix->width * pix->height) / (w * h);
mod->mempool = Mem_AllocPool( va( "^2%s^7", mod->name ));
psprite = Mem_Calloc( mod->mempool, sizeof( msprite_t ) + ( numframes - 1 ) * sizeof( psprite->frames ));
mod->cache.data = psprite; // make link to extradata
psprite->type = SPR_FWD_PARALLEL_ORIENTED;
psprite->texFormat = SPR_ALPHTEST;
psprite->numframes = mod->numframes = numframes;
psprite->radius = sqrt(((w >> 1) * (w >> 1)) + ((h >> 1) * (h >> 1)));
mod->mins[0] = mod->mins[1] = -w / 2;
mod->maxs[0] = mod->maxs[1] = w / 2;
mod->mins[2] = -h / 2;
mod->maxs[2] = h / 2;
// create a temporary pic
memset( &temp, 0, sizeof( temp ));
temp.width = w;
temp.height = h;
temp.type = pix->type;
temp.flags = pix->flags;
temp.size = w * h * gEngine.Image_GetPFDesc(temp.type)->bpp;
temp.buffer = Mem_Malloc( /* FIXME VK r_temppool*/ vk_core.pool, temp.size );
temp.palette = NULL;
// chop the image and upload into video memory
for( i = xl = yl = 0; i < numframes; i++ )
{
xh = xl + w;
yh = yl + h;
src = pix->buffer + ( yl * pix->width + xl ) * 4;
linedelta = ( pix->width - w ) * 4;
dst = temp.buffer;
// cut block from source
for( y = yl; y < yh; y++ )
{
for( x = xl; x < xh; x++ )
for( j = 0; j < 4; j++ )
*dst++ = *src++;
src += linedelta;
}
// build uinque frame name
Q_snprintf( texname, sizeof( texname ), "#MAP/%s_%i%i.spr", mod->name, i / 10, i % 10 );
psprite->frames[i].frameptr = Mem_Calloc( mod->mempool, sizeof( mspriteframe_t ));
pspriteframe = psprite->frames[i].frameptr;
pspriteframe->width = w;
pspriteframe->height = h;
pspriteframe->up = ( h >> 1 );
pspriteframe->left = -( w >> 1 );
pspriteframe->down = ( h >> 1 ) - h;
pspriteframe->right = w + -( w >> 1 );
pspriteframe->gl_texturenum = VK_LoadTextureInternal( texname, &temp, TF_IMAGE );
xl += w;
if( xl >= pix->width )
{
xl = 0;
yl += h;
}
}
gEngine.FS_FreeImage( pix );
Mem_Free( temp.buffer );
if( loaded ) *loaded = true;
}
/*
================
R_GetSpriteFrameInterpolant
NOTE: we using prevblending[0] and [1] for holds interval
between frames where are we lerping
================
*/
float R_GetSpriteFrameInterpolant( cl_entity_t *ent, mspriteframe_t **oldframe, mspriteframe_t **curframe )
{
msprite_t *psprite;
mspritegroup_t *pspritegroup;
int i, j, numframes, frame;
float lerpFrac, time, jtime, jinterval;
float *pintervals, fullinterval, targettime;
int m_fDoInterp;
psprite = ent->model->cache.data;
frame = (int)ent->curstate.frame;
lerpFrac = 1.0f;
// misc info
m_fDoInterp = (ent->curstate.effects & EF_NOINTERP) ? false : true;
if( frame < 0 )
{
frame = 0;
}
else if( frame >= psprite->numframes )
{
gEngine.Con_Reportf( S_WARN "R_GetSpriteFrameInterpolant: no such frame %d (%s)\n", frame, ent->model->name );
frame = psprite->numframes - 1;
}
if( psprite->frames[frame].type == FRAME_SINGLE )
{
if( m_fDoInterp )
{
if( ent->latched.prevblending[0] >= psprite->numframes || psprite->frames[ent->latched.prevblending[0]].type != FRAME_SINGLE )
{
// this can be happens when rendering switched between single and angled frames
// or change model on replace delta-entity
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 1.0f;
}
if( ent->latched.sequencetime < gpGlobals->time )
{
if( frame != ent->latched.prevblending[1] )
{
ent->latched.prevblending[0] = ent->latched.prevblending[1];
ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 0.0f;
}
else lerpFrac = (gpGlobals->time - ent->latched.sequencetime) * 11.0f;
}
else
{
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 0.0f;
}
}
else
{
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
lerpFrac = 1.0f;
}
if( ent->latched.prevblending[0] >= psprite->numframes )
{
// reset interpolation on change model
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 0.0f;
}
// get the interpolated frames
if( oldframe ) *oldframe = psprite->frames[ent->latched.prevblending[0]].frameptr;
if( curframe ) *curframe = psprite->frames[frame].frameptr;
}
else if( psprite->frames[frame].type == FRAME_GROUP )
{
pspritegroup = (mspritegroup_t *)psprite->frames[frame].frameptr;
pintervals = pspritegroup->intervals;
numframes = pspritegroup->numframes;
fullinterval = pintervals[numframes-1];
jinterval = pintervals[1] - pintervals[0];
time = gpGlobals->time;
jtime = 0.0f;
// when loading in Mod_LoadSpriteGroup, we guaranteed all interval values
// are positive, so we don't have to worry about division by zero
targettime = time - ((int)(time / fullinterval)) * fullinterval;
// LordHavoc: since I can't measure the time properly when it loops from numframes - 1 to 0,
// i instead measure the time of the first frame, hoping it is consistent
for( i = 0, j = numframes - 1; i < (numframes - 1); i++ )
{
if( pintervals[i] > targettime )
break;
j = i;
jinterval = pintervals[i] - jtime;
jtime = pintervals[i];
}
if( m_fDoInterp )
lerpFrac = (targettime - jtime) / jinterval;
else j = i; // no lerping
// get the interpolated frames
if( oldframe ) *oldframe = pspritegroup->frames[j];
if( curframe ) *curframe = pspritegroup->frames[i];
}
else if( psprite->frames[frame].type == FRAME_ANGLED )
{
// e.g. doom-style sprite monsters
float yaw = ent->angles[YAW];
int angleframe = (int)(Q_rint(( g_camera.viewangles[1] - yaw + 45.0f ) / 360 * 8) - 4) & 7;
if( m_fDoInterp )
{
if( ent->latched.prevblending[0] >= psprite->numframes || psprite->frames[ent->latched.prevblending[0]].type != FRAME_ANGLED )
{
// this can be happens when rendering switched between single and angled frames
// or change model on replace delta-entity
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 1.0f;
}
if( ent->latched.sequencetime < gpGlobals->time )
{
if( frame != ent->latched.prevblending[1] )
{
ent->latched.prevblending[0] = ent->latched.prevblending[1];
ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 0.0f;
}
else lerpFrac = (gpGlobals->time - ent->latched.sequencetime) * ent->curstate.framerate;
}
else
{
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
ent->latched.sequencetime = gpGlobals->time;
lerpFrac = 0.0f;
}
}
else
{
ent->latched.prevblending[0] = ent->latched.prevblending[1] = frame;
lerpFrac = 1.0f;
}
pspritegroup = (mspritegroup_t *)psprite->frames[ent->latched.prevblending[0]].frameptr;
if( oldframe ) *oldframe = pspritegroup->frames[angleframe];
pspritegroup = (mspritegroup_t *)psprite->frames[frame].frameptr;
if( curframe ) *curframe = pspritegroup->frames[angleframe];
}
return lerpFrac;
}
/* FIXME VK
// Cull sprite model by bbox
qboolean R_CullSpriteModel( cl_entity_t *e, vec3_t origin )
{
vec3_t sprite_mins, sprite_maxs;
float scale = 1.0f;
if( !e->model->cache.data )
return true;
if( e->curstate.scale > 0.0f )
scale = e->curstate.scale;
// scale original bbox (no rotation for sprites)
VectorScale( e->model->mins, scale, sprite_mins );
VectorScale( e->model->maxs, scale, sprite_maxs );
sprite_radius = RadiusFromBounds( sprite_mins, sprite_maxs );
VectorAdd( sprite_mins, origin, sprite_mins );
VectorAdd( sprite_maxs, origin, sprite_maxs );
return R_CullModel( e, sprite_mins, sprite_maxs );
}
*/
// Set sprite brightness factor
static float R_SpriteGlowBlend( vec3_t origin, int rendermode, int renderfx, float *pscale )
{
float dist, brightness;
vec3_t glowDist;
pmtrace_t *tr;
VectorSubtract( origin, g_camera.vieworg, glowDist );
dist = VectorLength( glowDist );
// FIXME VK if( RP_NORMALPASS( ))
{
tr = gEngine.EV_VisTraceLine( g_camera.vieworg, origin,
// FIXME VK r_traceglow->value ? PM_GLASS_IGNORE :
(PM_GLASS_IGNORE|PM_STUDIO_IGNORE));
if(( 1.0f - tr->fraction ) * dist > 8.0f )
return 0.0f;
}
if( renderfx == kRenderFxNoDissipation )
return 1.0f;
brightness = GLARE_FALLOFF / ( dist * dist );
brightness = bound( 0.05f, brightness, 1.0f );
*pscale *= dist * ( 1.0f / 200.0f );
return brightness;
}
// FIXME
int TriWorldToScreen( const float *world, float *screen );
// Do occlusion test for glow-sprites
qboolean R_SpriteOccluded( cl_entity_t *e, vec3_t origin, float *pscale )
{
if( e->curstate.rendermode == kRenderGlow )
{
float blend;
vec3_t v;
TriWorldToScreen( origin, v );
if( v[0] < g_camera.viewport[0] || v[0] > g_camera.viewport[0] + g_camera.viewport[2] )
return true; // do scissor
if( v[1] < g_camera.viewport[1] || v[1] > g_camera.viewport[1] + g_camera.viewport[3] )
return true; // do scissor
blend = R_SpriteGlowBlend( origin, e->curstate.rendermode, e->curstate.renderfx, pscale );
// FIXME VK tr.blend *= blend;
if( blend <= 0.01f )
return true; // faded
}
else
{
// FIXME VK if( R_CullSpriteModel( e, origin )) return true;
return false;
}
return false;
}
static void R_DrawSpriteQuad( mspriteframe_t *frame, vec3_t org, vec3_t v_right, vec3_t v_up, float scale, int texture, int render_mode )
{
vec3_t point;
vk_buffer_handle_t vertex_buffer, index_buffer;
vk_buffer_lock_t vertex_lock, index_lock;
vk_vertex_t *dst_vtx;
uint16_t *dst_idx;
// Get buffer region for vertices and indices
vertex_buffer = VK_RenderBufferAlloc( sizeof(vk_vertex_t), 4, LifetimeSingleFrame );
index_buffer = VK_RenderBufferAlloc( sizeof(uint16_t), 6, LifetimeSingleFrame );
if (vertex_buffer == InvalidHandle || index_buffer == InvalidHandle)
{
// TODO should we free one of the above if it still succeeded?
gEngine.Con_Printf(S_ERROR "Ran out of buffer space\n");
return;
}
vertex_lock = VK_RenderBufferLock( vertex_buffer );
index_lock = VK_RenderBufferLock( index_buffer );
dst_vtx = vertex_lock.ptr;
dst_idx = index_lock.ptr;
// FIXME VK r_stats.c_sprite_polys++;
VectorMA( org, frame->down * scale, v_up, point );
VectorMA( point, frame->left * scale, v_right, dst_vtx[0].pos );
dst_vtx[0].gl_tc[0] = 0.f;
dst_vtx[0].gl_tc[1] = 1.f;
dst_vtx[0].lm_tc[0] = dst_vtx[0].lm_tc[1] = 0.f;
VectorMA( org, frame->up * scale, v_up, point );
VectorMA( point, frame->left * scale, v_right, dst_vtx[1].pos );
dst_vtx[1].gl_tc[0] = 0.f;
dst_vtx[1].gl_tc[1] = 0.f;
dst_vtx[1].lm_tc[0] = dst_vtx[1].lm_tc[1] = 0.f;
VectorMA( org, frame->up * scale, v_up, point );
VectorMA( point, frame->right * scale, v_right, dst_vtx[2].pos );
dst_vtx[2].gl_tc[0] = 1.f;
dst_vtx[2].gl_tc[1] = 0.f;
dst_vtx[2].lm_tc[0] = dst_vtx[2].lm_tc[1] = 0.f;
VectorMA( org, frame->down * scale, v_up, point );
VectorMA( point, frame->right * scale, v_right, dst_vtx[3].pos );
dst_vtx[3].gl_tc[0] = 1.f;
dst_vtx[3].gl_tc[1] = 1.f;
dst_vtx[3].lm_tc[0] = dst_vtx[3].lm_tc[1] = 0.f;
dst_idx[0] = 0;
dst_idx[1] = 1;
dst_idx[2] = 2;
dst_idx[3] = 0;
dst_idx[4] = 2;
dst_idx[5] = 3;
VK_RenderBufferUnlock( index_buffer );
VK_RenderBufferUnlock( vertex_buffer );
{
const render_draw_t draw = {
.lightmap = tglob.whiteTexture,
.texture = texture,
.render_mode = render_mode,
.element_count = 6,
.vertex_offset = 0,
.index_offset = 0,
.vertex_buffer = vertex_buffer,
.index_buffer = index_buffer,
};
VK_RenderScheduleDraw( &draw );
}
}
static qboolean R_SpriteHasLightmap( cl_entity_t *e, int texFormat )
{
/* FIXME VK
if( !r_sprite_lighting->value )
return false;
*/
if( texFormat != SPR_ALPHTEST )
return false;
if( e->curstate.effects & EF_FULLBRIGHT )
return false;
if( e->curstate.renderamt <= 127 )
return false;
switch( e->curstate.rendermode )
{
case kRenderNormal:
case kRenderTransAlpha:
case kRenderTransTexture:
break;
default:
return false;
}
return true;
}
static qboolean R_SpriteAllowLerping( cl_entity_t *e, msprite_t *psprite )
{
/* FIXME VK
if( !r_sprite_lerping->value )
return false;
*/
if( psprite->numframes <= 1 )
return false;
if( psprite->texFormat != SPR_ADDITIVE )
return false;
if( e->curstate.rendermode == kRenderNormal || e->curstate.rendermode == kRenderTransAlpha )
return false;
return true;
}
void VK_SpriteDrawModel( cl_entity_t *e )
{
mspriteframe_t *frame, *oldframe;
msprite_t *psprite;
model_t *model;
int i, type;
float angle, dot, sr, cr;
float lerp = 1.0f, ilerp, scale;
vec3_t v_forward, v_right, v_up;
vec3_t origin, color, color2 = { 0.0f };
/* FIXME VK
if( RI.params & RP_ENVVIEW )
return;
*/
model = e->model;
psprite = (msprite_t * )model->cache.data;
VectorCopy( e->origin, origin ); // set render origin
// do movewith
if( e->curstate.aiment > 0 && e->curstate.movetype == MOVETYPE_FOLLOW )
{
cl_entity_t *parent;
parent = gEngine.GetEntityByIndex( e->curstate.aiment );
if( parent && parent->model )
{
if( parent->model->type == mod_studio && e->curstate.body > 0 )
{
int num = bound( 1, e->curstate.body, MAXSTUDIOATTACHMENTS );
VectorCopy( parent->attachment[num-1], origin );
}
else VectorCopy( parent->origin, origin );
}
}
scale = e->curstate.scale;
if( !scale ) scale = 1.0f;
if( R_SpriteOccluded( e, origin, &scale ))
return; // sprite culled
/* FIXME VK
r_stats.c_sprite_models_drawn++;
if( e->curstate.rendermode == kRenderGlow || e->curstate.rendermode == kRenderTransAdd )
R_AllowFog( false );
*/
/* FIXME VK compare with pipeline state
// select properly rendermode
switch( e->curstate.rendermode )
{
case kRenderTransAlpha:
pglDepthMask( GL_FALSE );
// fallthrough
case kRenderTransColor:
case kRenderTransTexture:
pglEnable( GL_BLEND );
pglBlendFunc( GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA );
break;
case kRenderGlow:
pglDisable( GL_DEPTH_TEST );
// fallthrough
case kRenderTransAdd:
pglEnable( GL_BLEND );
pglBlendFunc( GL_SRC_ALPHA, GL_ONE );
pglDepthMask( GL_FALSE );
break;
case kRenderNormal:
default:
pglDisable( GL_BLEND );
break;
}
// all sprites can have color
pglTexEnvi( GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE );
pglEnable( GL_ALPHA_TEST );
*/
// NOTE: never pass sprites with rendercolor '0 0 0' it's a stupid Valve Hammer Editor bug
if( e->curstate.rendercolor.r || e->curstate.rendercolor.g || e->curstate.rendercolor.b )
{
color[0] = (float)e->curstate.rendercolor.r * ( 1.0f / 255.0f );
color[1] = (float)e->curstate.rendercolor.g * ( 1.0f / 255.0f );
color[2] = (float)e->curstate.rendercolor.b * ( 1.0f / 255.0f );
}
else
{
color[0] = 1.0f;
color[1] = 1.0f;
color[2] = 1.0f;
}
/* FIXME VK
if( R_SpriteHasLightmap( e, psprite->texFormat ))
{
colorVec lightColor = R_LightPoint( origin );
// FIXME: collect light from dlights?
color2[0] = (float)lightColor.r * ( 1.0f / 255.0f );
color2[1] = (float)lightColor.g * ( 1.0f / 255.0f );
color2[2] = (float)lightColor.b * ( 1.0f / 255.0f );
// NOTE: sprites with 'lightmap' looks ugly when alpha func is GL_GREATER 0.0
pglAlphaFunc( GL_GREATER, 0.5f );
}
*/
if( R_SpriteAllowLerping( e, psprite ))
lerp = R_GetSpriteFrameInterpolant( e, &oldframe, &frame );
else frame = oldframe = R_GetSpriteFrame( model, e->curstate.frame, e->angles[YAW] );
type = psprite->type;
// automatically roll parallel sprites if requested
if( e->angles[ROLL] != 0.0f && type == SPR_FWD_PARALLEL )
type = SPR_FWD_PARALLEL_ORIENTED;
switch( type )
{
case SPR_ORIENTED:
AngleVectors( e->angles, v_forward, v_right, v_up );
VectorScale( v_forward, 0.01f, v_forward ); // to avoid z-fighting
VectorSubtract( origin, v_forward, origin );
break;
case SPR_FACING_UPRIGHT:
VectorSet( v_right, origin[1] - g_camera.vieworg[1], -(origin[0] - g_camera.vieworg[0]), 0.0f );
VectorSet( v_up, 0.0f, 0.0f, 1.0f );
VectorNormalize( v_right );
break;
case SPR_FWD_PARALLEL_UPRIGHT:
dot = g_camera.vforward[2];
if(( dot > 0.999848f ) || ( dot < -0.999848f )) // cos(1 degree) = 0.999848
return; // invisible
VectorSet( v_up, 0.0f, 0.0f, 1.0f );
VectorSet( v_right, g_camera.vforward[1], -g_camera.vforward[0], 0.0f );
VectorNormalize( v_right );
break;
case SPR_FWD_PARALLEL_ORIENTED:
angle = e->angles[ROLL] * (M_PI2 / 360.0f);
SinCos( angle, &sr, &cr );
for( i = 0; i < 3; i++ )
{
v_right[i] = (g_camera.vright[i] * cr + g_camera.vup[i] * sr);
v_up[i] = g_camera.vright[i] * -sr + g_camera.vup[i] * cr;
}
break;
case SPR_FWD_PARALLEL: // normal sprite
default:
VectorCopy( g_camera.vright, v_right );
VectorCopy( g_camera.vup, v_up );
break;
}
/* FIXME VK
if( psprite->facecull == SPR_CULL_NONE )
GL_Cull( GL_NONE );
*/
if (vk_core.debug) {
VkDebugUtilsLabelEXT label = {
.sType = VK_STRUCTURE_TYPE_DEBUG_UTILS_LABEL_EXT,
.pLabelName = model->name,
};
vkCmdBeginDebugUtilsLabelEXT(vk_core.cb, &label);
}
if( oldframe == frame )
{
// draw the single non-lerped frame
/* FIXME VK make sure we end up with the same values
ubo->color[0] = color[0];
ubo->color[1] = color[1];
ubo->color[2] = color[2];
ubo->color[3] = tr.blend;
*/
VK_RenderStateSetColor( color[0], color[1], color[2], .5f ); // FIXME VK: tr.blend
R_DrawSpriteQuad( frame, origin, v_right, v_up, scale, frame->gl_texturenum, e->curstate.rendermode );
}
else
{
// draw two combined lerped frames
lerp = bound( 0.0f, lerp, 1.0f );
ilerp = 1.0f - lerp;
if( ilerp != 0.0f )
{
// FIXME VK make sure we end up with the same values as gl
VK_RenderStateSetColor( color[0], color[1], color[2], 1.f * ilerp );
R_DrawSpriteQuad( oldframe, origin, v_right, v_up, scale, oldframe->gl_texturenum, e->curstate.rendermode );
}
if( lerp != 0.0f )
{
// FIXME VK make sure we end up with the same values as gl
VK_RenderStateSetColor( color[0], color[1], color[2], 1.f * lerp );
R_DrawSpriteQuad( frame, origin, v_right, v_up, scale, frame->gl_texturenum, e->curstate.rendermode );
}
}
/* FIXME VK
// draw the sprite 'lightmap' :-)
if( R_SpriteHasLightmap( e, psprite->texFormat ))
{
if( !r_lightmap->value )
pglEnable( GL_BLEND );
else pglDisable( GL_BLEND );
pglDepthFunc( GL_EQUAL );
pglDisable( GL_ALPHA_TEST );
pglBlendFunc( GL_ZERO, GL_SRC_COLOR );
pglTexEnvi( GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE );
pglColor4f( color2[0], color2[1], color2[2], tr.blend );
GL_Bind( XASH_TEXTURE0, tr.whiteTexture );
R_DrawSpriteQuad( frame, origin, v_right, v_up, scale, ubo_index, frame->gl_texturenum, e->curstate.rendermode );
pglAlphaFunc( GL_GREATER, DEFAULT_ALPHATEST );
pglDepthFunc( GL_LEQUAL );
}
*/
if (vk_core.debug)
vkCmdEndDebugUtilsLabelEXT(vk_core.cb);
}