raze/source/core/rendering/scene/hw_walls.cpp
Christoph Oelckers 264d42179e - optimized the wall drawer a bit to avoid repeated calls to the render API's deoth bias function.
The setters in FRenderState should check if the value actually changes and the wall drawer should only call it for non-translucent wall sprites.
2021-05-21 19:07:22 +02:00

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//
//---------------------------------------------------------------------------
//
// Copyright(C) 2000-2016 Christoph Oelckers
// All rights reserved.
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 2 of the License, or
// (at your option) any later version.
//
// This program 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 Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with this program. If not, see http://www.gnu.org/licenses/
//
//--------------------------------------------------------------------------
//
#include "texturemanager.h"
#include "hw_dynlightdata.h"
#include "hw_material.h"
#include "hw_cvars.h"
#include "hw_clock.h"
//#include "hw_lighting.h"
#include "hw_drawinfo.h"
#include "hw_portal.h"
#include "hw_lightbuffer.h"
#include "hw_renderstate.h"
#include "hw_skydome.h"
#include "hw_drawstructs.h"
#include "gamefuncs.h"
#include "cmdlib.h"
#include "v_video.h"
#include "flatvertices.h"
#include "glbackend/glbackend.h"
//==========================================================================
//
//
//
//==========================================================================
static int GetClosestPointOnWall(spritetype* spr, walltype* wal, vec2_t* const n)
{
auto w = wal->pos;
auto d = wall[wal->point2].pos - w;
auto pos = spr->pos;
// avoid the math below for orthogonal walls. Here we allow only sprites that exactly match the line's coordinate and orientation
if (d.x == 0 && d.y == 0)
{
// line has no length.
// In Blood's E1M1 this gets triggered for wall 522.
return 1;
}
else if (d.x == 0)
{
// line is vertical.
if (pos.x == w.x && (spr->ang & 0x3ff) == 0)
{
*n = pos.vec2;
return 0;
}
return 1;
}
else if (d.y == 0)
{
// line is horizontal.
if (pos.y == w.y && (spr->ang & 0x3ff) == 0x200)
{
*n = pos.vec2;
return 0;
}
return 1;
}
int64_t i = d.x * ((int64_t)pos.x - w.x) + d.y * ((int64_t)pos.y - w.y);
if (i < 0)
return 1;
int64_t j = (int64_t)d.x * d.x + (int64_t)d.y * d.y;
if (i > j)
return 1;
i = ((i << 15) / j) << 15;
n->x = w.x + ((d.x * i) >> 30);
n->y = w.y + ((d.y * i) >> 30);
return 0;
}
//==========================================================================
//
//
//
//==========================================================================
static int IsOnWall(spritetype* tspr, int height)
{
int dist = 3, closest = -1;
auto sect = &sector[tspr->sectnum];
vec2_t n;
int topz = (tspr->z - ((height * tspr->yrepeat) << 2));
for (int i = sect->wallptr; i < sect->wallptr + sect->wallnum; i++)
{
auto wal = &wall[i];
if ((wal->nextsector == -1 || ((sector[wal->nextsector].ceilingz > topz) ||
sector[wal->nextsector].floorz < tspr->z)) && !GetClosestPointOnWall(tspr, wal, &n))
{
int const dst = abs(tspr->x - n.x) + abs(tspr->y - n.y);
if (dst <= dist)
{
dist = dst;
closest = i;
}
}
}
return closest == -1? -1 : dist;
}
//==========================================================================
//
// Create vertices for one wall
//
//==========================================================================
int HWWall::CreateVertices(FFlatVertex*& ptr, bool split)
{
auto oo = ptr;
ptr->Set(glseg.x1, zbottom[0], glseg.y1, tcs[LOLFT].u, tcs[LOLFT].v);
ptr++;
ptr->Set(glseg.x1, ztop[0], glseg.y1, tcs[UPLFT].u, tcs[UPLFT].v);
ptr++;
ptr->Set(glseg.x2, ztop[1], glseg.y2, tcs[UPRGT].u, tcs[UPRGT].v);
ptr++;
ptr->Set(glseg.x2, zbottom[1], glseg.y2, tcs[LORGT].u, tcs[LORGT].v);
ptr++;
return int(ptr - oo);
}
//==========================================================================
//
// build the vertices for this wall
//
//==========================================================================
void HWWall::MakeVertices(HWDrawInfo* di, bool nosplit)
{
if (vertcount == 0)
{
auto ret = screen->mVertexData->AllocVertices(4);
vertindex = ret.second;
vertcount = CreateVertices(ret.first, false);
}
}
//==========================================================================
//
// General purpose wall rendering function
// everything goes through here
//
//==========================================================================
void HWWall::RenderWall(HWDrawInfo *di, FRenderState &state, int textured)
{
assert(vertcount > 0);
state.SetLightIndex(dynlightindex);
state.Draw(DT_TriangleFan, vertindex, vertcount);
vertexcount += vertcount;
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::RenderFogBoundary(HWDrawInfo *di, FRenderState &state)
{
if (gl_fogmode)// && !di->isFullbrightScene())
{
state.EnableDrawBufferAttachments(false);
SetLightAndFog(state, fade, palette, shade, visibility, alpha);
state.SetEffect(EFF_FOGBOUNDARY);
state.AlphaFunc(Alpha_GEqual, 0.f);
state.SetDepthBias(-1, -128);
RenderWall(di, state, HWWall::RWF_BLANK);
state.ClearDepthBias();
state.SetEffect(EFF_NONE);
state.EnableDrawBufferAttachments(true);
}
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::RenderMirrorSurface(HWDrawInfo *di, FRenderState &state)
{
if (!TexMan.mirrorTexture.isValid()) return;
state.SetDepthFunc(DF_LEqual);
// we use texture coordinates and texture matrix to pass the normal stuff to the shader so that the default vertex buffer format can be used as is.
state.EnableTextureMatrix(true);
// Use sphere mapping for this
state.SetEffect(EFF_SPHEREMAP);
SetLightAndFog(state, fade, palette, min<int>(shade, numshades), visibility, alpha);
state.SetColor(PalEntry(25, globalr >> 1, globalg >> 1, globalb >> 1));
state.SetRenderStyle(STYLE_Add);
state.AlphaFunc(Alpha_Greater, 0);
auto tex = TexMan.GetGameTexture(TexMan.mirrorTexture, false);
state.SetMaterial(tex, UF_None, 0, CLAMP_NONE, 0, -1); // do not upscale the mirror texture.
RenderWall(di, state, HWWall::RWF_BLANK);
state.EnableTextureMatrix(false);
state.SetEffect(EFF_NONE);
state.AlphaFunc(Alpha_GEqual, 0.5f);
state.SetDepthFunc(DF_Less);
state.SetRenderStyle(STYLE_Translucent);
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::RenderTexturedWall(HWDrawInfo *di, FRenderState &state, int rflags)
{
SetLightAndFog(state, fade, palette, shade, visibility, alpha);
state.SetMaterial(texture, UF_Texture, 0, (flags & (HWF_CLAMPX | HWF_CLAMPY)), TRANSLATION(Translation_Remap + curbasepal, palette), -1);
if (Sprite == nullptr)
{
int h = (int)texture->GetDisplayHeight();
int h2 = 1 << sizeToBits(h);
if (h2 < h) h2 *= 2;
if (h != h2)
{
float xOffset = 1.f / texture->GetDisplayWidth();
state.SetNpotEmulation(float(h2) / h, xOffset);
}
RenderWall(di, state, rflags);
}
else if (!(rflags & RWF_TRANS))
{
auto oldbias = state.GetDepthBias();
if (walldist >= 0) state.SetDepthBias(-1, glseg.x1 == glseg.x2 || glseg.y1 == glseg.y2? -128 : -192);
else state.ClearDepthBias();
RenderWall(di, state, rflags);
state.SetDepthBias(oldbias);
}
else
RenderWall(di, state, rflags);
state.SetNpotEmulation(0.f, 0.f);
state.SetObjectColor(0xffffffff);
/* none of these functions is in use.
state.SetObjectColor2(0);
state.SetAddColor(0);
state.SetTextureMode(tmode);
state.EnableGlow(false);
state.EnableGradient(false);
state.ApplyTextureManipulation(nullptr);
*/
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::RenderTranslucentWall(HWDrawInfo *di, FRenderState &state)
{
if (RenderStyle.BlendOp != STYLEOP_Add)
{
state.EnableBrightmap(false);
}
state.SetRenderStyle(RenderStyle);
state.SetTextureMode(RenderStyle);
if (texture && !checkTranslucentReplacement(texture->GetID(), palette)) state.AlphaFunc(Alpha_GEqual, texture->alphaThreshold);
else state.AlphaFunc(Alpha_GEqual, 0.f);
RenderTexturedWall(di, state, HWWall::RWF_TEXTURED);
state.SetRenderStyle(STYLE_Translucent);
state.EnableBrightmap(true);
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::DrawWall(HWDrawInfo *di, FRenderState &state, bool translucent)
{
if (screen->BuffersArePersistent())
{
/*
if (di->Level->HasDynamicLights && !di->isFullbrightScene() && texture != nullptr)
{
SetupLights(di, lightdata);
}
*/
MakeVertices(di, !!(flags & HWWall::HWF_TRANSLUCENT));
}
state.SetNormal(glseg.Normal());
if (!translucent)
{
RenderTexturedWall(di, state, HWWall::RWF_TEXTURED);
}
else
{
switch (type)
{
case RENDERWALL_MIRRORSURFACE:
RenderMirrorSurface(di, state);
break;
case RENDERWALL_FOGBOUNDARY:
RenderFogBoundary(di, state);
break;
default:
RenderTranslucentWall(di, state);
break;
}
}
}
//==========================================================================
//
// Collect lights for shader
//
//==========================================================================
#if 0
void HWWall::SetupLights(HWDrawInfo *di, FDynLightData &lightdata)
{
lightdata.Clear();
if (RenderStyle == STYLE_Add && !di->Level->lightadditivesurfaces) return; // no lights on additively blended surfaces.
// check for wall types which cannot have dynamic lights on them (portal types never get here so they don't need to be checked.)
switch (type)
{
case RENDERWALL_FOGBOUNDARY:
case RENDERWALL_MIRRORSURFACE:
case RENDERWALL_COLOR:
return;
}
float vtx[]={glseg.x1,zbottom[0],glseg.y1, glseg.x1,ztop[0],glseg.y1, glseg.x2,ztop[1],glseg.y2, glseg.x2,zbottom[1],glseg.y2};
Plane p;
auto normal = glseg.Normal();
p.Set(normal, -normal.X * glseg.x1 - normal.Z * glseg.y1);
FLightNode *node;
if (seg->sidedef == NULL)
{
node = NULL;
}
else if (!(seg->sidedef->Flags & WALLF_POLYOBJ))
{
node = seg->sidedef->lighthead;
}
else if (sub)
{
// Polobject segs cannot be checked per sidedef so use the subsector instead.
node = sub->section->lighthead;
}
else node = NULL;
// Iterate through all dynamic lights which touch this wall and render them
while (node)
{
if (node->lightsource->IsActive())
{
iter_dlight++;
DVector3 posrel = node->lightsource->PosRelative(seg->frontsector->PortalGroup);
float x = posrel.X;
float y = posrel.Y;
float z = posrel.Z;
float dist = fabsf(p.DistToPoint(x, z, y));
float radius = node->lightsource->GetRadius();
float scale = 1.0f / ((2.f * radius) - dist);
FVector3 fn, pos;
if (radius > 0.f && dist < radius)
{
FVector3 nearPt, up, right;
pos = { x, z, y };
fn = p.Normal();
fn.GetRightUp(right, up);
FVector3 tmpVec = fn * dist;
nearPt = pos + tmpVec;
FVector3 t1;
int outcnt[4]={0,0,0,0};
texcoord tcs[4];
// do a quick check whether the light touches this polygon
for(int i=0;i<4;i++)
{
t1 = FVector3(&vtx[i*3]);
FVector3 nearToVert = t1 - nearPt;
tcs[i].u = ((nearToVert | right) * scale) + 0.5f;
tcs[i].v = ((nearToVert | up) * scale) + 0.5f;
if (tcs[i].u<0) outcnt[0]++;
if (tcs[i].u>1) outcnt[1]++;
if (tcs[i].v<0) outcnt[2]++;
if (tcs[i].v>1) outcnt[3]++;
}
if (outcnt[0]!=4 && outcnt[1]!=4 && outcnt[2]!=4 && outcnt[3]!=4)
{
draw_dlight += GetLight(lightdata, seg->frontsector->PortalGroup, p, node->lightsource, true);
}
}
}
node = node->nextLight;
}
dynlightindex = screen->mLights->UploadLights(lightdata);
}
#endif
//==========================================================================
//
//
//
//==========================================================================
void HWWall::PutWall(HWDrawInfo *di, bool translucent)
{
if (translucent || (texture && texture->GetTranslucency() && type == RENDERWALL_M2S))
{
flags |= HWF_TRANSLUCENT;
ViewDistance = (di->Viewpoint.Pos.XY() - DVector2((glseg.x1 + glseg.x2) * 0.5f, (glseg.y1 + glseg.y2) * 0.5f)).LengthSquared();
}
if (texture->isHardwareCanvas())
{
tcs[UPLFT].v = 1.f - tcs[UPLFT].v;
tcs[LOLFT].v = 1.f - tcs[LOLFT].v;
tcs[UPRGT].v = 1.f - tcs[UPRGT].v;
tcs[LORGT].v = 1.f - tcs[LORGT].v;
}
if (!screen->BuffersArePersistent())
{
/*
if (di->Level->HasDynamicLights && !di->isFullbrightScene() && texture != nullptr)
{
SetupLights(di, lightdata);
}
*/
MakeVertices(di, translucent);
}
di->AddWall(this);
// make sure that following parts of the same linedef do not get this one's vertex and lighting info.
vertcount = 0;
dynlightindex = -1;
flags &= ~(HWF_TRANSLUCENT|HWF_CLAMPX|HWF_CLAMPY);
}
//==========================================================================
//
// will be done later.
//
//==========================================================================
void HWWall::PutPortal(HWDrawInfo *di, int ptype, int plane)
{
HWPortal * portal = nullptr;
MakeVertices(di, false);
switch (ptype)
{
#if 0
// portals don't go into the draw list.
// Instead they are added to the portal manager
case PORTALTYPE_HORIZON:
horizon = portalState.UniqueHorizons.Get(horizon);
portal = di->FindPortal(horizon);
if (!portal)
{
portal = new HWHorizonPortal(&portalState, horizon, di->Viewpoint);
di->Portals.Push(portal);
}
portal->AddLine(this);
break;
case PORTALTYPE_SKYBOX:
portal = di->FindPortal(secportal);
if (!portal)
{
// either a regular skybox or an Eternity-style horizon
if (secportal->mType != PORTS_SKYVIEWPOINT) portal = new HWEEHorizonPortal(&portalState, secportal);
else
{
portal = new HWSkyboxPortal(&portalState, secportal);
di->Portals.Push(portal);
}
}
portal->AddLine(this);
break;
#endif
case PORTALTYPE_SECTORSTACK:
portal = di->FindPortal(this->portal);
if (!portal)
{
portal = new HWSectorStackPortal(&portalState, this->portal);
di->Portals.Push(portal);
}
portal->AddLine(this);
break;
#if 0
case PORTALTYPE_PLANEMIRROR:
if (portalState.PlaneMirrorMode * planemirror->fC() <= 0)
{
planemirror = portalState.UniquePlaneMirrors.Get(planemirror);
portal = di->FindPortal(planemirror);
if (!portal)
{
portal = new HWPlaneMirrorPortal(&portalState, planemirror);
di->Portals.Push(portal);
}
portal->AddLine(this);
}
break;
#endif
case PORTALTYPE_MIRROR:
// These are unique. No need to look existing ones up.
portal = new HWMirrorPortal(&portalState, seg);
di->Portals.Push(portal);
portal->AddLine(this);
if (gl_mirror_envmap)
{
// draw a reflective layer over the mirror
di->AddMirrorSurface(this);
}
break;
case PORTALTYPE_LINETOLINE:
// These are also unique.
portal = new HWLineToLinePortal(&portalState, seg, &wall[seg->portalnum]);
di->Portals.Push(portal);
portal->AddLine(this);
break;
case PORTALTYPE_LINETOSPRITE:
// These are also unique.
assert(seg->portalnum >= 0 && seg->portalnum < MAXSPRITES);
portal = new HWLineToSpritePortal(&portalState, seg, &::sprite[seg->portalnum]);
di->Portals.Push(portal);
portal->AddLine(this);
break;
case PORTALTYPE_SKY:
sky = portalState.UniqueSkies.Get(sky);
portal = di->FindPortal(sky);
if (!portal)
{
portal = new HWSkyPortal(screen->mSkyData, &portalState, sky);
di->Portals.Push(portal);
}
portal->AddLine(this);
break;
}
vertcount = 0;
if (plane != -1 && portal)
{
portal->planesused |= (1<<plane);
}
}
//==========================================================================
//
// Build does not have horizon effects.
//
//==========================================================================
bool HWWall::DoHorizon(HWDrawInfo* di, walltype* seg, sectortype* fs, DVector2& v1, DVector2& v2)
{
#if 0
HWHorizonInfo hi;
lightlist_t * light;
// ZDoom doesn't support slopes in a horizon sector so I won't either!
ztop[1] = ztop[0] = fs->GetPlaneTexZ(sector_t::ceiling);
zbottom[1] = zbottom[0] = fs->GetPlaneTexZ(sector_t::floor);
auto vpz = di->Viewpoint.Pos.Z;
if (vpz < fs->GetPlaneTexZ(sector_t::ceiling))
{
if (vpz > fs->GetPlaneTexZ(sector_t::floor))
zbottom[1] = zbottom[0] = vpz;
if (fs->GetTexture(sector_t::ceiling) == skyflatnum)
{
SkyPlane(di, fs, sector_t::ceiling, false);
}
else
{
horizon = &hi;
PutPortal(di, PORTALTYPE_HORIZON, -1);
}
ztop[1] = ztop[0] = zbottom[0];
}
if (vpz > fs->GetPlaneTexZ(sector_t::floor))
{
zbottom[1] = zbottom[0] = fs->GetPlaneTexZ(sector_t::floor);
if (fs->GetTexture(sector_t::floor) == skyflatnum)
{
SkyPlane(di, fs, sector_t::floor, false);
}
else
{
horizon = &hi;
PutPortal(di, PORTALTYPE_HORIZON, -1);
}
}
#endif
return true;
}
//==========================================================================
//
//
//
//==========================================================================
bool HWWall::SetWallCoordinates(walltype * seg, float topleft, float topright, float bottomleft, float bottomright)
{
//
//
// set up coordinates for the left side of the polygon
//
// check left side for intersections
if (topleft >= bottomleft)
{
// normal case
ztop[0] = topleft;
zbottom[0] = bottomleft;
}
else
{
// ceiling below floor - clip to the visible part of the wall
float dch = topright - topleft;
float dfh = bottomright - bottomleft;
float inter_x = (bottomleft - topleft) / (dch - dfh);
float inter_y = topleft + inter_x * dch;
glseg.x1 = glseg.x1 + inter_x * (glseg.x2 - glseg.x1);
glseg.y1 = glseg.y1 + inter_x * (glseg.y2 - glseg.y1);
glseg.fracleft = inter_x;
zbottom[0] = ztop[0] = inter_y;
}
//
//
// set up coordinates for the right side of the polygon
//
// check left side for intersections
if (topright >= bottomright)
{
// normal case
ztop[1] = topright;
zbottom[1] = bottomright;
}
else
{
// ceiling below floor - clip to the visible part of the wall
float dch = topright - topleft;
float dfh = bottomright - bottomleft;
float inter_x = (bottomleft - topleft) / (dch - dfh);
float inter_y = topleft + inter_x * dch;
glseg.x2 = glseg.x1 + inter_x * (glseg.x2 - glseg.x1);
glseg.y2 = glseg.y1 + inter_x * (glseg.y2 - glseg.y1);
glseg.fracright = inter_x;
zbottom[1] = ztop[1] = inter_y;
}
return true;
}
//==========================================================================
//
// Do some tweaks with the texture coordinates to reduce visual glitches
//
//==========================================================================
void HWWall::CheckTexturePosition()
{
float sub;
if (texture->isHardwareCanvas()) return;
// clamp texture coordinates to a reasonable range.
// Extremely large values can cause visual problems
if (tcs[UPLFT].v < tcs[LOLFT].v || tcs[UPRGT].v < tcs[LORGT].v)
{
if (tcs[UPLFT].v < tcs[UPRGT].v)
{
sub = float(xs_FloorToInt(tcs[UPLFT].v));
}
else
{
sub = float(xs_FloorToInt(tcs[UPRGT].v));
}
tcs[UPLFT].v -= sub;
tcs[UPRGT].v -= sub;
tcs[LOLFT].v -= sub;
tcs[LORGT].v -= sub;
}
else
{
if (tcs[LOLFT].v < tcs[LORGT].v)
{
sub = float(xs_FloorToInt(tcs[LOLFT].v));
}
else
{
sub = float(xs_FloorToInt(tcs[LORGT].v));
}
tcs[UPLFT].v -= sub;
tcs[UPRGT].v -= sub;
tcs[LOLFT].v -= sub;
tcs[LORGT].v -= sub;
}
if (tcs[UPLFT].u >= 0.f && tcs[UPRGT].u >= 0.f && tcs[LOLFT].u >= 0.f && tcs[LORGT].u >= 0.f &&
tcs[UPLFT].u <= 1.f && tcs[UPRGT].u <= 1.f && tcs[LOLFT].u <= 1.f && tcs[LORGT].u <= 1.f)
{
flags |= HWF_CLAMPX;
}
if (tcs[UPLFT].v >= 0.f && tcs[UPRGT].v >= 0.f && tcs[LOLFT].v >= 0.f && tcs[LORGT].v >= 0.f &&
tcs[UPLFT].v <= 1.f && tcs[UPRGT].v <= 1.f && tcs[LOLFT].v <= 1.f && tcs[LORGT].v <= 1.f)
{
flags |= HWF_CLAMPY;
}
}
//==========================================================================
//
// Common part of wall drawers
//
//==========================================================================
void HWWall::DoTexture(HWDrawInfo* di, walltype* wal, walltype* refwall, float refheight, float topleft, float topright, float bottomleft, float bottomright)
{
auto glsave = glseg;
SetWallCoordinates(wal, topleft, topright, bottomleft, bottomright);
bool xflipped = (wal->cstat & CSTAT_WALL_XFLIP);
float leftdist = xflipped ? 1.f - glseg.fracleft : glseg.fracleft;
float rightdist = xflipped ? 1.f - glseg.fracright : glseg.fracright;
float tw = texture->GetDisplayWidth();
float th = texture->GetDisplayHeight();
int pow2size = 1 << sizeToBits(th);
if (pow2size < th) pow2size *= 2;
float ypanning = refwall->ypan_ ? pow2size * refwall->ypan_ / (256.0f * th) : 0;
tcs[LOLFT].u = tcs[UPLFT].u = ((leftdist * 8.f * wal->xrepeat) + refwall->xpan_) / tw;
tcs[LORGT].u = tcs[UPRGT].u = ((rightdist * 8.f * wal->xrepeat) + refwall->xpan_) / tw;
auto setv = [=](float hl, float hr, float frac) -> float
{
float h = hl + (hr - hl) * frac;
h = (-(float)(refheight + (h * 256)) / ((th * 2048.0f) / (float)(wal->yrepeat))) + ypanning;
if (refwall->cstat & CSTAT_WALL_YFLIP) h = -h;
return h;
};
tcs[UPLFT].v = setv(topleft, topright, glseg.fracleft);
tcs[LOLFT].v = setv(bottomleft, bottomright, glseg.fracleft);
tcs[UPRGT].v = setv(topleft, topright, glseg.fracright);
tcs[LORGT].v = setv(bottomleft, bottomright, glseg.fracright);
if (th == pow2size) CheckTexturePosition(); // for NPOT textures this adjustment can break things.
bool trans = type == RENDERWALL_M2S && maskWallHasTranslucency(wal);
if (trans)
{
RenderStyle = GetRenderStyle(0, !!(wal->cstat & CSTAT_WALL_TRANS_FLIP));
alpha = GetAlphaFromBlend((wal->cstat & CSTAT_WALL_TRANS_FLIP) ? DAMETH_TRANS2 : DAMETH_TRANS1, 0);
}
PutWall(di, trans);
flags = 0;
glseg = glsave;
}
//==========================================================================
//
// Handle one sided walls
//
//==========================================================================
void HWWall::DoOneSidedTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector,
float topleft, float topright, float bottomleft, float bottomright)
{
// get the alignment reference position.
int refheight;
if ((wal->cstat & CSTAT_WALL_1WAY) && backsector)
{
if ((!(wal->cstat & CSTAT_WALL_BOTTOM_SWAP) && (wal->cstat & CSTAT_WALL_1WAY)) ||
((wal->cstat & CSTAT_WALL_BOTTOM_SWAP) && (wall[wal->nextwall].cstat & CSTAT_WALL_ALIGN_BOTTOM)))
refheight = frontsector->ceilingz;
else
refheight = backsector->floorz;
}
else
{
refheight = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->floorz : frontsector->ceilingz;
}
type = RENDERWALL_M1S;
DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright);
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::DoUpperTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector,
float topleft, float topright, float bottomleft, float bottomright)
{
// get the alignment reference position.
int refheight = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->ceilingz : backsector->ceilingz;
type = RENDERWALL_TOP;
DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright);
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::DoLowerTexture(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector,
float topleft, float topright, float bottomleft, float bottomright)
{
// get the alignment reference position.
int refheight;
auto refwall = (wal->cstat & CSTAT_WALL_BOTTOM_SWAP) ? &wall[wal->nextwall] : wal;
refheight = (refwall->cstat & CSTAT_WALL_ALIGN_BOTTOM) ? frontsector->ceilingz : backsector->floorz;
shade = refwall->shade;
palette = refwall->pal;
type = RENDERWALL_BOTTOM;
DoTexture(di, wal, refwall, refheight, topleft, topright, bottomleft, bottomright);
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::DoMidTexture(HWDrawInfo* di, walltype* wal,
sectortype* front, sectortype* back,
float fch1, float fch2, float ffh1, float ffh2,
float bch1, float bch2, float bfh1, float bfh2)
{
float topleft,bottomleft,topright,bottomright;
int refheight;
const int swapit = (wal->cstat & CSTAT_WALL_ALIGN_BOTTOM);
if (wal->cstat & CSTAT_WALL_1WAY)
{
// 1-sided wall
refheight = swapit ? front->ceilingz : back->ceilingz;
}
else
{
// masked wall
if (swapit)
refheight = min(front->floorz, back->floorz);
else
refheight = max(front->ceilingz, back->ceilingz);
}
topleft = std::min(bch1,fch1);
topright = std::min(bch2,fch2);
bottomleft = std::max(bfh1,ffh1);
bottomright = std::max(bfh2,ffh2);
if (topleft<=bottomleft && topright<=bottomright) return;
type = seg->cstat & CSTAT_WALL_1WAY ? RENDERWALL_M1S : RENDERWALL_M2S;
// todo: transparency.
DoTexture(di, wal, wal, refheight, topleft, topright, bottomleft, bottomright);
RenderStyle = STYLE_Translucent;
alpha = 1.f;
}
//==========================================================================
//
//
//
//==========================================================================
void HWWall::Process(HWDrawInfo* di, walltype* wal, sectortype* frontsector, sectortype* backsector)
{
auto backwall = wal->nextwall >= 0 && wal->nextwall < numwalls ? &wall[wal->nextwall] : nullptr;
auto p2wall = &wall[wal->point2];
float fch1;
float ffh1;
float fch2;
float ffh2;
FVector2 v1(WallStartX(wal), WallStartY(wal));
FVector2 v2(WallEndX(wal), WallEndY(wal));
PlanesAtPoint(frontsector, wal->x, wal->y, &fch1, &ffh1);
PlanesAtPoint(frontsector, p2wall->x, p2wall->y, &fch2, &ffh2);
#ifdef _DEBUG
if (wal - wall == 788)
{
int a = 0;
}
#endif
this->seg = wal;
this->frontsector = frontsector;
this->backsector = backsector;
Sprite = nullptr;
vertindex = 0;
vertcount = 0;
glseg.x1 = v1.X;
glseg.y1 = v1.Y;
glseg.x2 = v2.X;
glseg.y2 = v2.Y;
glseg.fracleft = 0;
glseg.fracright = 1;
flags = 0;
dynlightindex = -1;
shade = wal->shade;
palette = wal->pal;
fade = lookups.getFade(wal->pal);
visibility = sectorVisibility(frontsector);
alpha = 1.0f;
RenderStyle = STYLE_Translucent;
texture = NULL;
/*
if (wal->linedef->special == Line_Horizon)
{
SkyNormal(di, frontsector, v1, v2);
DoHorizon(di, wal, frontsector, v1, v2);
return;
}
*/
bool isportal = false;// wal->linedef->isVisualPortal() && wal->sidedef == wal->linedef->sidedef[0];
if (seg->portalflags)
{
int ptype = -1;
if (seg->portalflags == PORTAL_WALL_MIRROR) ptype = PORTALTYPE_MIRROR;
else if (seg->portalflags == PORTAL_WALL_VIEW) ptype = PORTALTYPE_LINETOLINE;
else if (seg->portalflags == PORTAL_WALL_TO_SPRITE) ptype = PORTALTYPE_LINETOSPRITE;
if (ptype != -1)
{
ztop[0] = fch1;
ztop[1] = fch2;
zbottom[0] = ffh1;
zbottom[1] = ffh2;
PutPortal(di, ptype, -1);
return;
}
}
if (!backsector || !backwall)
{
// sector's sky
SkyNormal(di, frontsector, v1, v2, fch1, fch2, ffh1, ffh2);
// normal texture
int tilenum = ((wal->cstat & CSTAT_WALL_1WAY) && wal->nextwall != -1) ? wal->overpicnum : wal->picnum;
setgotpic(tilenum);
tileUpdatePicnum(&tilenum, int(wal-wall) + 16384, wal->cstat);
texture = tileGetTexture(tilenum);
if (texture && texture->isValid())
{
DoOneSidedTexture(di, wal, frontsector, backsector, fch1, fch2, ffh1, ffh2);
}
}
else // two sided
{
float bfh1;
float bfh2;
float bch1;
float bch2;
PlanesAtPoint(backsector, wal->x, wal->y, &bch1, &bfh1);
PlanesAtPoint(backsector, p2wall->x, p2wall->y, &bch2, &bfh2);
float zalign = 0.f;
SkyTop(di, wal, frontsector, backsector, v1, v2, fch1, fch2);
SkyBottom(di, wal, frontsector, backsector, v1, v2, ffh1, ffh2);
// upper texture
if (!(frontsector->ceilingstat & backsector->ceilingstat & CSTAT_SECTOR_SKY))
{
float bch1a = bch1;
float bch2a = bch2;
if (ffh1 > bch1 || ffh2 > bch2)
{
// the back sector's floor obstructs part of this wall. Todo: Handle the portal case better.
if ((ffh1 > bch1 && ffh2 > bch2) || frontsector->portalflags == PORTAL_SECTOR_FLOOR)
{
bch2a = ffh2;
bch1a = ffh1;
}
}
if (bch1a < fch1 || bch2a < fch2)
{
int tilenum = wal->picnum;
setgotpic(tilenum);
tileUpdatePicnum(&tilenum, int(wal - wall) + 16384, wal->cstat);
texture = tileGetTexture(tilenum);
if (texture && texture->isValid())
{
DoUpperTexture(di, wal, frontsector, backsector, fch1, fch2, bch1a, bch2a);
}
}
}
if (wal->cstat & (CSTAT_WALL_MASKED | CSTAT_WALL_1WAY))
{
int tilenum = wal->overpicnum;
setgotpic(tilenum);
tileUpdatePicnum(&tilenum, int(wal - wall) + 16384, wal->cstat);
texture = tileGetTexture(tilenum);
if (texture && texture->isValid())
{
DoMidTexture(di, wal, frontsector, backsector, fch1, fch2, ffh1, ffh2, bch1, bch2, bfh1, bfh2);
}
}
// lower texture
if (!(frontsector->floorstat & backsector->floorstat & CSTAT_SECTOR_SKY))
{
if (fch1 < bfh1 || fch2 < bfh2)
{
// the back sector's ceiling obstructs part of this wall. Todo: Handle the portal case better.
if ((fch1 < bfh1 && fch2 < bfh2) || frontsector->portalflags == PORTAL_SECTOR_CEILING)
{
bfh1 = fch1;
bfh2 = fch2;
}
}
if (bfh1 > ffh1 || bfh2 > ffh2)
{
auto w = (wal->cstat & CSTAT_WALL_BOTTOM_SWAP) ? backwall : wal;
int tilenum = w->picnum;
setgotpic(tilenum);
tileUpdatePicnum(&tilenum, int(wal - wall) + 16384, w->cstat);
texture = tileGetTexture(tilenum);
if (texture && texture->isValid())
{
DoLowerTexture(di, wal, frontsector, backsector, bfh1, bfh2, ffh1, ffh2);
}
}
}
}
}
void HWWall::ProcessWallSprite(HWDrawInfo* di, spritetype* spr, sectortype* sector)
{
auto tex = tileGetTexture(spr->picnum);
if (!tex || !tex->isValid()) return;
seg = nullptr;
Sprite = spr;
vec2_t pos[2];
int sprz = spr->pos.z;
GetWallSpritePosition(spr, spr->pos.vec2, pos, true);
glseg.x1 = pos[0].x * (1 / 16.f);
glseg.y1 = pos[0].y * (1 / -16.f);
glseg.x2 = pos[1].x * (1 / 16.f);
glseg.y2 = pos[1].y * (1 / -16.f);
if (spr->cstat & CSTAT_SPRITE_ONE_SIDED)
{
if (PointOnLineSide(di->Viewpoint.Pos.X, di->Viewpoint.Pos.Y, glseg.x1, glseg.y1, glseg.x2 - glseg.x1, glseg.y2 - glseg.y1) <= 0)
{
return;
}
}
vertindex = 0;
vertcount = 0;
type = RENDERWALL_M2S;
frontsector = sector;
backsector = sector;
texture = tex;
flags = HWF_CLAMPX|HWF_CLAMPY;
dynlightindex = -1;
shade = spr->shade;
palette = spr->pal;
fade = lookups.getFade(sector->floorpal); // fog is per sector.
visibility = sectorVisibility(sector);
SetSpriteTranslucency(Sprite, alpha, RenderStyle);
int height, topofs;
if (hw_hightile && TileFiles.tiledata[spr->picnum].hiofs.xsize)
{
height = TileFiles.tiledata[spr->picnum].hiofs.ysize;
topofs = (TileFiles.tiledata[spr->picnum].hiofs.yoffs + spr->yoffset);
}
else
{
height = (int)tex->GetDisplayHeight();
topofs = ((int)tex->GetDisplayTopOffset() + spr->yoffset);
}
walldist = IsOnWall(spr, height);
if (spr->cstat & CSTAT_SPRITE_YFLIP)
topofs = -topofs;
sprz -= ((topofs * spr->yrepeat) << 2);
if (spr->cstat & CSTAT_SPRITE_YCENTER)
{
sprz += ((height * spr->yrepeat) << 1);
if (height & 1) sprz += (spr->yrepeat << 1); // Odd yspans (taken from polymost as-is)
}
glseg.fracleft = 0;
glseg.fracright = 1;
tcs[LOLFT].u = tcs[UPLFT].u = (spr->cstat & CSTAT_SPRITE_XFLIP) ? 1.f : 0.f;
tcs[LORGT].u = tcs[UPRGT].u = (spr->cstat & CSTAT_SPRITE_XFLIP) ? 0.f : 1.f;
tcs[UPLFT].v = tcs[UPRGT].v = (spr->cstat & CSTAT_SPRITE_YFLIP) ? 1.f : 0.f;
tcs[LOLFT].v = tcs[LORGT].v = (spr->cstat & CSTAT_SPRITE_YFLIP) ? 0.f : 1.f;
zbottom[0] = zbottom[1] = (sprz) * (1 / -256.);
ztop[0] = ztop[1] = (sprz - ((height * spr->yrepeat) << 2)) * (1 / -256.);
if (zbottom[0] > ztop[0])
{
// reorder coordinates to make the clipping code below behave.
auto zz = zbottom[0];
zbottom[0] = zbottom[1] = ztop[0];
ztop[0] = ztop[1] = zz;
tcs[UPLFT].v = tcs[UPRGT].v = 1.f - tcs[UPLFT].v;
tcs[LOLFT].v = tcs[LORGT].v = 1.f - tcs[LOLFT].v;
}
// Clip sprites to ceilings/floors
if (!(sector->ceilingstat & CSTAT_SECTOR_SKY))
{
float polyh = (ztop[0] - zbottom[0]);
float ceilingz = sector->ceilingz * (1 / -256.f);
if (ceilingz < ztop[0] && ceilingz > zbottom[0])
{
float newv = (ceilingz - zbottom[0]) / polyh;
tcs[UPLFT].v = tcs[UPRGT].v = tcs[LOLFT].v + newv * (tcs[UPLFT].v - tcs[LOLFT].v);
ztop[0] = ztop[1] = ceilingz;
}
}
if (!(sector->floorstat & CSTAT_SECTOR_SKY))
{
float polyh = (ztop[0] - zbottom[0]);
float floorz = sector->floorz * (1 / -256.f);
if (floorz < ztop[0] && floorz > zbottom[0])
{
float newv = (floorz - zbottom[0]) / polyh;
tcs[LOLFT].v = tcs[LORGT].v = tcs[LOLFT].v + newv * (tcs[UPLFT].v - tcs[LOLFT].v);
zbottom[0] = zbottom[1] = floorz;
}
}
// If the sprite is backward, flip it around so that we have guaranteed orientation when this is about to be sorted.
if (PointOnLineSide(di->Viewpoint.Pos.XY(), DVector2(glseg.x1, glseg.y1), DVector2(glseg.x2, glseg.y2)) < 0)
{
std::swap(glseg.x1, glseg.x2);
std::swap(glseg.y1, glseg.y2);
// z is always the same on both sides.
std::swap(tcs[LOLFT], tcs[LORGT]);
std::swap(tcs[UPLFT], tcs[UPRGT]);
}
PutWall(di, spriteHasTranslucency(Sprite));
}