//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//
void
MLRLightMap::DrawLightMaps(MLRSorter *sorter)
{
Check_Object(stream);
void *ptr, *end = stream->GetPointer();
Stuff::Matrix4D *currentMatrix=NULL;
MLRClippingState currentClippingState;
MLRState currentState, masterState;
unsigned short stride;
int i, pointerValue;
Stuff::Point3D *coords = NULL;
Stuff::RGBAColor color;
Stuff::RGBAColor *colors = NULL;
Vector2DScalar *texCoords = NULL;
DWORD argb = 0xffffffff;
Check_Object(vertexPool);
GOSVertex* gos_vertices = vertexPool->GetActualVertexPool();
int numGOSVertices = 0;
int msd;
MemoryStreamData type;
stream->Rewind();
ptr = stream->GetPointer();
while(ptr < end)
{
*stream >> msd;
type = static_cast<MemoryStreamData>(msd);
switch(msd)
{
case Matrix4D:
*stream >> pointerValue;
currentMatrix = reinterpret_cast<Stuff::Matrix4D*>(pointerValue);
break;
case ClippingState:
currentClippingState.Load(stream);
break;
case MasterRenderState:
masterState.Load(stream, Current_MLR_Version);
break;
case LightMapRenderState:
{
MLRState lightmapState;
lightmapState.Load(stream, Current_MLR_Version);
lightmapState.Combine(masterState, lightmapState);
if(numGOSVertices && (lightmapState != currentState))
{
vertexPool->Increase(numGOSVertices);
SortData *sd = sorter->SetRawData
(
gos_vertices,
numGOSVertices,
currentState,
SortData::TriList
);
if(currentState.GetDrawNowMode()==MLRState::DrawNowOnMode)
{
SortData::DrawFunc drawFunc = sd->Draw[sd->type];
(sd->*drawFunc)();
}
else
{
sorter->AddSortRawData(sd);
}
gos_vertices = vertexPool->GetActualVertexPool();
numGOSVertices = 0;
}
currentState = lightmapState;
}
break;
case Polygon:
{
*stream >> stride;
Verify(stride<=Limits::Max_Number_Vertices_Per_Polygon);
*stream >> color;
argb = GOSCopyColor(&color);
coords = (Stuff::Point3D *)stream->GetPointer();
stream->AdvancePointer(stride*sizeof(Stuff::Point3D));
texCoords = (Vector2DScalar *)stream->GetPointer();
stream->AdvancePointer(stride*sizeof(Vector2DScalar));
MLRClippingState theAnd(0x3f), theOr(0);
MLRClippingState *cs = clippingStates->GetData();
Vector4D *v4d = transformedCoords->GetData();
for(i=0;i<stride;i++,v4d++,cs++)
{
v4d->Multiply(coords[i], *currentMatrix);
if(currentClippingState!=0)
{
cs->Clip4dVertex(v4d);
theAnd &= *cs;
theOr |= *cs;
}
#if defined(_ARMOR)
else
{
Verify((*transformedCoords)[i].x >= 0.0f && (*transformedCoords)[i].x <= (*transformedCoords)[i].w );
Verify((*transformedCoords)[i].y >= 0.0f && (*transformedCoords)[i].y <= (*transformedCoords)[i].w );
Verify((*transformedCoords)[i].z >= 0.0f && (*transformedCoords)[i].z <= (*transformedCoords)[i].w );
}
#endif
}
if(theOr == 0)
{
for(i=1;i<stride-1;i++)
{
Verify((vertexPool->GetLast() + 3 + numGOSVertices) < vertexPool->GetLength());
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
transformedCoords->GetData(),
texCoords,
0, i + 1, i
);
gos_vertices[numGOSVertices].argb = argb;
gos_vertices[numGOSVertices+1].argb = argb;
gos_vertices[numGOSVertices+2].argb = argb;
numGOSVertices+=3;
}
}
else
{
if(theAnd != 0)
{
break;
}
else
{
int k, k0, k1, l, mask, ct = 0;
Scalar a = 0.0f;
int numberVerticesPerPolygon = 0;
//
//---------------------------------------------------------------
// Handle the case of a single clipping plane by stepping through
// the vertices and finding the edge it originates
//---------------------------------------------------------------
//
bool firstIsIn;
MLRClippingState theTest;
if (theOr.GetNumberOfSetBits() == 1)
{
#ifdef LAB_ONLY
Set_Statistic(PolysClippedButOnePlane, PolysClippedButOnePlane+1);
#endif
for(k=0;k<stride;k++)
{
int clipped_index = numberVerticesPerPolygon;
k0 = k;
k1 = (k+1) < stride ? k+1 : 0;
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
theTest = (*clippingStates)[k0];
if(theTest == 0)
{
firstIsIn = true;
(*clipExtraCoords)[clipped_index] = (*transformedCoords)[k0];
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
(*clipExtraTexCoords)[clipped_index] = texCoords[k0];
numberVerticesPerPolygon++;
clipped_index++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if((*clippingStates)[k1] == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else
{
firstIsIn = false;
if((*clippingStates)[k1] != 0)
{
Verify((*clippingStates)[k1] == (*clippingStates)[k0]);
continue;
}
}
//
//--------------------------------------------------
// We now find the distance along the edge where the
// clipping plane will intersect
//--------------------------------------------------
//
mask = 1;
theTest |= (*clippingStates)[k1];
//
//-----------------------------------------------------
// Find the boundary conditions that match our clipping
// plane
//-----------------------------------------------------
//
for (l=0; l<MLRClippingState::NextBit; l++)
{
if(theTest.IsClipped(mask))
{
// GetDoubleBC(l, bc0, bc1, transformedCoords[k0], transformedCoords[k1]);
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
if(firstIsIn==true)
{
a = GetLerpFactor(l, (*transformedCoords)[k0], (*transformedCoords)[k1]);
}
else
{
a = GetLerpFactor(l, (*transformedCoords)[k1], (*transformedCoords)[k0]);
}
Verify(a >= 0.0f && a <= 1.0f);
ct = l;
break;
}
mask <<= 1;
}
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
if(firstIsIn==true)
{
(*clipExtraCoords)[clipped_index].Lerp(
(*transformedCoords)[k0],
(*transformedCoords)[k1],
a
);
DoClipTrick((*clipExtraCoords)[clipped_index], ct);
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
(*clipExtraTexCoords)[clipped_index].Lerp
(
texCoords[k0],
texCoords[k1],
a
);
}
else
{
(*clipExtraCoords)[clipped_index].Lerp(
(*transformedCoords)[k1],
(*transformedCoords)[k0],
a
);
DoClipTrick((*clipExtraCoords)[clipped_index], ct);
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
(*clipExtraTexCoords)[clipped_index].Lerp
(
texCoords[k1],
texCoords[k0],
a
);
}
//
//--------------------------------
// Bump the polygon's vertex count
//--------------------------------
//
numberVerticesPerPolygon++;
}
}
//
//---------------------------------------------------------------
// We have to handle multiple planes. We do this by creating two
// buffers and we switch between them as we clip plane by plane
//---------------------------------------------------------------
//
else
{
#ifdef LAB_ONLY
Set_Statistic(PolysClippedButGOnePlane, PolysClippedButGOnePlane+1);
#endif
ClipData2 srcPolygon, dstPolygon;
int dstBuffer = 1;
srcPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
srcPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
srcPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
//
//----------------------------------------------------------
// unravel and copy the original data into the source buffer
//----------------------------------------------------------
//
for(k=0;k<stride;k++)
{
srcPolygon.coords[k] = (*transformedCoords)[k];
srcPolygon.texCoords[k] = texCoords[k];
srcPolygon.clipPerVertex[k] = (*clippingStates)[k];
}
srcPolygon.length = stride;
//
//--------------------------------
// Point to the destination buffer
//--------------------------------
//
dstBuffer = 0;
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.length = 0;
//
//-----------------------------------------------------------
// Spin through each plane that clipped the primitive and use
// it to actually clip the primitive
//-----------------------------------------------------------
//
mask = 1;
MLRClippingState theNewOr(0);
int loop = 4;
do
{
for(l=0; l<MLRClippingState::NextBit; l++)
{
if(theOr.IsClipped(mask))
{
//
//-----------------------------------
// Clip each vertex against the plane
//-----------------------------------
//
for(k=0;k<srcPolygon.length;k++)
{
k1 = (k+1) < srcPolygon.length ? k+1 : 0;
theTest = srcPolygon.clipPerVertex[k];
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
if(theTest.IsClipped(mask) == 0)
{
firstIsIn = true;
dstPolygon.coords[dstPolygon.length] =
srcPolygon.coords[k];
dstPolygon.clipPerVertex[dstPolygon.length] =
srcPolygon.clipPerVertex[k];
dstPolygon.texCoords[dstPolygon.length] =
srcPolygon.texCoords[k];
dstPolygon.length++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if(srcPolygon.clipPerVertex[k1].IsClipped(mask) == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else
{
firstIsIn = false;
if(srcPolygon.clipPerVertex[k1].IsClipped(mask) != 0)
{
Verify(
srcPolygon.clipPerVertex[k1].IsClipped(mask)
== srcPolygon.clipPerVertex[k].IsClipped(mask)
);
continue;
}
}
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
if(firstIsIn == true)
{
a = GetLerpFactor (l, srcPolygon.coords[k], srcPolygon.coords[k1]);
Verify(a >= 0.0f && a <= 1.0f);
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
dstPolygon.coords[dstPolygon.length].Lerp(
srcPolygon.coords[k],
srcPolygon.coords[k1],
a
);
DoClipTrick(dstPolygon.coords[dstPolygon.length], l);
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
dstPolygon.texCoords[dstPolygon.length].Lerp
(
srcPolygon.texCoords[k],
srcPolygon.texCoords[k1],
a
);
}
else
{
a = GetLerpFactor (l, srcPolygon.coords[k1], srcPolygon.coords[k]);
Verify(a >= 0.0f && a <= 1.0f);
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
dstPolygon.coords[dstPolygon.length].Lerp(
srcPolygon.coords[k1],
srcPolygon.coords[k],
a
);
DoClipTrick(dstPolygon.coords[dstPolygon.length], l);
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
dstPolygon.texCoords[dstPolygon.length].Lerp
(
srcPolygon.texCoords[k1],
srcPolygon.texCoords[k],
a
);
}
//
//-------------------------------------
// We have to generate a new clip state
//-------------------------------------
//
dstPolygon.clipPerVertex[dstPolygon.length].Clip4dVertex(&dstPolygon.coords[dstPolygon.length]);
//
//----------------------------------
// Bump the new polygon vertex count
//----------------------------------
//
dstPolygon.length++;
}
//
//-----------------------------------------------
// Swap source and destination buffer pointers in
// preparation for the next plane test
//-----------------------------------------------
//
srcPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
srcPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
srcPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
srcPolygon.length = dstPolygon.length;
dstBuffer = !dstBuffer;
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.length = 0;
}
mask = mask << 1;
}
theNewOr = 0;
for(k=0;k<srcPolygon.length;k++)
{
theNewOr |= srcPolygon.clipPerVertex[k];
}
theOr == theNewOr;
loop++;
} while (theNewOr != 0 && loop--);
Verify(theNewOr == 0);
//
//--------------------------------------------------
// Move the most recent polygon into the clip buffer
//--------------------------------------------------
//
for(k=0;k<srcPolygon.length;k++)
{
(*clipExtraCoords)[k] = srcPolygon.coords[k];
Verify((*clipExtraCoords)[k].x >= 0.0f && (*clipExtraCoords)[k].x <= (*clipExtraCoords)[k].w );
Verify((*clipExtraCoords)[k].y >= 0.0f && (*clipExtraCoords)[k].y <= (*clipExtraCoords)[k].w );
Verify((*clipExtraCoords)[k].z >= 0.0f && (*clipExtraCoords)[k].z <= (*clipExtraCoords)[k].w );
(*clipExtraTexCoords)[k] = srcPolygon.texCoords[k];
}
numberVerticesPerPolygon = srcPolygon.length;
}
// clip
for(i=1;i<numberVerticesPerPolygon-1;i++)
{
Verify((vertexPool->GetLast() + 3 + numGOSVertices) < vertexPool->GetLength());
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
clipExtraCoords->GetData(),
clipExtraTexCoords->GetData(),
0, i + 1, i
);
gos_vertices[numGOSVertices].argb = argb;
gos_vertices[numGOSVertices+1].argb = argb;
gos_vertices[numGOSVertices+2].argb = argb;
numGOSVertices+=3;
}
}
}
}
break;
case PolygonWithColor:
{
*stream >> stride;
Verify(stride<=Limits::Max_Number_Vertices_Per_Polygon);
coords = (Stuff::Point3D *)stream->GetPointer();
stream->AdvancePointer(stride*sizeof(Stuff::Point3D));
colors = (Stuff::RGBAColor *)stream->GetPointer();
stream->AdvancePointer(stride*sizeof(Stuff::RGBAColor));
texCoords = (Vector2DScalar *)stream->GetPointer();
stream->AdvancePointer(stride*sizeof(Vector2DScalar));
MLRClippingState theAnd(0x3f), theOr(0);
MLRClippingState *cs = clippingStates->GetData();
Vector4D *v4d = transformedCoords->GetData();
for(i=0;i<stride;i++,v4d++,cs++)
{
v4d->Multiply(coords[i], *currentMatrix);
if(currentClippingState!=0)
{
cs->Clip4dVertex(v4d);
theAnd &= *cs;
theOr |= *cs;
}
#if defined(_ARMOR)
else
{
Verify((*transformedCoords)[i].x >= 0.0f && (*transformedCoords)[i].x <= (*transformedCoords)[i].w );
Verify((*transformedCoords)[i].y >= 0.0f && (*transformedCoords)[i].y <= (*transformedCoords)[i].w );
Verify((*transformedCoords)[i].z >= 0.0f && (*transformedCoords)[i].z <= (*transformedCoords)[i].w );
}
#endif
}
if(theOr == 0)
{
for(i=1;i<stride-1;i++)
{
Verify((vertexPool->GetLast() + 3 + numGOSVertices) < vertexPool->GetLength());
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
transformedCoords->GetData(),
colors,
texCoords,
0, i + 1, i
);
numGOSVertices+=3;
}
}
else
{
if(theAnd != 0)
{
break;
}
else
{
int k, k0, k1, l, mask, ct = 0;
Scalar a = 0.0f;
int numberVerticesPerPolygon = 0;
//
//---------------------------------------------------------------
// Handle the case of a single clipping plane by stepping through
// the vertices and finding the edge it originates
//---------------------------------------------------------------
//
bool firstIsIn;
MLRClippingState theTest;
if (theOr.GetNumberOfSetBits() == 1)
{
#ifdef LAB_ONLY
Set_Statistic(PolysClippedButOnePlane, PolysClippedButOnePlane+1);
#endif
for(k=0;k<stride;k++)
{
int clipped_index = numberVerticesPerPolygon;
k0 = k;
k1 = (k+1) < stride ? k+1 : 0;
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
theTest = (*clippingStates)[k0];
if(theTest == 0)
{
firstIsIn = true;
(*clipExtraCoords)[clipped_index] = (*transformedCoords)[k0];
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
(*clipExtraColors)[clipped_index] = colors[k0];
(*clipExtraTexCoords)[clipped_index] = texCoords[k0];
numberVerticesPerPolygon++;
clipped_index++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if((*clippingStates)[k1] == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else
{
firstIsIn = false;
if((*clippingStates)[k1] != 0)
{
Verify((*clippingStates)[k1] == (*clippingStates)[k0]);
continue;
}
}
//
//--------------------------------------------------
// We now find the distance along the edge where the
// clipping plane will intersect
//--------------------------------------------------
//)
mask = 1;
theTest |= (*clippingStates)[k1];
//
//-----------------------------------------------------
// Find the boundary conditions that match our clipping
// plane
//-----------------------------------------------------
//
for (l=0; l<MLRClippingState::NextBit; l++)
{
if(theTest.IsClipped(mask))
{
// GetDoubleBC(l, bc0, bc1, transformedCoords[k0], transformedCoords[k1]);
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
if(firstIsIn==true)
{
a = GetLerpFactor(l, (*transformedCoords)[k0], (*transformedCoords)[k1]);
}
else
{
a = GetLerpFactor(l, (*transformedCoords)[k1], (*transformedCoords)[k0]);
}
Verify(a >= 0.0f && a <= 1.0f);
ct = l;
break;
}
mask <<= 1;
}
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
if(firstIsIn==true)
{
(*clipExtraCoords)[clipped_index].Lerp(
(*transformedCoords)[k0],
(*transformedCoords)[k1],
a
);
DoClipTrick((*clipExtraCoords)[clipped_index], ct);
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
(*clipExtraTexCoords)[clipped_index].Lerp
(
texCoords[k0],
texCoords[k1],
a
);
(*clipExtraColors)[clipped_index].Lerp
(
colors[k0],
colors[k1],
a
);
}
else
{
(*clipExtraCoords)[clipped_index].Lerp(
(*transformedCoords)[k1],
(*transformedCoords)[k0],
a
);
DoClipTrick((*clipExtraCoords)[clipped_index], ct);
Verify((*clipExtraCoords)[clipped_index].x >= 0.0f && (*clipExtraCoords)[clipped_index].x <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].y >= 0.0f && (*clipExtraCoords)[clipped_index].y <= (*clipExtraCoords)[clipped_index].w );
Verify((*clipExtraCoords)[clipped_index].z >= 0.0f && (*clipExtraCoords)[clipped_index].z <= (*clipExtraCoords)[clipped_index].w );
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
(*clipExtraTexCoords)[clipped_index].Lerp
(
texCoords[k1],
texCoords[k0],
a
);
(*clipExtraColors)[clipped_index].Lerp
(
colors[k1],
colors[k0],
a
);
}
//
//--------------------------------
// Bump the polygon's vertex count
//--------------------------------
//
numberVerticesPerPolygon++;
}
}
//
//---------------------------------------------------------------
// We have to handle multiple planes. We do this by creating two
// buffers and we switch between them as we clip plane by plane
//---------------------------------------------------------------
//
else
{
#ifdef LAB_ONLY
Set_Statistic(PolysClippedButGOnePlane, PolysClippedButGOnePlane+1);
#endif
ClipData2 srcPolygon, dstPolygon;
int dstBuffer = 1;
srcPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
srcPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
srcPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
srcPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
//
//----------------------------------------------------------
// unravel and copy the original data into the source buffer
//----------------------------------------------------------
//
for(k=0;k<stride;k++)
{
srcPolygon.coords[k] = (*transformedCoords)[k];
srcPolygon.texCoords[k] = texCoords[k];
srcPolygon.colors[k] = colors[k];
srcPolygon.clipPerVertex[k] = (*clippingStates)[k];
}
srcPolygon.length = stride;
//
//--------------------------------
// Point to the destination buffer
//--------------------------------
//
dstBuffer = 0;
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.length = 0;
//
//-----------------------------------------------------------
// Spin through each plane that clipped the primitive and use
// it to actually clip the primitive
//-----------------------------------------------------------
//
mask = 1;
MLRClippingState theNewOr(0);
int loop = 4;
do
{
for(l=0; l<MLRClippingState::NextBit; l++)
{
if(theOr.IsClipped(mask))
{
//
//-----------------------------------
// Clip each vertex against the plane
//-----------------------------------
//
for(k=0;k<srcPolygon.length;k++)
{
k1 = (k+1) < srcPolygon.length ? k+1 : 0;
theTest = srcPolygon.clipPerVertex[k];
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
if(theTest.IsClipped(mask) == 0)
{
firstIsIn = true;
dstPolygon.coords[dstPolygon.length] =
srcPolygon.coords[k];
dstPolygon.clipPerVertex[dstPolygon.length] =
srcPolygon.clipPerVertex[k];
dstPolygon.texCoords[dstPolygon.length] =
srcPolygon.texCoords[k];
dstPolygon.colors[dstPolygon.length] =
srcPolygon.colors[k];
dstPolygon.length++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if(srcPolygon.clipPerVertex[k1].IsClipped(mask) == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else
{
firstIsIn = false;
if(srcPolygon.clipPerVertex[k1].IsClipped(mask) != 0)
{
Verify(
srcPolygon.clipPerVertex[k1].IsClipped(mask)
== srcPolygon.clipPerVertex[k].IsClipped(mask)
);
continue;
}
}
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
if(firstIsIn == true)
{
a = GetLerpFactor (l, srcPolygon.coords[k], srcPolygon.coords[k1]);
Verify(a >= 0.0f && a <= 1.0f);
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
dstPolygon.coords[dstPolygon.length].Lerp(
srcPolygon.coords[k],
srcPolygon.coords[k1],
a
);
DoClipTrick(dstPolygon.coords[dstPolygon.length], l);
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
dstPolygon.texCoords[dstPolygon.length].Lerp
(
srcPolygon.texCoords[k],
srcPolygon.texCoords[k1],
a
);
dstPolygon.colors[dstPolygon.length].Lerp
(
srcPolygon.colors[k],
srcPolygon.colors[k1],
a
);
}
else
{
a = GetLerpFactor (l, srcPolygon.coords[k1], srcPolygon.coords[k]);
Verify(a >= 0.0f && a <= 1.0f);
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
dstPolygon.coords[dstPolygon.length].Lerp(
srcPolygon.coords[k1],
srcPolygon.coords[k],
a
);
DoClipTrick(dstPolygon.coords[dstPolygon.length], l);
//
//-----------------------------------------------------
// If there are texture uv's, we need to lerp them in a
// perspective correct manner
//-----------------------------------------------------
//
dstPolygon.texCoords[dstPolygon.length].Lerp
(
srcPolygon.texCoords[k1],
srcPolygon.texCoords[k],
a
);
dstPolygon.colors[dstPolygon.length].Lerp
(
srcPolygon.colors[k1],
srcPolygon.colors[k],
a
);
}
//
//-------------------------------------
// We have to generate a new clip state
//-------------------------------------
//
dstPolygon.clipPerVertex[dstPolygon.length].Clip4dVertex(&dstPolygon.coords[dstPolygon.length]);
//
//----------------------------------
// Bump the new polygon vertex count
//----------------------------------
//
dstPolygon.length++;
}
//
//-----------------------------------------------
// Swap source and destination buffer pointers in
// preparation for the next plane test
//-----------------------------------------------
//
srcPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
srcPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
srcPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
srcPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
srcPolygon.length = dstPolygon.length;
dstBuffer = !dstBuffer;
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.length = 0;
}
mask = mask << 1;
}
theNewOr = 0;
for(k=0;k<srcPolygon.length;k++)
{
theNewOr |= srcPolygon.clipPerVertex[k];
}
theOr == theNewOr;
loop++;
} while (theNewOr != 0 && loop--);
Verify(theNewOr == 0);
//
//--------------------------------------------------
// Move the most recent polygon into the clip buffer
//--------------------------------------------------
//
for(k=0;k<srcPolygon.length;k++)
{
(*clipExtraCoords)[k] = srcPolygon.coords[k];
Verify((*clipExtraCoords)[k].x >= 0.0f && (*clipExtraCoords)[k].x <= (*clipExtraCoords)[k].w );
Verify((*clipExtraCoords)[k].y >= 0.0f && (*clipExtraCoords)[k].y <= (*clipExtraCoords)[k].w );
Verify((*clipExtraCoords)[k].z >= 0.0f && (*clipExtraCoords)[k].z <= (*clipExtraCoords)[k].w );
(*clipExtraTexCoords)[k] = srcPolygon.texCoords[k];
(*clipExtraColors)[k] = srcPolygon.colors[k];
}
numberVerticesPerPolygon = srcPolygon.length;
}
// clip
for(i=1;i<numberVerticesPerPolygon-1;i++)
{
Verify((vertexPool->GetLast() + 3 + numGOSVertices) < vertexPool->GetLength());
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
clipExtraCoords->GetData(),
clipExtraColors->GetData(),
clipExtraTexCoords->GetData(),
0, i + 1, i
);
numGOSVertices+=3;
}
}
}
}
break;
}
ptr = stream->GetPointer();
}
if(numGOSVertices)
{
vertexPool->Increase(numGOSVertices);
SortData *sd = sorter->SetRawData
(
gos_vertices,
numGOSVertices,
currentState,
SortData::TriList
);
if(currentState.GetDrawNowMode()==MLRState::DrawNowOnMode)
{
SortData::DrawFunc drawFunc = sd->Draw[sd->type];
(sd->*drawFunc)();
}
else
{
sorter->AddSortRawData(sd);
}
}
}
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//
uint32_t MLRNGonCloud::Clip(MLRClippingState clippingFlags, GOSVertexPool* vt)
{
Check_Object(this);
size_t i, j, k;
size_t end, len = *usedNrOfNGons, ret = 0;
#if EFECT_CLIPPED // this effect gets not clipped
int32_t l, mask, k1, ct = 0;
float a = 0.0f, bc0, bc1;
#endif
Check_Object(vt);
gos_vertices = vt->GetActualVertexPool();
Check_Pointer(gos_vertices);
numGOSVertices = 0;
//
//--------------------------------------
// See if we don't have to draw anything
//--------------------------------------
//
if(clippingFlags.GetClippingState() == 0 || len <= 0)
{
if(len <= 0)
{
visible = 0;
}
else
{
//
//-------------------------------
// Handle the non-indexed version
//-------------------------------
//
for(i = 0, j = 0; i < len; i++, j += numOfVertices)
{
// if(IsOn(i) == false)
// {
// continue;
// }
uint32_t inColor = GOSCopyColor(&colors[2 * i]);
uint32_t outColor = GOSCopyColor(&colors[2 * i + 1]);
for(size_t z = 1; z < numOfVertices - 1; z++)
{
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
transformedCoords->GetData(),
j, z + j + 1, z + j,
true
);
gos_vertices[numGOSVertices].argb = inColor;
gos_vertices[numGOSVertices + 1].argb = outColor;
gos_vertices[numGOSVertices + 2].argb = outColor;
numGOSVertices += 3;
}
}
Check_Object(vt);
vt->Increase(numGOSVertices);
visible = uint32_t(numGOSVertices ? 1 : 0);
}
return visible;
}
int32_t myNumberUsedClipVertex, myNumberUsedClipIndex, myNumberUsedClipLength;
myNumberUsedClipVertex = 0;
myNumberUsedClipIndex = 0;
myNumberUsedClipLength = 0;
//
//-------------------------------
// Handle the non-indexed version
//-------------------------------
//
//
//-----------------------------------------------------------------
// Step through each polygon, making sure that we don't try to clip
// backfaced polygons
//-----------------------------------------------------------------
//
for(i = 0, j = 0; i < len; i++, j += numOfVertices)
{
// if(IsOn(i) == false)
// {
// continue;
// }
TurnVisible(i);
//
//---------------------------------------------------------------
// Test each vertex of the polygon against the allowed clipping
// planes, and accumulate status for which planes always clip and
// which planes clipped at least once
//---------------------------------------------------------------
//
theAnd.SetClippingState(0x3f);
theOr.SetClippingState(0);
end = j + numOfVertices;
Stuff::Vector4D* v4d = transformedCoords->GetData() + j;
MLRClippingState* cs = clipPerVertex->GetData() + j;
for(k = j; k < end; k++, v4d++, cs++)
{
cs->Clip4dVertex(v4d);
theAnd &= (*clipPerVertex)[k];
theOr |= (*clipPerVertex)[k];
#ifdef LAB_ONLY
if(*cs == 0)
{
Set_Statistic(NonClippedVertices, NonClippedVertices + 1);
}
else
{
Set_Statistic(ClippedVertices, ClippedVertices + 1);
}
#endif
}
theAnd = theOr = 0; //ASSUME NO CLIPPING NEEDED FOR MC2. Its just not done here!
//
//-------------------------------------------------------------------
// If any bit is set for all vertices, then the polygon is completely
// outside the viewing space and we don't have to draw it. On the
// other hand, if no bits at all were ever set, we can do a trivial
// accept of the polygon
//-------------------------------------------------------------------
//
if(theAnd != 0)
{
TurnInVisible(i);
}
else if(theOr == 0)
{
TurnVisible(i);
uint32_t inColor = GOSCopyColor(&colors[2 * i]);
uint32_t outColor = GOSCopyColor(&colors[2 * i + 1]);
for(size_t z = 1; z < numOfVertices - 1; z++)
{
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
transformedCoords->GetData(),
j, z + j + 1, z + j,
true
);
gos_vertices[numGOSVertices].argb = inColor;
gos_vertices[numGOSVertices + 1].argb = outColor;
gos_vertices[numGOSVertices + 2].argb = outColor;
#ifdef LAB_ONLY
if(gShowClippedPolys)
{
gos_vertices[numGOSVertices].argb = 0xff0000ff;
gos_vertices[numGOSVertices].u = 0.0f;
gos_vertices[numGOSVertices].v = 0.0f;
gos_vertices[numGOSVertices + 1].argb = 0xff0000ff;
gos_vertices[numGOSVertices + 1].u = 0.0f;
gos_vertices[numGOSVertices + 1].v = 0.0f;
gos_vertices[numGOSVertices + 2].argb = 0xff0000ff;
gos_vertices[numGOSVertices + 2].u = 0.0f;
gos_vertices[numGOSVertices + 2].v = 0.0f;
}
#endif
numGOSVertices += 3;
}
ret++;
}
//
//-----------------------------------------------------------------
// It is not a trivial case, so we must now do real clipping on the
// polygon
//-----------------------------------------------------------------
//
else
{
#if EFECT_CLIPPED // this effect gets not clipped
int32_t numberVerticesPerPolygon = 0;
//
//---------------------------------------------------------------
// Handle the case of a single clipping plane by stepping through
// the vertices and finding the edge it originates
//---------------------------------------------------------------
//
if(theOr.GetNumberOfSetBits() == 1)
{
for(k = j; k < end; k++)
{
k1 = (k + 1 < end) ? k + 1 : j;
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
int32_t clipped_index =
myNumberUsedClipVertex + numberVerticesPerPolygon;
theTest = clipPerVertex[k];
if(theTest == 0)
{
clipExtraCoords[clipped_index] = transformedCoords[k];
if(k == j)
{
clipExtraColors[clipped_index] = colors[2 * i];
}
else
{
clipExtraColors[clipped_index] = colors[2 * i + 1];
}
numberVerticesPerPolygon++;
clipped_index++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if(clipPerVertex[k1] == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else if(clipPerVertex[k1] != 0)
{
Verify(clipPerVertex[k1] == clipPerVertex[k]);
continue;
}
//
//--------------------------------------------------
// We now find the distance along the edge where the
// clipping plane will intersect
//--------------------------------------------------
//
mask = 1;
theTest |= clipPerVertex[k1];
//
//-----------------------------------------------------
// Find the boundary conditions that match our clipping
// plane
//-----------------------------------------------------
//
for(l = 0; l < MLRClippingState::NextBit; l++)
{
if(theTest.IsClipped(mask))
{
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
a = GetLerpFactor(l, (*transformedCoords)[k], (*transformedCoords)[k1]);
Verify(a >= 0.0f && a <= 1.0f);
ct = l;
break;
}
mask <<= 1;
}
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
clipExtraCoords[clipped_index].Lerp(
transformedCoords[k],
transformedCoords[k1],
a
);
DoClipTrick(clipExtraCoords[clipped_index], ct);
//
//----------------------------------------------------------
// If there are colors, lerp them in screen space for now as
// most cards do that anyway
//----------------------------------------------------------
//
clipExtraColors[clipped_index].Lerp(
(k == j) ? colors[2 * i] : colors[2 * i + 1],
(k1 == j) ? colors[2 * i] : colors[2 * i + 1],
a
);
//
//--------------------------------
// Bump the polygon's vertex count
//--------------------------------
//
numberVerticesPerPolygon++;
}
}
//
//---------------------------------------------------------------
// We have to handle multiple planes. We do this by creating two
// buffers and we switch between them as we clip plane by plane
//---------------------------------------------------------------
//
else
{
EffectClipData srcPolygon, dstPolygon;
int32_t dstBuffer = 0;
specialClipColors[0] = colors[2 * i];
for(l = 1; l < numOfVertices; l++)
{
specialClipColors[l] = colors[2 * i + 1];
}
//
//-----------------------------------------------------
// Point the source polygon buffer at our original data
//-----------------------------------------------------
//
srcPolygon.coords = &transformedCoords[j];
srcPolygon.clipPerVertex = &clipPerVertex[j];
srcPolygon.flags = 0;
srcPolygon.colors = specialClipColors.GetData();
srcPolygon.length = numOfVertices;
//
//--------------------------------
// Point to the destination buffer
//--------------------------------
//
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.flags = srcPolygon.flags;
dstPolygon.length = 0;
//
//-----------------------------------------------------------
// Spin through each plane that clipped the primitive and use
// it to actually clip the primitive
//-----------------------------------------------------------
//
mask = 1;
MLRClippingState theNewOr(0);
int32_t loop = 4;
do
{
for(l = 0; l < MLRClippingState::NextBit; l++)
{
if(theOr.IsClipped(mask))
{
//
//-----------------------------------
// Clip each vertex against the plane
//-----------------------------------
//
for(k = 0; k < srcPolygon.length; k++)
{
k1 = (k + 1 < srcPolygon.length) ? k + 1 : 0;
theTest = srcPolygon.clipPerVertex[k];
//
//----------------------------------------------------
// If this vertex is inside the viewing space, copy it
// directly to the clipping buffer
//----------------------------------------------------
//
if(theTest.IsClipped(mask) == 0)
{
dstPolygon.coords[dstPolygon.length] =
srcPolygon.coords[k];
dstPolygon.clipPerVertex[dstPolygon.length] =
srcPolygon.clipPerVertex[k];
dstPolygon.colors[dstPolygon.length] =
srcPolygon.colors[k];
dstPolygon.length++;
//
//-------------------------------------------------------
// We don't need to clip this edge if the next vertex is
// also in the viewing space, so just move on to the next
// vertex
//-------------------------------------------------------
//
if(srcPolygon.clipPerVertex[k1].IsClipped(mask) == 0)
{
continue;
}
}
//
//---------------------------------------------------------
// This vertex is outside the viewing space, so if the next
// vertex is also outside the viewing space, no clipping is
// needed and we throw this vertex away. Since only one
// clipping plane is involved, it must be in the same space
// as the first vertex
//---------------------------------------------------------
//
else if(srcPolygon.clipPerVertex[k1].IsClipped(mask) != 0)
{
Verify(
srcPolygon.clipPerVertex[k1].IsClipped(mask)
== srcPolygon.clipPerVertex[k].IsClipped(mask)
);
continue;
}
//
//-------------------------------------------
// Find the clipping interval from bc0 to bc1
//-------------------------------------------
//
bc0 = GetBC(l, srcPolygon.coords[k]);
bc1 = GetBC(l, srcPolygon.coords[k1]);
Verify(!Close_Enough(bc0, bc1));
a = bc0 / (bc0 - bc1);
Verify(a >= 0.0f && a <= 1.0f);
//
//------------------------------
// Lerp the homogeneous position
//------------------------------
//
dstPolygon.coords[dstPolygon.length].Lerp(
srcPolygon.coords[k],
srcPolygon.coords[k1],
a
);
DoCleanClipTrick(dstPolygon.coords[dstPolygon.length], l);
//
//----------------------------------------------------------
// If there are colors, lerp them in screen space for now as
// most cards do that anyway
//----------------------------------------------------------
//
dstPolygon.colors[dstPolygon.length].Lerp(
srcPolygon.colors[k],
srcPolygon.colors[k1],
a
);
//
//-------------------------------------
// We have to generate a new clip state
//-------------------------------------
//
dstPolygon.clipPerVertex[dstPolygon.length].Clip4dVertex(&dstPolygon.coords[dstPolygon.length]);
//
//----------------------------------
// Bump the new polygon vertex count
//----------------------------------
//
dstPolygon.length++;
}
//
//-----------------------------------------------
// Swap source and destination buffer pointers in
// preparation for the next plane test
//-----------------------------------------------
//
srcPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
srcPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
// srcPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
srcPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
srcPolygon.length = dstPolygon.length;
dstBuffer = !dstBuffer;
dstPolygon.coords = clipBuffer[dstBuffer].coords.GetData();
dstPolygon.colors = clipBuffer[dstBuffer].colors.GetData();
// dstPolygon.texCoords = clipBuffer[dstBuffer].texCoords.GetData();
dstPolygon.clipPerVertex = clipBuffer[dstBuffer].clipPerVertex.GetData();
dstPolygon.length = 0;
}
mask = mask << 1;
}
theNewOr = 0;
for(k = 0; k < srcPolygon.length; k++)
{
theNewOr |= srcPolygon.clipPerVertex[k];
}
theOr == theNewOr;
loop++;
}
while(theNewOr != 0 && loop--);
Verify(theNewOr == 0);
//
//--------------------------------------------------
// Move the most recent polygon into the clip buffer
//--------------------------------------------------
//
for(k = 0; k < srcPolygon.length; k++)
{
int32_t clipped_index = myNumberUsedClipVertex + k;
if(srcPolygon.coords[k].z == srcPolygon.coords[k].w)
{
srcPolygon.coords[k].z -= SMALL;
}
clipExtraCoords[clipped_index] = srcPolygon.coords[k];
clipExtraColors[clipped_index] = srcPolygon.colors[k];
}
numberVerticesPerPolygon = srcPolygon.length;
}
clipExtraLength[myNumberUsedClipLength] = numberVerticesPerPolygon;
myNumberUsedClipVertex += numberVerticesPerPolygon;
myNumberUsedClipLength++;
ret++;
// clip
// dont draw the original
TurnInVisible(i);
#endif
}
}
#if EFECT_CLIPPED // this effect gets not clipped
if(myNumberUsedClipLength > 0)
{
for(i = 0, j = 0; i < myNumberUsedClipLength; i++)
{
int32_t stride = clipExtraLength[i];
for(k = 1; k < stride - 1; k++)
{
Verify((vt->GetLast() + 3 + numGOSVertices) < vt->GetLength());
GOSCopyTriangleData(
&gos_vertices[numGOSVertices],
clipExtraCoords.GetData(),
clipExtraColors.GetData(),
j, j + k + 1, j + k,
true
);
#ifdef LAB_ONLY
if(gShowClippedPolys)
{
gos_vertices[numGOSVertices].argb = 0xffff0000;
gos_vertices[numGOSVertices].u = 0.0f;
gos_vertices[numGOSVertices].v = 0.0f;
gos_vertices[numGOSVertices + 1].argb = 0xffff0000;
gos_vertices[numGOSVertices + 1].u = 0.0f;
gos_vertices[numGOSVertices + 1].v = 0.0f;
gos_vertices[numGOSVertices + 2].argb = 0xffff0000;
gos_vertices[numGOSVertices + 2].u = 0.0f;
gos_vertices[numGOSVertices + 2].v = 0.0f;
}
#endif
numGOSVertices += 3;
}
j += stride;
}
}
#endif
vt->Increase(numGOSVertices);
visible = uint32_t(numGOSVertices ? 1 : 0);
if(visible)
{
}
else
{
}
return visible;
}
