dolphin/Source/Core/VideoCommon/Src/BPStructs.cpp

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// Copyright (C) 2003-2009 Dolphin Project.
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, version 2.0.
// 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 General Public License 2.0 for more details.
// A copy of the GPL 2.0 should have been included with the program.
// If not, see http://www.gnu.org/licenses/
// Official SVN repository and contact information can be found at
// http://code.google.com/p/dolphin-emu/
#include <cmath>
#include "Profiler.h"
#include "Statistics.h"
#include "VideoCommon.h"
#include "PixelShaderManager.h"
#include "BPFunctions.h"
#include "BPStructs.h"
#include "TextureDecoder.h"
#include "OpcodeDecoding.h"
#include "VertexLoader.h"
#include "VertexShaderManager.h"
using namespace BPFunctions;
void BPInit()
{
memset(&bpmem, 0, sizeof(bpmem));
bpmem.bpMask = 0xFFFFFF;
}
// ----------------------------------------------------------------------------------------------------------
// Write to the Bypass Memory (Bypass Raster State Registers)
/* ------------------
Called:
At the end of every: OpcodeDecoding.cpp ExecuteDisplayList > Decode() > LoadBPReg
TODO:
Turn into function table. The (future) DisplayList (DL) jit can then call the functions directly,
getting rid of dynamic dispatch. Unfortunately, few games use DLs properly - most\
just stuff geometry in them and don't put state changes there. */
// ----------------------------------------------------------------------------------------------------------
void BPWritten(const Bypass& bp)
{
// --------------------------------------------------------------------------------------------------------
// First the pipeline is flushed then update the bpmem with the new value.
// Some of the BP cases have to call certain functions while others just update the bpmem.
// some bp cases check the changes variable, because they might not have to be updated all the time
// NOTE: it seems not all bp cases like checking changes, so calling if (bp.changes == 0 ? false : true)
// had to be ditched and the games seem to work fine with out it.
// --------------------------------------------------------------------------------------------------------
// Debugging only, this lets you skip a bp update
//static int times = 0;
//static bool enable = false;
//switch (bp.address)
//{
//case BPMEM_CONSTANTALPHA:
// {
// if (times-- == 0 && enable)
// return;
// else
// break;
// }
//default: break;
//}
FlushPipeline();
((u32*)&bpmem)[bp.address] = bp.newvalue;
switch (bp.address)
{
case BPMEM_GENMODE: // Set the Generation Mode
{
PRIM_LOG("genmode: texgen=%d, col=%d, ms_en=%d, tev=%d, culmode=%d, ind=%d, zfeeze=%d",
bpmem.genMode.numtexgens, bpmem.genMode.numcolchans,
bpmem.genMode.ms_en, bpmem.genMode.numtevstages+1, bpmem.genMode.cullmode,
bpmem.genMode.numindstages, bpmem.genMode.zfreeze);
SetGenerationMode(bp);
break;
}
case BPMEM_IND_MTXA: // Index Matrix Changed
case BPMEM_IND_MTXB:
case BPMEM_IND_MTXC:
case BPMEM_IND_MTXA+3:
case BPMEM_IND_MTXB+3:
case BPMEM_IND_MTXC+3:
case BPMEM_IND_MTXA+6:
case BPMEM_IND_MTXB+6:
case BPMEM_IND_MTXC+6:
PixelShaderManager::SetIndMatrixChanged((bp.address - BPMEM_IND_MTXA) / 3);
break;
case BPMEM_RAS1_SS0: // Index Texture Coordinate Scale 0
PixelShaderManager::SetIndTexScaleChanged(0x03);
case BPMEM_RAS1_SS1: // Index Texture Coordinate Scale 1
PixelShaderManager::SetIndTexScaleChanged(0x0c);
break;
case BPMEM_SCISSORTL: // Scissor Rectable Top, Left
case BPMEM_SCISSORBR: // Scissor Rectable Bottom, Right
case BPMEM_SCISSOROFFSET: // Scissor Offset
SetScissor(bp);
break;
case BPMEM_LINEPTWIDTH: // Line Width
SetLineWidth(bp);
break;
case BPMEM_ZMODE: // Depth Control
PRIM_LOG("zmode: test=%d, func=%d, upd=%d", bpmem.zmode.testenable, bpmem.zmode.func,
bpmem.zmode.updateenable);
SetDepthMode(bp);
break;
case BPMEM_BLENDMODE: // Blending Control
{
if (bp.changes & 0xFFFF)
{
PRIM_LOG("blendmode: en=%d, open=%d, colupd=%d, alphaupd=%d, dst=%d, src=%d, sub=%d, mode=%d",
bpmem.blendmode.blendenable, bpmem.blendmode.logicopenable, bpmem.blendmode.colorupdate, bpmem.blendmode.alphaupdate,
bpmem.blendmode.dstfactor, bpmem.blendmode.srcfactor, bpmem.blendmode.subtract, bpmem.blendmode.logicmode);
// Set LogicOp Blending Mode
if (bp.changes & 2)
{
SETSTAT(stats.logicOpMode, bpmem.blendmode.logicopenable != 0 ? bpmem.blendmode.logicmode : stats.logicOpMode);
SetLogicOpMode(bp);
}
// Set Dithering Mode
if (bp.changes & 4)
{
SETSTAT(stats.dither, bpmem.blendmode.dither);
SetDitherMode(bp);
}
// Set Blending Mode
if (bp.changes & 0xFE1)
{
SETSTAT(stats.srcFactor, bpmem.blendmode.srcfactor);
SETSTAT(stats.dstFactor, bpmem.blendmode.dstfactor);
SetBlendMode(bp);
}
// Set Color Mask
if (bp.changes & 0x18)
{
SETSTAT(stats.alphaUpdate, bpmem.blendmode.alphaupdate);
SETSTAT(stats.colorUpdate, bpmem.blendmode.colorupdate);
SetColorMask(bp);
}
}
break;
}
case BPMEM_CONSTANTALPHA: // Set Destination Alpha
{
PRIM_LOG("constalpha: alp=%d, en=%d", bpmem.dstalpha.alpha, bpmem.dstalpha.enable);
SETSTAT(stats.dstAlphaEnable, bpmem.dstalpha.enable);
SETSTAT_UINT(stats.dstAlpha, bpmem.dstalpha.alpha);
PixelShaderManager::SetDestAlpha(bpmem.dstalpha);
break;
}
case BPMEM_SETDRAWDONE: // This is called when the game is done drawing (eg: like in DX: Begin(); Draw(); End();)
switch (bp.newvalue & 0xFF)
{
case 0x02:
g_VideoInitialize.pSetPEFinish(); // may generate interrupt
DEBUG_LOG(VIDEO, "GXSetDrawDone SetPEFinish (value: 0x%02X)", (bp.newvalue & 0xFFFF));
break;
default:
WARN_LOG(VIDEO, "GXSetDrawDone ??? (value 0x%02X)", (bp.newvalue & 0xFFFF));
break;
}
break;
case BPMEM_PE_TOKEN_ID: // Pixel Engine Token ID
g_VideoInitialize.pSetPEToken(static_cast<u16>(bp.newvalue & 0xFFFF), FALSE);
DEBUG_LOG(VIDEO, "SetPEToken 0x%04x", (bp.newvalue & 0xFFFF));
break;
case BPMEM_PE_TOKEN_INT_ID: // Pixel Engine Interrupt Token ID
g_VideoInitialize.pSetPEToken(static_cast<u16>(bp.newvalue & 0xFFFF), TRUE);
DEBUG_LOG(VIDEO, "SetPEToken + INT 0x%04x", (bp.newvalue & 0xFFFF));
break;
// ------------------------
// EFB copy command. This copies a rectangle from the EFB to either RAM in a texture format or to XFB as YUYV.
// It can also optionally clear the EFB while copying from it. To emulate this, we of course copy first and clear afterwards.
case BPMEM_TRIGGER_EFB_COPY: // Copy EFB Region or Render to the XFB or Clear the screen.
{
DVSTARTSUBPROFILE("LoadBPReg:swap");
// The bottom right is within the rectangle
// The values in bpmem.copyTexSrcXY and bpmem.copyTexSrcWH are updated in case 0x49 and 0x4a in this function
TRectangle rc = {
(int)(bpmem.copyTexSrcXY.x),
(int)(bpmem.copyTexSrcXY.y),
(int)((bpmem.copyTexSrcXY.x + bpmem.copyTexSrcWH.x + 1)),
(int)((bpmem.copyTexSrcXY.y + bpmem.copyTexSrcWH.y + 1))
};
float MValueX = GetRendererTargetScaleX();
float MValueY = GetRendererTargetScaleY();
// Need another rc here to get it to scale.
// Here the bottom right is the out of the rectangle.
TRectangle multirc = {
(int)(bpmem.copyTexSrcXY.x * MValueX),
(int)(bpmem.copyTexSrcXY.y * MValueY),
(int)((bpmem.copyTexSrcXY.x * MValueX + (bpmem.copyTexSrcWH.x + 1) * MValueX)),
(int)((bpmem.copyTexSrcXY.y * MValueY + (bpmem.copyTexSrcWH.y + 1) * MValueY))
};
UPE_Copy PE_copy;
PE_copy.Hex = bpmem.triggerEFBCopy;
// Check if we are to copy from the EFB or draw to the XFB
if (PE_copy.copy_to_xfb == 0)
{
if (GetConfig(CONFIG_SHOWEFBREGIONS))
stats.efb_regions.push_back(rc);
CopyEFB(bp, rc, bpmem.copyTexDest << 5,
bpmem.zcontrol.pixel_format == PIXELFMT_Z24,
PE_copy.intensity_fmt > 0,
((PE_copy.target_pixel_format / 2) + ((PE_copy.target_pixel_format & 1) * 8)),
PE_copy.half_scale > 0);
}
else
{
// the number of lines copied is determined by the y scale * source efb height
const float yScale = bpmem.dispcopyyscale / 256.0f;
const float xfbLines = ((bpmem.copyTexSrcWH.y + 1.0f) * yScale);
RenderToXFB(bp, multirc, yScale, xfbLines,
Memory_GetPtr(bpmem.copyTexDest << 5),
bpmem.copyMipMapStrideChannels << 4,
(u32)ceil(xfbLines));
}
// Clear the picture after it's done and submitted, to prepare for the next picture
if (PE_copy.clear)
ClearScreen(bp, multirc);
RestoreRenderState(bp);
break;
}
case BPMEM_LOADTLUT0: // Load a Texture Look Up Table
case BPMEM_LOADTLUT1:
{
DVSTARTSUBPROFILE("LoadBPReg:GXLoadTlut");
u32 tlutTMemAddr = (bp.newvalue & 0x3FF) << 9;
u32 tlutXferCount = (bp.newvalue & 0x1FFC00) >> 5;
u8 *ptr = 0;
// TODO - figure out a cleaner way.
if (GetConfig(CONFIG_ISWII))
ptr = GetPointer(bpmem.tlutXferSrc << 5);
else
ptr = GetPointer((bpmem.tlutXferSrc & 0xFFFFF) << 5);
if (ptr)
memcpy_gc(texMem + tlutTMemAddr, ptr, tlutXferCount);
else
PanicAlert("Invalid palette pointer %08x %08x %08x", bpmem.tlutXferSrc, bpmem.tlutXferSrc << 5, (bpmem.tlutXferSrc & 0xFFFFF)<< 5);
// TODO(ector) : kill all textures that use this palette
// Not sure if it's a good idea, though. For now, we hash texture palettes
break;
}
case BPMEM_FOGRANGE: // Fog Settings Control
case BPMEM_FOGPARAM0:
case BPMEM_FOGBMAGNITUDE:
case BPMEM_FOGBEXPONENT:
case BPMEM_FOGPARAM3:
if(!GetConfig(CONFIG_DISABLEFOG))
PixelShaderManager::SetFogParamChanged();
break;
case BPMEM_FOGCOLOR: // Fog Color
PixelShaderManager::SetFogColorChanged();
break;
case BPMEM_ALPHACOMPARE: // Compare Alpha Values
PRIM_LOG("alphacmp: ref0=%d, ref1=%d, comp0=%d, comp1=%d, logic=%d", bpmem.alphaFunc.ref0,
bpmem.alphaFunc.ref1, bpmem.alphaFunc.comp0, bpmem.alphaFunc.comp1, bpmem.alphaFunc.logic);
PixelShaderManager::SetAlpha(bpmem.alphaFunc);
break;
case BPMEM_BIAS: // BIAS
PRIM_LOG("ztex bias=0x%x", bpmem.ztex1.bias);
PixelShaderManager::SetZTextureBias(bpmem.ztex1.bias);
break;
case BPMEM_ZTEX2: // Z Texture type
{
if (bp.changes & 3)
PixelShaderManager::SetZTextureTypeChanged();
#if defined(_DEBUG) || defined(DEBUGFAST)
const char* pzop[] = {"DISABLE", "ADD", "REPLACE", "?"};
const char* pztype[] = {"Z8", "Z16", "Z24", "?"};
PRIM_LOG("ztex op=%s, type=%s", pzop[bpmem.ztex2.op], pztype[bpmem.ztex2.type]);
#endif
break;
}
case BPMEM_DISPLAYCOPYFILER: // Display Filtering Control, ignore this
case BPMEM_DISPLAYCOPYFILER+1:
case BPMEM_DISPLAYCOPYFILER+2:
case BPMEM_DISPLAYCOPYFILER+3:
case BPMEM_COPYFILTER0:
case BPMEM_COPYFILTER1:
break;
case BPMEM_FIELDMASK: // Interlacing Control
case BPMEM_FIELDMODE:
SetInterlacingMode(bp);
break;
// ---------------------------------------------------
// Debugging/Profiling info, we don't care about them
// ---------------------------------------------------
case BPMEM_CLOCK0: // Some Clock
case BPMEM_CLOCK1: // Some Clock
case BPMEM_SU_COUNTER: // Pixel or Poly Count
case BPMEM_RAS_COUNTER: // Sound Count of something in the Texture Units
case BPMEM_SETGPMETRIC: // Set the Graphic Processor Metric
break;
// ----------------
// EFB Copy config
// ----------------
case BPMEM_EFB_TL: // EFB Source Rect. Top, Left
case BPMEM_EFB_BR: // EFB Source Rect. Bottom, Right (w, h - 1)
case BPMEM_EFB_ADDR: // EFB Target Address
break;
// --------------
// Clear Config
// --------------
case BPMEM_CLEAR_AR: // Alpha and Red Components
case BPMEM_CLEAR_GB: // Green and Blue Components
case BPMEM_CLEAR_Z: // Z Components (24-bit Zbuffer)
break;
// -------------------------
// Culling Occulsion, we don't support this
// let's hope not many games use bboxes..
// TODO(ector): add something that watches bboxes
// -------------------------
case BPMEM_CLEARBBOX1:
case BPMEM_CLEARBBOX2:
break;
case BPMEM_ZCOMPARE: // Set the Z-Compare
case BPMEM_TEXINVALIDATE: // Used, if game has manual control the Texture Cache, which we don't allow
case BPMEM_MIPMAP_STRIDE: // MipMap Stride Channel
case BPMEM_COPYYSCALE: // Display Copy Y Scale
case BPMEM_IREF: /* 24 RID
21 BC3 - Ind. Tex Stage 3 NTexCoord
18 BI3 - Ind. Tex Stage 3 NTexMap
15 BC2 - Ind. Tex Stage 2 NTexCoord
12 BI2 - Ind. Tex Stage 2 NTexMap
9 BC1 - Ind. Tex Stage 1 NTexCoord
6 BI1 - Ind. Tex Stage 1 NTexMap
3 BC0 - Ind. Tex Stage 0 NTexCoord
0 BI0 - Ind. Tex Stage 0 NTexMap */
break;
case BPMEM_TEV_KSEL: // Texture Environment Swap Mode Table 0
case BPMEM_TEV_KSEL+1:// Texture Environment Swap Mode Table 1
case BPMEM_TEV_KSEL+2:// Texture Environment Swap Mode Table 2
case BPMEM_TEV_KSEL+3:// Texture Environment Swap Mode Table 3
case BPMEM_TEV_KSEL+4:// Texture Environment Swap Mode Table 4
case BPMEM_TEV_KSEL+5:// Texture Environment Swap Mode Table 5
case BPMEM_TEV_KSEL+6:// Texture Environment Swap Mode Table 6
case BPMEM_TEV_KSEL+7:// Texture Environment Swap Mode Table 7
break;
case BPMEM_BP_MASK: // This Register can be used to limit to which bits of BP registers is actually written to. the mask is
// only valid for the next BP command, and will reset itself.
case BPMEM_IND_IMASK: // Index Mask ?
break;
case BPMEM_UNKNOWN: // This is always set to 0xF at boot of any game, so this sounds like a useless reg
if (bp.newvalue != 0x0F)
PanicAlert("Unknown is not 0xF! val = 0x%08x", bp.newvalue);
break;
// ------------------------------------------------
// On Default, we try to look for other things
// before we give up and say its an unknown opcode
// ------------------------------------------------
default:
switch (bp.address & 0xFC) // Texture sampler filter
{
// -------------------------
// Texture Environment Order
// -------------------------
case BPMEM_TREF:
case BPMEM_TREF+1:
case BPMEM_TREF+2:
case BPMEM_TREF+3:
case BPMEM_TREF+4:
case BPMEM_TREF+5:
case BPMEM_TREF+6:
case BPMEM_TREF+7:
break;
// ----------------------
// Set a triangle's Wrap
// ----------------------
case BPMEM_SU_SSIZE:
case BPMEM_SU_TSIZE:
case BPMEM_SU_SSIZE+2:
case BPMEM_SU_TSIZE+2:
case BPMEM_SU_SSIZE+4:
case BPMEM_SU_TSIZE+4:
case BPMEM_SU_SSIZE+6:
case BPMEM_SU_TSIZE+6:
case BPMEM_SU_SSIZE+8:
case BPMEM_SU_TSIZE+8:
case BPMEM_SU_SSIZE+10:
case BPMEM_SU_TSIZE+10:
case BPMEM_SU_SSIZE+12:
case BPMEM_SU_TSIZE+12:
case BPMEM_SU_SSIZE+14:
case BPMEM_SU_TSIZE+14:
PixelShaderManager::SetTexCoordChanged((bp.address - BPMEM_SU_SSIZE) >> 1);
break;
// ------------------------
// BPMEM_TX_SETMODE0 - (Texture lookup and filtering mode) LOD/BIAS Clamp, MaxAnsio, LODBIAS, DiagLoad, Min Filter, Mag Filter, Wrap T, S
// BPMEM_TX_SETMODE1 - (LOD Stuff) - Max LOD, Min LOD
// ------------------------
case BPMEM_TX_SETMODE0: // (0x90 for linear)
case BPMEM_TX_SETMODE0+1:
case BPMEM_TX_SETMODE0+2:
case BPMEM_TX_SETMODE0+3:
case BPMEM_TX_SETMODE1:
case BPMEM_TX_SETMODE1+1:
case BPMEM_TX_SETMODE1+2:
case BPMEM_TX_SETMODE1+3:
case BPMEM_TX_SETMODE0_4:
case BPMEM_TX_SETMODE0_4+1:
case BPMEM_TX_SETMODE0_4+2:
case BPMEM_TX_SETMODE0_4+3:
case BPMEM_TX_SETMODE1_4:
case BPMEM_TX_SETMODE1_4+1:
case BPMEM_TX_SETMODE1_4+2:
case BPMEM_TX_SETMODE1_4+3:
SetSamplerState(bp);
break;
// --------------------------------------------
// BPMEM_TX_SETIMAGE0 - Texture width, height, format
// BPMEM_TX_SETIMAGE1 - even LOD address in TMEM - Image Type, Cache Height, Cache Width, TMEM Offset
// BPMEM_TX_SETIMAGE2 - odd LOD address in TMEM - Cache Height, Cache Width, TMEM Offset
// BPMEM_TX_SETIMAGE3 - Address of Texture in main memory
// --------------------------------------------
case BPMEM_TX_SETIMAGE0:
case BPMEM_TX_SETIMAGE0+1:
case BPMEM_TX_SETIMAGE0+2:
case BPMEM_TX_SETIMAGE0+3:
case BPMEM_TX_SETIMAGE0_4:
case BPMEM_TX_SETIMAGE0_4+1:
case BPMEM_TX_SETIMAGE0_4+2:
case BPMEM_TX_SETIMAGE0_4+3:
case BPMEM_TX_SETIMAGE1:
case BPMEM_TX_SETIMAGE1+1:
case BPMEM_TX_SETIMAGE1+2:
case BPMEM_TX_SETIMAGE1+3:
case BPMEM_TX_SETIMAGE1_4:
case BPMEM_TX_SETIMAGE1_4+1:
case BPMEM_TX_SETIMAGE1_4+2:
case BPMEM_TX_SETIMAGE1_4+3:
case BPMEM_TX_SETIMAGE2:
case BPMEM_TX_SETIMAGE2+1:
case BPMEM_TX_SETIMAGE2+2:
case BPMEM_TX_SETIMAGE2+3:
case BPMEM_TX_SETIMAGE2_4:
case BPMEM_TX_SETIMAGE2_4+1:
case BPMEM_TX_SETIMAGE2_4+2:
case BPMEM_TX_SETIMAGE2_4+3:
case BPMEM_TX_SETIMAGE3:
case BPMEM_TX_SETIMAGE3+1:
case BPMEM_TX_SETIMAGE3+2:
case BPMEM_TX_SETIMAGE3+3:
case BPMEM_TX_SETIMAGE3_4:
case BPMEM_TX_SETIMAGE3_4+1:
case BPMEM_TX_SETIMAGE3_4+2:
case BPMEM_TX_SETIMAGE3_4+3:
break;
// -------------------------------
// Set a TLUT
// BPMEM_TX_SETTLUT - Format, TMEM Offset (offset of TLUT from start of TMEM high bank > > 5)
// -------------------------------
case BPMEM_TX_SETTLUT:
case BPMEM_TX_SETTLUT+1:
case BPMEM_TX_SETTLUT+2:
case BPMEM_TX_SETTLUT+3:
case BPMEM_TX_SETLUT_4:
case BPMEM_TX_SETLUT_4+1:
case BPMEM_TX_SETLUT_4+2:
case BPMEM_TX_SETLUT_4+3:
break;
// ---------------------------------------------------
// Set the TEV Color
// ---------------------------------------------------
case BPMEM_TEV_REGISTER_L: // Reg 1
case BPMEM_TEV_REGISTER_H:
case BPMEM_TEV_REGISTER_L+2: // Reg 2
case BPMEM_TEV_REGISTER_H+2:
case BPMEM_TEV_REGISTER_L+4: // Reg 3
case BPMEM_TEV_REGISTER_H+4:
case BPMEM_TEV_REGISTER_L+6: // Reg 4
case BPMEM_TEV_REGISTER_H+6:
{
if (bp.address & 1)
{
// don't compare with changes!
int num = (bp.address >> 1 ) & 0x3;
PixelShaderManager::SetColorChanged(bpmem.tevregs[num].high.type, num);
}
break;
}
// ------------------------------------------------
// On Default, we try to look for other things
// before we give up and say its an unknown opcode
// again ...
// ------------------------------------------------
default:
switch (bp.address & 0xF0)
{
// --------------
// Indirect Tev
// --------------
case BPMEM_IND_CMD:
case BPMEM_IND_CMD+1:
case BPMEM_IND_CMD+2:
case BPMEM_IND_CMD+3:
case BPMEM_IND_CMD+4:
case BPMEM_IND_CMD+5:
case BPMEM_IND_CMD+6:
case BPMEM_IND_CMD+7:
case BPMEM_IND_CMD+8:
case BPMEM_IND_CMD+9:
case BPMEM_IND_CMD+10:
case BPMEM_IND_CMD+11:
case BPMEM_IND_CMD+12:
case BPMEM_IND_CMD+13:
case BPMEM_IND_CMD+14:
case BPMEM_IND_CMD+15:
break;
// --------------------------------------------------
// Set Color/Alpha of a Tev
// BPMEM_TEV_COLOR_ENV - Dest, Shift, Clamp, Sub, Bias, Sel A, Sel B, Sel C, Sel D
// BPMEM_TEV_ALPHA_ENV - Dest, Shift, Clamp, Sub, Bias, Sel A, Sel B, Sel C, Sel D, T Swap, R Swap
// --------------------------------------------------
case BPMEM_TEV_COLOR_ENV: // Texture Environment 1
case BPMEM_TEV_ALPHA_ENV:
case BPMEM_TEV_COLOR_ENV+2: // Texture Environment 2
case BPMEM_TEV_ALPHA_ENV+2:
case BPMEM_TEV_COLOR_ENV+4: // Texture Environment 3
case BPMEM_TEV_ALPHA_ENV+4:
case BPMEM_TEV_COLOR_ENV+8: // Texture Environment 4
case BPMEM_TEV_ALPHA_ENV+8:
case BPMEM_TEV_COLOR_ENV+10: // Texture Environment 5
case BPMEM_TEV_ALPHA_ENV+10:
case BPMEM_TEV_COLOR_ENV+12: // Texture Environment 6
case BPMEM_TEV_ALPHA_ENV+12:
case BPMEM_TEV_COLOR_ENV+14: // Texture Environment 7
case BPMEM_TEV_ALPHA_ENV+14:
case BPMEM_TEV_COLOR_ENV+16: // Texture Environment 8
case BPMEM_TEV_ALPHA_ENV+16:
case BPMEM_TEV_COLOR_ENV+18: // Texture Environment 9
case BPMEM_TEV_ALPHA_ENV+18:
case BPMEM_TEV_COLOR_ENV+20: // Texture Environment 10
case BPMEM_TEV_ALPHA_ENV+20:
case BPMEM_TEV_COLOR_ENV+22: // Texture Environment 11
case BPMEM_TEV_ALPHA_ENV+22:
case BPMEM_TEV_COLOR_ENV+24: // Texture Environment 12
case BPMEM_TEV_ALPHA_ENV+24:
case BPMEM_TEV_COLOR_ENV+26: // Texture Environment 13
case BPMEM_TEV_ALPHA_ENV+26:
case BPMEM_TEV_COLOR_ENV+28: // Texture Environment 14
case BPMEM_TEV_ALPHA_ENV+28:
case BPMEM_TEV_COLOR_ENV+30: // Texture Environment 15
case BPMEM_TEV_ALPHA_ENV+30:
case BPMEM_TEV_COLOR_ENV+32: // Texture Environment 16
case BPMEM_TEV_ALPHA_ENV+32:
break;
}
}
}
}