/* ZZ Open GL graphics plugin * Copyright (c)2009-2010 zeydlitz@gmail.com, arcum42@gmail.com * Based on Zerofrog's ZeroGS KOSMOS (c)2005-2008 * * 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; 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include "GS.h" #include "Mem.h" #include "Regs.h" #include "PS2Etypes.h" #include "targets.h" #include "ZZoglVB.h" #include "ZZoglDrawing.h" #ifdef USE_OLD_REGS #ifdef _MSC_VER #pragma warning(disable:4244) #endif GIFRegHandler g_GIFPackedRegHandlers[16]; GIFRegHandler g_GIFRegHandlers[256]; GIFRegHandler g_GIFTempRegHandlers[16] = {0}; // values for keeping track of changes u32 s_uTex1Data[2][2] = {{0, }}; u32 s_uClampData[2] = {0, }; //u32 results[65535] = {0, }; void __gifCall GIFPackedRegHandlerNull(const u32* data) { FUNCLOG ZZLog::Debug_Log("Unexpected packed reg handler %8.8lx_%8.8lx %x.", data[0], data[1], data[2]); } // All these just call their non-packed equivalent. void __gifCall GIFPackedRegHandlerPRIM(const u32* data) { GIFRegHandlerPRIM(data); } template void __gifCall GIFPackedRegHandlerTEX0(const u32* data) { GIFRegHandlerTEX0(data); } template void __gifCall GIFPackedRegHandlerCLAMP(const u32* data) { GIFRegHandlerCLAMP(data); } void __gifCall GIFPackedRegHandlerXYZF3(const u32* data) { GIFRegHandlerXYZF3(data); } void __gifCall GIFPackedRegHandlerXYZ3(const u32* data) { GIFRegHandlerXYZ3(data); } void __gifCall GIFPackedRegHandlerRGBA(const u32* data) { FUNCLOG gs.rgba = (data[0] & 0xff) | ((data[1] & 0xff) << 8) | ((data[2] & 0xff) << 16) | ((data[3] & 0xff) << 24); gs.vertexregs.rgba = gs.rgba; gs.vertexregs.q = gs.q; } void __gifCall GIFPackedRegHandlerSTQ(const u32* data) { FUNCLOG // Despite this code generating a warning, it's correct. float -> float reduction. S and Y are missed mantissas. *(u32*)&gs.vertexregs.s = data[0] & 0xffffff00; *(u32*)&gs.vertexregs.t = data[1] & 0xffffff00; *(u32*)&gs.q = data[2]; } void __gifCall GIFPackedRegHandlerUV(const u32* data) { FUNCLOG gs.vertexregs.u = data[0] & 0x3fff; gs.vertexregs.v = data[1] & 0x3fff; } void __gifCall GIFPackedRegHandlerXYZF2(const u32* data) { FUNCLOG GIFPackedXYZF2* r = (GIFPackedXYZF2*)(data); gs.add_vertex(r->X, r->Y,r->Z, r->F); ZZKick->KickVertex(((data[3]>>15) & 0x1)); } void __gifCall GIFPackedRegHandlerXYZ2(const u32* data) { FUNCLOG GIFPackedXYZ2* r = (GIFPackedXYZ2*)(data); gs.add_vertex(r->X, r->Y,r->Z); ZZKick->KickVertex(((data[3]>>15) & 0x1)); } void __gifCall GIFPackedRegHandlerFOG(const u32* data) { FUNCLOG gs.vertexregs.f = (data[3] & 0xff0) >> 4; } void __gifCall GIFPackedRegHandlerA_D(const u32* data) { FUNCLOG if ((data[2] & 0xff) < 100) g_GIFRegHandlers[data[2] & 0xff](data); else GIFRegHandlerNull(data); } void __gifCall GIFPackedRegHandlerNOP(const u32* data) { FUNCLOG } void __gifCall GIFRegHandlerNull(const u32* data) { FUNCLOG #ifdef _DEBUG if ((((uptr)&data[2])&0xffff) == 0) return; // 0x7f happens on a lot of games if (data[2] != 0x7f && (data[0] || data[1])) { ZZLog::Debug_Log("Unexpected reg handler %x %x %x.", data[0], data[1], data[2]); } #endif } void __gifCall GIFRegHandlerPRIM(const u32 *data) { FUNCLOG //if (data[0] & ~0x3ff) //{ //ZZLog::Warn_Log("Warning: unknown bits in prim %8.8lx_%8.8lx", data[1], data[0]); //} gs.primC = 0; u16 prim_type = (data[0]) & 0x7; prim->prim = prim_type; gs._prim[0].prim = prim_type; gs._prim[1].prim = prim_type; gs._prim[1]._val = (data[0] >> 3) & 0xff; gs.new_tri_fan = !(prim_type ^ PRIM_TRIANGLE_FAN); ZZKick->DirtyValidPrevPrim(); Prim(); } void __gifCall GIFRegHandlerRGBAQ(const u32* data) { FUNCLOG gs.rgba = data[0]; gs.vertexregs.rgba = data[0]; *(u32*)&gs.vertexregs.q = data[1]; } void __gifCall GIFRegHandlerST(const u32* data) { FUNCLOG *(u32*)&gs.vertexregs.s = data[0] & 0xffffff00; *(u32*)&gs.vertexregs.t = data[1] & 0xffffff00; //*(u32*)&gs.q = data[2]; } void __gifCall GIFRegHandlerUV(const u32* data) { FUNCLOG gs.vertexregs.u = (data[0]) & 0x3fff; gs.vertexregs.v = (data[0] >> 16) & 0x3fff; } void __gifCall GIFRegHandlerXYZF2(const u32* data) { FUNCLOG GIFRegXYZF* r = (GIFRegXYZF*)(data); gs.add_vertex(r->X, r->Y,r->Z, r->F); ZZKick->KickVertex(false); } void __gifCall GIFRegHandlerXYZ2(const u32* data) { FUNCLOG GIFRegXYZ* r = (GIFRegXYZ*)(data); gs.add_vertex(r->X, r->Y,r->Z); ZZKick->KickVertex(false); } template void __gifCall GIFRegHandlerTEX0(const u32* data) { FUNCLOG if (!NoHighlights(ctxt)) return; u32 psm = ZZOglGet_psm_TexBitsFix(data[0]); if (m_Blocks[psm].bpp == 0) { // kh and others return; } vb[ctxt].uNextTex0Data[0] = data[0]; vb[ctxt].uNextTex0Data[1] = data[1]; vb[ctxt].bNeedTexCheck = 1; // don't update unless necessary if (PSMT_ISCLUT(psm)) { if (CheckChangeInClut(data[1], psm)) { // loading clut, so flush whole texture vb[ctxt].FlushTexData(); } // check if csa is the same!! (ffx bisaid island, grass) else if ((data[1] & CPSM_CSA_BITMASK) != (vb[ctxt].uCurTex0Data[1] & CPSM_CSA_BITMASK)) { Flush(ctxt); // flush any previous entries } } } template void __gifCall GIFRegHandlerCLAMP(const u32* data) { FUNCLOG if (!NoHighlights(ctxt)) return; clampInfo& clamp = vb[ctxt].clamp; if ((s_uClampData[ctxt] != data[0]) || (((clamp.minv >> 8) | (clamp.maxv << 2)) != (data[1]&0x0fff))) { Flush(ctxt); s_uClampData[ctxt] = data[0]; clamp.wms = (data[0]) & 0x3; clamp.wmt = (data[0] >> 2) & 0x3; clamp.minu = (data[0] >> 4) & 0x3ff; clamp.maxu = (data[0] >> 14) & 0x3ff; clamp.minv = ((data[0] >> 24) & 0xff) | ((data[1] & 0x3) << 8); clamp.maxv = (data[1] >> 2) & 0x3ff; vb[ctxt].bTexConstsSync = false; } } void __gifCall GIFRegHandlerFOG(const u32* data) { FUNCLOG //gs.gsvertex[gs.primIndex].f = (data[1] >> 24); // shift to upper bits gs.vertexregs.f = data[1] >> 24; } void __gifCall GIFRegHandlerXYZF3(const u32* data) { FUNCLOG GIFRegXYZF* r = (GIFRegXYZF*)(data); gs.add_vertex(r->X, r->Y,r->Z, r->F); ZZKick->KickVertex(true); } void __gifCall GIFRegHandlerXYZ3(const u32* data) { FUNCLOG GIFRegXYZ* r = (GIFRegXYZ*)(data); gs.add_vertex(r->X, r->Y,r->Z); ZZKick->KickVertex(true); } void __gifCall GIFRegHandlerNOP(const u32* data) { FUNCLOG } template void __gifCall GIFRegHandlerTEX1(const u32* data) { FUNCLOG if (!NoHighlights(ctxt)) return; tex1Info& tex1 = vb[ctxt].tex1; if (conf.bilinear == 1 && (tex1.mmag != ((data[0] >> 5) & 0x1) || tex1.mmin != ((data[0] >> 6) & 0x7))) { Flush(ctxt); vb[ctxt].bVarsTexSync = false; } tex1.lcm = (data[0]) & 0x1; tex1.mxl = (data[0] >> 2) & 0x7; tex1.mmag = (data[0] >> 5) & 0x1; tex1.mmin = (data[0] >> 6) & 0x7; tex1.mtba = (data[0] >> 9) & 0x1; tex1.l = (data[0] >> 19) & 0x3; tex1.k = (data[1] >> 4) & 0xff; } template void __gifCall GIFRegHandlerTEX2(const u32* data) { FUNCLOG tex0Info& tex0 = vb[ctxt].tex0; vb[ctxt].FlushTexData(); u32 psm = ZZOglGet_psm_TexBitsFix(data[0]); u32* s_uTex0Data = vb[ctxt].uCurTex0Data; // don't update unless necessary // if( ZZOglGet_psm_TexBitsFix(*s_uTex0Data) == ZZOglGet_psm_TexBitsFix(data[0]) ) { // psm is the same if (ZZOglAllExceptClutIsSame(s_uTex0Data, data)) { if (!PSMT_ISCLUT(psm)) return; // have to write the CLUT again if changed if (ZZOglClutMinusCLDunchanged(s_uTex0Data, data)) { tex0.cld = ZZOglGet_cld_TexBits(data[1]); if (tex0.cld != 0) { texClutWrite(ctxt); // invalidate to make sure target didn't change! vb[ctxt].bVarsTexSync = false; } return; } } Flush(ctxt); vb[ctxt].bVarsTexSync = false; vb[ctxt].bTexConstsSync = false; s_uTex0Data[0] = (s_uTex0Data[0] & ~0x03f00000) | (psm << 20); s_uTex0Data[1] = (s_uTex0Data[1] & 0x1f) | (data[1] & ~0x1f); tex0.psm = ZZOglGet_psm_TexBitsFix(data[0]); if (PSMT_ISCLUT(tex0.psm)) CluttingForFlushedTex(&tex0, data[1], ctxt); } template void __gifCall GIFRegHandlerXYOFFSET(const u32* data) { FUNCLOG vb[ctxt].offset.x = (data[0]) & 0xffff; vb[ctxt].offset.y = (data[1]) & 0xffff; // if( !conf.interlace ) { // vb[1].offset.x &= ~15; // vb[1].offset.y &= ~15; // } } void __gifCall GIFRegHandlerPRMODECONT(const u32* data) { FUNCLOG gs.prac = data[0] & 0x1; prim = &gs._prim[gs.prac]; Prim(); } void __gifCall GIFRegHandlerPRMODE(const u32* data) { FUNCLOG gs._prim[0]._val = (data[0] >> 3) & 0xff; if (gs.prac == 0) Prim(); } void __gifCall GIFRegHandlerTEXCLUT(const u32* data) { FUNCLOG vb[0].FlushTexData(); vb[1].FlushTexData(); gs.clut.cbw = ((data[0]) & 0x3f) * 64; gs.clut.cou = ((data[0] >> 6) & 0x3f) * 16; gs.clut.cov = (data[0] >> 12) & 0x3ff; } void __gifCall GIFRegHandlerSCANMSK(const u32* data) { FUNCLOG // FlushBoth(); // ResolveC(&vb[0]); // ResolveZ(&vb[0]); gs.smask = data[0] & 0x3; } template void __gifCall GIFRegHandlerMIPTBP1(const u32* data) { FUNCLOG miptbpInfo& miptbp0 = vb[ctxt].miptbp0; miptbp0.tbp[0] = (data[0]) & 0x3fff; miptbp0.tbw[0] = (data[0] >> 14) & 0x3f; miptbp0.tbp[1] = ((data[0] >> 20) & 0xfff) | ((data[1] & 0x3) << 12); miptbp0.tbw[1] = (data[1] >> 2) & 0x3f; miptbp0.tbp[2] = (data[1] >> 8) & 0x3fff; miptbp0.tbw[2] = (data[1] >> 22) & 0x3f; } template void __gifCall GIFRegHandlerMIPTBP2(const u32* data) { FUNCLOG miptbpInfo& miptbp1 = vb[ctxt].miptbp1; miptbp1.tbp[0] = (data[0]) & 0x3fff; miptbp1.tbw[0] = (data[0] >> 14) & 0x3f; miptbp1.tbp[1] = ((data[0] >> 20) & 0xfff) | ((data[1] & 0x3) << 12); miptbp1.tbw[1] = (data[1] >> 2) & 0x3f; miptbp1.tbp[2] = (data[1] >> 8) & 0x3fff; miptbp1.tbw[2] = (data[1] >> 22) & 0x3f; } void __gifCall GIFRegHandlerTEXA(const u32* data) { FUNCLOG texaInfo newinfo; newinfo.aem = (data[0] >> 15) & 0x1; newinfo.ta[0] = data[0] & 0xff; newinfo.ta[1] = data[1] & 0xff; if (*(u32*)&newinfo != *(u32*)&gs.texa) { FlushBoth(); *(u32*)&gs.texa = *(u32*) & newinfo; gs.texa.fta[0] = newinfo.ta[0] / 255.0f; gs.texa.fta[1] = newinfo.ta[1] / 255.0f; vb[0].bTexConstsSync = false; vb[1].bTexConstsSync = false; } } void __gifCall GIFRegHandlerFOGCOL(const u32* data) { FUNCLOG SetFogColor(data[0]&0xffffff); } void __gifCall GIFRegHandlerTEXFLUSH(const u32* data) { FUNCLOG SetTexFlush(); } template void __gifCall GIFRegHandlerSCISSOR(const u32* data) { FUNCLOG Rect2& scissor = vb[ctxt].scissor; Rect2 newscissor; newscissor.x0 = ((data[0]) & 0x7ff) << 3; newscissor.x1 = ((data[0] >> 16) & 0x7ff) << 3; newscissor.y0 = ((data[1]) & 0x7ff) << 3; newscissor.y1 = ((data[1] >> 16) & 0x7ff) << 3; if (newscissor.x1 != scissor.x1 || newscissor.y1 != scissor.y1 || newscissor.x0 != scissor.x0 || newscissor.y0 != scissor.y0) { Flush(ctxt); scissor = newscissor; // flush everything vb[ctxt].bNeedFrameCheck = 1; } } template void __gifCall GIFRegHandlerALPHA(const u32* data) { FUNCLOG alphaInfo newalpha; newalpha.abcd = *(u8*)data; newalpha.fix = *(u8*)(data + 1); if (*(u16*)&newalpha != *(u16*)&vb[ctxt].alpha) { Flush(ctxt); if (newalpha.a == 3) newalpha.a = 0; if (newalpha.b == 3) newalpha.b = 0; if (newalpha.c == 3) newalpha.c = 0; if (newalpha.d == 3) newalpha.d = 0; *(u16*)&vb[ctxt].alpha = *(u16*) & newalpha; } } void __gifCall GIFRegHandlerDIMX(const u32* data) { FUNCLOG } void __gifCall GIFRegHandlerDTHE(const u32* data) { FUNCLOG gs.dthe = data[0] & 0x1; } void __gifCall GIFRegHandlerCOLCLAMP(const u32* data) { FUNCLOG gs.colclamp = data[0] & 0x1; } template void __gifCall GIFRegHandlerTEST(const u32* data) { FUNCLOG pixTest* test = &vb[ctxt].test; if ((*(u32*)test & 0x0007ffff) == (data[0] & 0x0007ffff)) return; Flush(ctxt); *(u32*)test = data[0]; // test.ate = (data[0] ) & 0x1; // test.atst = (data[0] >> 1) & 0x7; // test.aref = (data[0] >> 4) & 0xff; // test.afail = (data[0] >> 12) & 0x3; // test.date = (data[0] >> 14) & 0x1; // test.datm = (data[0] >> 15) & 0x1; // test.zte = (data[0] >> 16) & 0x1; // test.ztst = (data[0] >> 17) & 0x3; } void __gifCall GIFRegHandlerPABE(const u32* data) { FUNCLOG //SetAlphaChanged(0, GPUREG_PABE); //SetAlphaChanged(1, GPUREG_PABE); FlushBoth(); gs.pabe = *data & 0x1; } template void __gifCall GIFRegHandlerFBA(const u32* data) { FUNCLOG FlushBoth(); vb[ctxt].fba.fba = *data & 0x1; } template void __gifCall GIFRegHandlerFRAME(const u32* data) { FUNCLOG frameInfo& gsfb = vb[ctxt].gsfb; if ((gsfb.fbp == ZZOglGet_fbp_FrameBitsMult(data[0])) && (gsfb.fbw == ZZOglGet_fbw_FrameBitsMult(data[0])) && (gsfb.psm == ZZOglGet_psm_FrameBits(data[0])) && (gsfb.fbm == ZZOglGet_fbm_FrameBits(data[0]))) { return; } FlushBoth(); gsfb.fbp = ZZOglGet_fbp_FrameBitsMult(data[0]); gsfb.fbw = ZZOglGet_fbw_FrameBitsMult(data[0]); gsfb.psm = ZZOglGet_psm_FrameBits(data[0]); gsfb.fbm = ZZOglGet_fbm_FrameBitsFix(data[0], data[1]); gsfb.fbh = ZZOglGet_fbh_FrameBitsCalc(data[0]); // gsfb.fbhCalc = gsfb.fbh; vb[ctxt].bNeedFrameCheck = 1; } template void __gifCall GIFRegHandlerZBUF(const u32* data) { FUNCLOG zbufInfo& zbuf = vb[ctxt].zbuf; int psm = (0x30 | ((data[0] >> 24) & 0xf)); if (zbuf.zbp == (data[0] & 0x1ff) * 32 && zbuf.psm == psm && zbuf.zmsk == (data[1] & 0x1)) { return; } // error detection if (m_Blocks[psm].bpp == 0) return; FlushBoth(); zbuf.zbp = (data[0] & 0x1ff) * 32; zbuf.psm = 0x30 | ((data[0] >> 24) & 0xf); zbuf.zmsk = data[1] & 0x1; vb[ctxt].bNeedZCheck = 1; vb[ctxt].zprimmask = 0xffffffff; if (zbuf.psm > 0x31) vb[ctxt].zprimmask = 0xffff; } void __gifCall GIFRegHandlerBITBLTBUF(const u32* data) { FUNCLOG gs.srcbufnew.bp = ((data[0]) & 0x3fff); // * 64; gs.srcbufnew.bw = ((data[0] >> 16) & 0x3f) * 64; gs.srcbufnew.psm = (data[0] >> 24) & 0x3f; gs.dstbufnew.bp = ((data[1]) & 0x3fff); // * 64; gs.dstbufnew.bw = ((data[1] >> 16) & 0x3f) * 64; gs.dstbufnew.psm = (data[1] >> 24) & 0x3f; if (gs.dstbufnew.bw == 0) gs.dstbufnew.bw = 64; } void __gifCall GIFRegHandlerTRXPOS(const u32* data) { FUNCLOG gs.trxposnew.sx = (data[0]) & 0x7ff; gs.trxposnew.sy = (data[0] >> 16) & 0x7ff; gs.trxposnew.dx = (data[1]) & 0x7ff; gs.trxposnew.dy = (data[1] >> 16) & 0x7ff; gs.trxposnew.dir = (data[1] >> 27) & 0x3; } void __gifCall GIFRegHandlerTRXREG(const u32* data) { FUNCLOG gs.imageWtemp = data[0] & 0xfff; gs.imageHtemp = data[1] & 0xfff; } void __gifCall GIFRegHandlerTRXDIR(const u32* data) { FUNCLOG // terminate any previous transfers switch (gs.imageTransfer) { case 0: // host->loc TerminateHostLocal(); break; case 1: // loc->host TerminateLocalHost(); break; } gs.srcbuf = gs.srcbufnew; gs.dstbuf = gs.dstbufnew; gs.trxpos = gs.trxposnew; gs.imageTransfer = data[0] & 0x3; gs.imageWnew = gs.imageWtemp; gs.imageHnew = gs.imageHtemp; if (gs.imageWnew > 0 && gs.imageHnew > 0) { switch (gs.imageTransfer) { case 0: // host->loc InitTransferHostLocal(); break; case 1: // loc->host InitTransferLocalHost(); break; case 2: TransferLocalLocal(); break; case 3: gs.imageTransfer = -1; break; default: assert(0); } } else { #if defined(ZEROGS_DEVBUILD) ZZLog::Warn_Log("Dummy transfer."); #endif gs.imageTransfer = -1; } } void __gifCall GIFRegHandlerHWREG(const u32* data) { FUNCLOG if (gs.imageTransfer == 0) { TransferHostLocal(data, 2); } else { #if defined(ZEROGS_DEVBUILD) ZZLog::Error_Log("ZeroGS: HWREG!? %8.8x_%8.8x", data[0], data[1]); //assert(0); #endif } } extern int g_GSMultiThreaded; void __gifCall GIFRegHandlerSIGNAL(const u32* data) { FUNCLOG if (!g_GSMultiThreaded) { SIGLBLID->SIGID = (SIGLBLID->SIGID & ~data[1]) | (data[0] & data[1]); // if (gs.CSRw & 0x1) CSR->SIGNAL = 1; // if (!IMR->SIGMSK && GSirq) // GSirq(); if (gs.CSRw & 0x1) { CSR->SIGNAL = 1; //gs.CSRw &= ~1; } if (!IMR->SIGMSK && GSirq) GSirq(); } } void __gifCall GIFRegHandlerFINISH(const u32* data) { FUNCLOG if (!g_GSMultiThreaded) { if (gs.CSRw & 0x2) CSR->FINISH = 1; if (!IMR->FINISHMSK && GSirq) GSirq(); // if( gs.CSRw & 2 ) { // //gs.CSRw &= ~2; // //CSR->FINISH = 0; // // // } // CSR->FINISH = 1; // // if( !IMR->FINISHMSK && GSirq ) // GSirq(); } } void __gifCall GIFRegHandlerLABEL(const u32* data) { FUNCLOG if (!g_GSMultiThreaded) { SIGLBLID->LBLID = (SIGLBLID->LBLID & ~data[1]) | (data[0] & data[1]); } } void SetMultithreaded() { // Some older versions of PCSX2 didn't properly set the irq callback to NULL // in multithreaded mode (possibly because ZeroGS itself would assert in such // cases), and didn't bind them to a dummy callback either. PCSX2 handles all // IRQs internally when multithreaded anyway -- so let's ignore them here: if (g_GSMultiThreaded) { g_GIFRegHandlers[GIF_A_D_REG_SIGNAL] = &GIFRegHandlerNull; g_GIFRegHandlers[GIF_A_D_REG_FINISH] = &GIFRegHandlerNull; g_GIFRegHandlers[GIF_A_D_REG_LABEL] = &GIFRegHandlerNull; } else { g_GIFRegHandlers[GIF_A_D_REG_SIGNAL] = &GIFRegHandlerSIGNAL; g_GIFRegHandlers[GIF_A_D_REG_FINISH] = &GIFRegHandlerFINISH; g_GIFRegHandlers[GIF_A_D_REG_LABEL] = &GIFRegHandlerLABEL; } } void ResetRegs() { for (int i = 0; i < 16; i++) { g_GIFPackedRegHandlers[i] = &GIFPackedRegHandlerNull; } g_GIFPackedRegHandlers[GIF_REG_PRIM] = &GIFPackedRegHandlerPRIM; g_GIFPackedRegHandlers[GIF_REG_RGBA] = &GIFPackedRegHandlerRGBA; g_GIFPackedRegHandlers[GIF_REG_STQ] = &GIFPackedRegHandlerSTQ; g_GIFPackedRegHandlers[GIF_REG_UV] = &GIFPackedRegHandlerUV; g_GIFPackedRegHandlers[GIF_REG_XYZF2] = &GIFPackedRegHandlerXYZF2; g_GIFPackedRegHandlers[GIF_REG_XYZ2] = &GIFPackedRegHandlerXYZ2; g_GIFPackedRegHandlers[GIF_REG_TEX0_1] = &GIFPackedRegHandlerTEX0<0>; g_GIFPackedRegHandlers[GIF_REG_TEX0_2] = &GIFPackedRegHandlerTEX0<1>; g_GIFPackedRegHandlers[GIF_REG_CLAMP_1] = &GIFPackedRegHandlerCLAMP<0>; g_GIFPackedRegHandlers[GIF_REG_CLAMP_2] = &GIFPackedRegHandlerCLAMP<1>; g_GIFPackedRegHandlers[GIF_REG_FOG] = &GIFPackedRegHandlerFOG; g_GIFPackedRegHandlers[GIF_REG_XYZF3] = &GIFPackedRegHandlerXYZF3; g_GIFPackedRegHandlers[GIF_REG_XYZ3] = &GIFPackedRegHandlerXYZ3; g_GIFPackedRegHandlers[GIF_REG_A_D] = &GIFPackedRegHandlerA_D; g_GIFPackedRegHandlers[GIF_REG_NOP] = &GIFPackedRegHandlerNOP; for (int i = 0; i < 256; i++) { g_GIFRegHandlers[i] = &GIFPackedRegHandlerNull; } g_GIFRegHandlers[GIF_A_D_REG_PRIM] = &GIFRegHandlerPRIM; g_GIFRegHandlers[GIF_A_D_REG_RGBAQ] = &GIFRegHandlerRGBAQ; g_GIFRegHandlers[GIF_A_D_REG_ST] = &GIFRegHandlerST; g_GIFRegHandlers[GIF_A_D_REG_UV] = &GIFRegHandlerUV; g_GIFRegHandlers[GIF_A_D_REG_XYZF2] = &GIFRegHandlerXYZF2; g_GIFRegHandlers[GIF_A_D_REG_XYZ2] = &GIFRegHandlerXYZ2; g_GIFRegHandlers[GIF_A_D_REG_TEX0_1] = &GIFRegHandlerTEX0<0>; g_GIFRegHandlers[GIF_A_D_REG_TEX0_2] = &GIFRegHandlerTEX0<1>; g_GIFRegHandlers[GIF_A_D_REG_CLAMP_1] = &GIFRegHandlerCLAMP<0>; g_GIFRegHandlers[GIF_A_D_REG_CLAMP_2] = &GIFRegHandlerCLAMP<1>; g_GIFRegHandlers[GIF_A_D_REG_FOG] = &GIFRegHandlerFOG; g_GIFRegHandlers[GIF_A_D_REG_XYZF3] = &GIFRegHandlerXYZF3; g_GIFRegHandlers[GIF_A_D_REG_XYZ3] = &GIFRegHandlerXYZ3; g_GIFRegHandlers[GIF_A_D_REG_NOP] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_TEX1_1] = &GIFRegHandlerTEX1<0>; g_GIFRegHandlers[GIF_A_D_REG_TEX1_2] = &GIFRegHandlerTEX1<1>; g_GIFRegHandlers[GIF_A_D_REG_TEX2_1] = &GIFRegHandlerTEX2<0>; g_GIFRegHandlers[GIF_A_D_REG_TEX2_2] = &GIFRegHandlerTEX2<1>; g_GIFRegHandlers[GIF_A_D_REG_XYOFFSET_1] = &GIFRegHandlerXYOFFSET<0>; g_GIFRegHandlers[GIF_A_D_REG_XYOFFSET_2] = &GIFRegHandlerXYOFFSET<1>; g_GIFRegHandlers[GIF_A_D_REG_PRMODECONT] = &GIFRegHandlerPRMODECONT; g_GIFRegHandlers[GIF_A_D_REG_PRMODE] = &GIFRegHandlerPRMODE; g_GIFRegHandlers[GIF_A_D_REG_TEXCLUT] = &GIFRegHandlerTEXCLUT; g_GIFRegHandlers[GIF_A_D_REG_SCANMSK] = &GIFRegHandlerSCANMSK; g_GIFRegHandlers[GIF_A_D_REG_MIPTBP1_1] = &GIFRegHandlerMIPTBP1<0>; g_GIFRegHandlers[GIF_A_D_REG_MIPTBP1_2] = &GIFRegHandlerMIPTBP1<1>; g_GIFRegHandlers[GIF_A_D_REG_MIPTBP2_1] = &GIFRegHandlerMIPTBP2<0>; g_GIFRegHandlers[GIF_A_D_REG_MIPTBP2_2] = &GIFRegHandlerMIPTBP2<1>; g_GIFRegHandlers[GIF_A_D_REG_TEXA] = &GIFRegHandlerTEXA; g_GIFRegHandlers[GIF_A_D_REG_FOGCOL] = &GIFRegHandlerFOGCOL; g_GIFRegHandlers[GIF_A_D_REG_TEXFLUSH] = &GIFRegHandlerTEXFLUSH; g_GIFRegHandlers[GIF_A_D_REG_SCISSOR_1] = &GIFRegHandlerSCISSOR<0>; g_GIFRegHandlers[GIF_A_D_REG_SCISSOR_2] = &GIFRegHandlerSCISSOR<1>; g_GIFRegHandlers[GIF_A_D_REG_ALPHA_1] = &GIFRegHandlerALPHA<0>; g_GIFRegHandlers[GIF_A_D_REG_ALPHA_2] = &GIFRegHandlerALPHA<1>; g_GIFRegHandlers[GIF_A_D_REG_DIMX] = &GIFRegHandlerDIMX; g_GIFRegHandlers[GIF_A_D_REG_DTHE] = &GIFRegHandlerDTHE; g_GIFRegHandlers[GIF_A_D_REG_COLCLAMP] = &GIFRegHandlerCOLCLAMP; g_GIFRegHandlers[GIF_A_D_REG_TEST_1] = &GIFRegHandlerTEST<0>; g_GIFRegHandlers[GIF_A_D_REG_TEST_2] = &GIFRegHandlerTEST<1>; g_GIFRegHandlers[GIF_A_D_REG_PABE] = &GIFRegHandlerPABE; g_GIFRegHandlers[GIF_A_D_REG_FBA_1] = &GIFRegHandlerFBA<0>; g_GIFRegHandlers[GIF_A_D_REG_FBA_2] = &GIFRegHandlerFBA<1>; g_GIFRegHandlers[GIF_A_D_REG_FRAME_1] = &GIFRegHandlerFRAME<0>; g_GIFRegHandlers[GIF_A_D_REG_FRAME_2] = &GIFRegHandlerFRAME<1>; g_GIFRegHandlers[GIF_A_D_REG_ZBUF_1] = &GIFRegHandlerZBUF<0>; g_GIFRegHandlers[GIF_A_D_REG_ZBUF_2] = &GIFRegHandlerZBUF<1>; g_GIFRegHandlers[GIF_A_D_REG_BITBLTBUF] = &GIFRegHandlerBITBLTBUF; g_GIFRegHandlers[GIF_A_D_REG_TRXPOS] = &GIFRegHandlerTRXPOS; g_GIFRegHandlers[GIF_A_D_REG_TRXREG] = &GIFRegHandlerTRXREG; g_GIFRegHandlers[GIF_A_D_REG_TRXDIR] = &GIFRegHandlerTRXDIR; g_GIFRegHandlers[GIF_A_D_REG_HWREG] = &GIFRegHandlerHWREG; SetMultithreaded(); } void WriteTempRegs() { memcpy(g_GIFTempRegHandlers, g_GIFPackedRegHandlers, sizeof(g_GIFTempRegHandlers)); } void SetFrameSkip(bool skip) { if (skip) { g_GIFPackedRegHandlers[GIF_REG_PRIM] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_RGBA] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_STQ] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_UV] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_XYZF2] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_XYZ2] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_CLAMP_1] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_CLAMP_2] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_FOG] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_XYZF3] = &GIFPackedRegHandlerNOP; g_GIFPackedRegHandlers[GIF_REG_XYZ3] = &GIFPackedRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_PRIM] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_RGBAQ] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_ST] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_UV] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_XYZF2] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_XYZ2] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_XYZF3] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_XYZ3] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_PRMODECONT] = &GIFRegHandlerNOP; g_GIFRegHandlers[GIF_A_D_REG_PRMODE] = &GIFRegHandlerNOP; } else { g_GIFPackedRegHandlers[GIF_REG_PRIM] = &GIFPackedRegHandlerPRIM; g_GIFPackedRegHandlers[GIF_REG_RGBA] = &GIFPackedRegHandlerRGBA; g_GIFPackedRegHandlers[GIF_REG_STQ] = &GIFPackedRegHandlerSTQ; g_GIFPackedRegHandlers[GIF_REG_UV] = &GIFPackedRegHandlerUV; g_GIFPackedRegHandlers[GIF_REG_XYZF2] = &GIFPackedRegHandlerXYZF2; g_GIFPackedRegHandlers[GIF_REG_XYZ2] = &GIFPackedRegHandlerXYZ2; g_GIFPackedRegHandlers[GIF_REG_CLAMP_1] = &GIFPackedRegHandlerCLAMP<0>; g_GIFPackedRegHandlers[GIF_REG_CLAMP_2] = &GIFPackedRegHandlerCLAMP<1>; g_GIFPackedRegHandlers[GIF_REG_FOG] = &GIFPackedRegHandlerFOG; g_GIFPackedRegHandlers[GIF_REG_XYZF3] = &GIFPackedRegHandlerXYZF3; g_GIFPackedRegHandlers[GIF_REG_XYZ3] = &GIFPackedRegHandlerXYZ3; g_GIFRegHandlers[GIF_A_D_REG_PRIM] = &GIFRegHandlerPRIM; g_GIFRegHandlers[GIF_A_D_REG_RGBAQ] = &GIFRegHandlerRGBAQ; g_GIFRegHandlers[GIF_A_D_REG_ST] = &GIFRegHandlerST; g_GIFRegHandlers[GIF_A_D_REG_UV] = &GIFRegHandlerUV; g_GIFRegHandlers[GIF_A_D_REG_XYZF2] = &GIFRegHandlerXYZF2; g_GIFRegHandlers[GIF_A_D_REG_XYZ2] = &GIFRegHandlerXYZ2; g_GIFRegHandlers[GIF_A_D_REG_XYZF3] = &GIFRegHandlerXYZF3; g_GIFRegHandlers[GIF_A_D_REG_XYZ3] = &GIFRegHandlerXYZ3; g_GIFRegHandlers[GIF_A_D_REG_PRMODECONT] = &GIFRegHandlerPRMODECONT; g_GIFRegHandlers[GIF_A_D_REG_PRMODE] = &GIFRegHandlerPRMODE; } } #endif