/* * Copyright (C) 2007-2009 Gabest * http://www.gabest.org * * 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, 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 GNU Make; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA USA. * http://www.gnu.org/copyleft/gpl.html * */ #include "stdafx.h" #include "GSRendererHW.h" GSRendererHW::GSRendererHW(GSTextureCache* tc) : m_width(1280) , m_height(1024) , m_custom_width(1280) , m_custom_height(1024) , m_reset(false) , m_upscale_multiplier(1) , m_tc(tc) , m_channel_shuffle(false) , m_lod(GSVector2i(0,0)) { m_mipmap = theApp.GetConfigI("mipmap_hw"); m_upscale_multiplier = theApp.GetConfigI("upscale_multiplier"); m_large_framebuffer = theApp.GetConfigB("large_framebuffer"); if (theApp.GetConfigB("UserHacks")) { m_userhacks_align_sprite_X = theApp.GetConfigB("UserHacks_align_sprite_X"); m_userhacks_round_sprite_offset = theApp.GetConfigI("UserHacks_round_sprite_offset"); m_userhacks_disable_gs_mem_clear = theApp.GetConfigB("UserHacks_DisableGsMemClear"); } else { m_userhacks_align_sprite_X = false; m_userhacks_round_sprite_offset = 0; m_userhacks_disable_gs_mem_clear = false; } if (!m_upscale_multiplier) { //Custom Resolution m_custom_width = m_width = theApp.GetConfigI("resx"); m_custom_height = m_height = theApp.GetConfigI("resy"); } if (m_upscale_multiplier == 1) { // hacks are only needed for upscaling issues. m_userhacks_round_sprite_offset = 0; m_userhacks_align_sprite_X = 0; } m_dump_root = root_hw; } void GSRendererHW::SetScaling() { GSVector2i crtc_size(GetDisplayRect().width(), GetDisplayRect().height()); // Details of (potential) perf impact of a big framebuffer // 1/ extra memory // 2/ texture cache framebuffer rescaling/copy // 3/ upload of framebuffer (preload hack) // 4/ framebuffer clear (color/depth/stencil) // 5/ read back of the frambuffer // 6/ MSAA // // With the solution // 1/ Nothing to do.Except the texture cache bug (channel shuffle effect) // most of the market is 1GB of VRAM (and soon 2GB) // 2/ limit rescaling/copy to the valid data of the framebuffer // 3/ ??? no solution so far // 4a/ stencil can be limited to valid data. // 4b/ is it useful to clear color? depth? (in any case, it ought to be few operation) // 5/ limit the read to the valid data // 6/ not support on openGL // Framebuffer width is always a multiple of 64 so at certain cases it can't cover some weird width values. // 480P , 576P use width as 720 which is not referencable by FBW * 64. so it produces 704 ( the closest value multiple by 64). // In such cases, let's just use the CRTC width. int fb_width = max({ (int)m_context->FRAME.FBW * 64, crtc_size.x , 512 }); // GS doesn't have a specific register for the FrameBuffer height. so we get the height // from physical units of the display rectangle in case the game uses a heigher value of height. // // Gregory: the framebuffer must have enough room to draw // * at least 2 frames such as FMV (see OI_BlitFMV) // * high resolution game such as snowblind engine game // // Autodetection isn't a good idea because it will create flickering // If memory consumption is an issue, there are 2 possibilities // * 1/ Avoid to create hundreds of RT // * 2/ Use sparse texture (requires recent HW) // // Avoid to alternate between 640x1280 and 1280x1024 on snow blind engine game // int fb_height = (fb_width < 1024) ? 1280 : 1024; // // Until performance issue is properly fixed, let's keep an option to reduce the framebuffer size. int fb_height = m_large_framebuffer ? 1280 : (fb_width < 1024) ? max(512, crtc_size.y) : 1024; int upscaled_fb_w = fb_width * m_upscale_multiplier; int upscaled_fb_h = fb_height * m_upscale_multiplier; bool good_rt_size = m_width >= upscaled_fb_w && m_height >= upscaled_fb_h; bool initialized_register_state = (m_context->FRAME.FBW > 1) && (crtc_size.y > 1); if (!m_upscale_multiplier && initialized_register_state) { if (m_height == m_custom_height) { float ratio = ceil(static_cast(m_height) / crtc_size.y); float buffer_scale_offset = (m_large_framebuffer) ? ratio : 0.5f; ratio = round(ratio + buffer_scale_offset); m_tc->RemovePartial(); m_width = max(m_width, 1280); m_height = max(static_cast(crtc_size.y * ratio) , 1024); } } // No need to resize for native/custom resolutions as default size will be enough for native and we manually get RT Buffer size for custom. // don't resize until the display rectangle and register states are stabilized. if ( m_upscale_multiplier <= 1 || good_rt_size) return; m_tc->RemovePartial(); m_width = upscaled_fb_w; m_height = upscaled_fb_h; printf("Frame buffer size set to %dx%d (%dx%d)\n", fb_width, fb_height , m_width, m_height); } GSRendererHW::~GSRendererHW() { delete m_tc; } void GSRendererHW::SetGameCRC(uint32 crc, int options) { GSRenderer::SetGameCRC(crc, options); m_hacks.SetGameCRC(m_game); } bool GSRendererHW::CanUpscale() { if(m_hacks.m_cu && !(this->*m_hacks.m_cu)()) { return false; } return m_upscale_multiplier!=1 && m_regs->PMODE.EN != 0; // upscale ratio depends on the display size, with no output it may not be set correctly (ps2 logo to game transition) } int GSRendererHW::GetUpscaleMultiplier() { return m_upscale_multiplier; } GSVector2i GSRendererHW::GetCustomResolution() { return GSVector2i(m_custom_width, m_custom_height); } void GSRendererHW::Reset() { // TODO: GSreset can come from the main thread too => crash // m_tc->RemoveAll(); m_reset = true; GSRenderer::Reset(); } void GSRendererHW::VSync(int field) { //Check if the frame buffer width or display width has changed SetScaling(); if(m_reset) { m_tc->RemoveAll(); m_reset = false; } GSRenderer::VSync(field); m_tc->IncAge(); m_tc->PrintMemoryUsage(); m_dev->PrintMemoryUsage(); m_skip = 0; } void GSRendererHW::ResetDevice() { m_tc->RemoveAll(); GSRenderer::ResetDevice(); } GSTexture* GSRendererHW::GetOutput(int i, int& y_offset) { const GSRegDISPFB& DISPFB = m_regs->DISP[i].DISPFB; GIFRegTEX0 TEX0; TEX0.TBP0 = DISPFB.Block(); TEX0.TBW = DISPFB.FBW; TEX0.PSM = DISPFB.PSM; // TRACE(_T("[%d] GetOutput %d %05x (%d)\n"), (int)m_perfmon.GetFrame(), i, (int)TEX0.TBP0, (int)TEX0.PSM); GSTexture* t = NULL; if(GSTextureCache::Target* rt = m_tc->LookupTarget(TEX0, m_width, m_height, GetFramebufferHeight())) { t = rt->m_texture; int delta = TEX0.TBP0 - rt->m_TEX0.TBP0; if (delta > 0 && DISPFB.FBW != 0) { int pages = delta >> 5u; int y_pages = pages / DISPFB.FBW; y_offset = y_pages * GSLocalMemory::m_psm[DISPFB.PSM].pgs.y; GL_CACHE("Frame y offset %d pixels, unit %d", y_offset, i); } #ifdef ENABLE_OGL_DEBUG if(s_dump) { if(s_savef && s_n >= s_saven) { t->Save(m_dump_root + format("%05d_f%lld_fr%d_%05x_%s.bmp", s_n, m_perfmon.GetFrame(), i, (int)TEX0.TBP0, psm_str(TEX0.PSM))); } } #endif } return t; } GSTexture* GSRendererHW::GetFeedbackOutput() { GIFRegTEX0 TEX0; TEX0.TBP0 = m_regs->EXTBUF.EXBP; TEX0.TBW = m_regs->EXTBUF.EXBW; TEX0.PSM = m_regs->DISP[m_regs->EXTBUF.FBIN & 1].DISPFB.PSM; GSTextureCache::Target* rt = m_tc->LookupTarget(TEX0, m_width, m_height, /*GetFrameRect(i).bottom*/0); GSTexture* t = rt->m_texture; #ifdef ENABLE_OGL_DEBUG if(s_dump && s_savef && s_n >= s_saven) t->Save(m_dump_root + format("%05d_f%lld_fr%d_%05x_%s.bmp", s_n, m_perfmon.GetFrame(), 3, (int)TEX0.TBP0, psm_str(TEX0.PSM))); #endif return t; } void GSRendererHW::InvalidateVideoMem(const GIFRegBITBLTBUF& BITBLTBUF, const GSVector4i& r) { // printf("[%d] InvalidateVideoMem %d,%d - %d,%d %05x (%d)\n", (int)m_perfmon.GetFrame(), r.left, r.top, r.right, r.bottom, (int)BITBLTBUF.DBP, (int)BITBLTBUF.DPSM); m_tc->InvalidateVideoMem(m_mem.GetOffset(BITBLTBUF.DBP, BITBLTBUF.DBW, BITBLTBUF.DPSM), r); } void GSRendererHW::InvalidateLocalMem(const GIFRegBITBLTBUF& BITBLTBUF, const GSVector4i& r, bool clut) { // printf("[%d] InvalidateLocalMem %d,%d - %d,%d %05x (%d)\n", (int)m_perfmon.GetFrame(), r.left, r.top, r.right, r.bottom, (int)BITBLTBUF.SBP, (int)BITBLTBUF.SPSM); if(clut) return; // FIXME m_tc->InvalidateLocalMem(m_mem.GetOffset(BITBLTBUF.SBP, BITBLTBUF.SBW, BITBLTBUF.SPSM), r); } uint16 GSRendererHW::Interpolate_UV(float alpha, int t0, int t1) { float t = (1.0f - alpha) * t0 + alpha * t1; return (uint16)t & ~0xF; // cheap rounding } float GSRendererHW::alpha0(int L, int X0, int X1) { int x = (X0 + 15) & ~0xF; // Round up return float(x - X0) / (float)L; } float GSRendererHW::alpha1(int L, int X0, int X1) { int x = (X1 - 1) & ~0xF; // Round down. Note -1 because right pixel isn't included in primitive so 0x100 must return 0. return float(x - X0) / (float)L; } template void GSRendererHW::RoundSpriteOffset() { //#define DEBUG_U //#define DEBUG_V #if defined(DEBUG_V) || defined(DEBUG_U) bool debug = linear; #endif size_t count = m_vertex.next; GSVertex* v = &m_vertex.buff[0]; for(size_t i = 0; i < count; i += 2) { // Performance note: if it had any impact on perf, someone would port it to SSE (AKA GSVector) // Compute the coordinate of first and last texels (in native with a linear filtering) int ox = m_context->XYOFFSET.OFX; int X0 = v[i].XYZ.X - ox; int X1 = v[i+1].XYZ.X - ox; int Lx = (v[i+1].XYZ.X - v[i].XYZ.X); float ax0 = alpha0(Lx, X0, X1); float ax1 = alpha1(Lx, X0, X1); uint16 tx0 = Interpolate_UV(ax0, v[i].U, v[i+1].U); uint16 tx1 = Interpolate_UV(ax1, v[i].U, v[i+1].U); #ifdef DEBUG_U if (debug) { fprintf(stderr, "u0:%d and u1:%d\n", v[i].U, v[i+1].U); fprintf(stderr, "a0:%f and a1:%f\n", ax0, ax1); fprintf(stderr, "t0:%d and t1:%d\n", tx0, tx1); } #endif int oy = m_context->XYOFFSET.OFY; int Y0 = v[i].XYZ.Y - oy; int Y1 = v[i+1].XYZ.Y - oy; int Ly = (v[i+1].XYZ.Y - v[i].XYZ.Y); float ay0 = alpha0(Ly, Y0, Y1); float ay1 = alpha1(Ly, Y0, Y1); uint16 ty0 = Interpolate_UV(ay0, v[i].V, v[i+1].V); uint16 ty1 = Interpolate_UV(ay1, v[i].V, v[i+1].V); #ifdef DEBUG_V if (debug) { fprintf(stderr, "v0:%d and v1:%d\n", v[i].V, v[i+1].V); fprintf(stderr, "a0:%f and a1:%f\n", ay0, ay1); fprintf(stderr, "t0:%d and t1:%d\n", ty0, ty1); } #endif #ifdef DEBUG_U if (debug) fprintf(stderr, "GREP_BEFORE %d => %d\n", v[i].U, v[i+1].U); #endif #ifdef DEBUG_V if (debug) fprintf(stderr, "GREP_BEFORE %d => %d\n", v[i].V, v[i+1].V); #endif #if 1 // Use rounded value of the newly computed texture coordinate. It ensures // that sampling will remains inside texture boundary // // Note for bilinear: by definition it will never work correctly! A sligh modification // of interpolation migth trigger a discard (with alpha testing) // Let's use something simple that correct really bad case (for a couple of 2D games). // I hope it won't create too much glitches. if (linear) { int Lu = v[i+1].U - v[i].U; // Note 32 is based on taisho-mononoke if ((Lu > 0) && (Lu <= (Lx+32))) { v[i+1].U -= 8; } } else { if (tx0 <= tx1) { v[i].U = tx0; v[i+1].U = tx1 + 16; } else { v[i].U = tx0 + 15; v[i+1].U = tx1; } } #endif #if 1 if (linear) { int Lv = v[i+1].V - v[i].V; if ((Lv > 0) && (Lv <= (Ly+32))) { v[i+1].V -= 8; } } else { if (ty0 <= ty1) { v[i].V = ty0; v[i+1].V = ty1 + 16; } else { v[i].V = ty0 + 15; v[i+1].V = ty1; } } #endif #ifdef DEBUG_U if (debug) fprintf(stderr, "GREP_AFTER %d => %d\n\n", v[i].U, v[i+1].U); #endif #ifdef DEBUG_V if (debug) fprintf(stderr, "GREP_AFTER %d => %d\n\n", v[i].V, v[i+1].V); #endif } } void GSRendererHW::Draw() { if(m_dev->IsLost() || IsBadFrame()) { GL_INS("Warning skipping a draw call (%d)", s_n); return; } GL_PUSH("HW Draw %d", s_n); GSDrawingEnvironment& env = m_env; GSDrawingContext* context = m_context; const GSLocalMemory::psm_t& tex_psm = GSLocalMemory::m_psm[m_context->TEX0.PSM]; // skip alpha test if possible // Note: do it first so we know if frame/depth writes are masked GIFRegTEST TEST = context->TEST; GIFRegFRAME FRAME = context->FRAME; GIFRegZBUF ZBUF = context->ZBUF; uint32 fm = context->FRAME.FBMSK; uint32 zm = context->ZBUF.ZMSK || context->TEST.ZTE == 0 ? 0xffffffff : 0; // Note required to compute TryAlphaTest below. So do it now. if (PRIM->TME && tex_psm.pal > 0) m_mem.m_clut.Read32(context->TEX0, env.TEXA); // Test if we can optimize Alpha Test as a NOP context->TEST.ATE = context->TEST.ATE && !GSRenderer::TryAlphaTest(fm, zm); context->FRAME.FBMSK = fm; context->ZBUF.ZMSK = zm != 0; // It is allowed to use the depth and rt at the same location. However at least 1 must // be disabled. Or the written value must be the same on both channels. // 1/ GoW uses a Cd blending on a 24 bits buffer (no alpha) // 2/ SuperMan really draws (0,0,0,0) color and a (0) 32-bits depth // 3/ 50cents really draws (0,0,0,128) color and a (0) 24 bits depth // Note: FF DoC has both buffer at same location but disable the depth test (write?) with ZTE = 0 const bool no_rt = (context->ALPHA.IsCd() && PRIM->ABE && (context->FRAME.PSM == 1)); const bool no_ds = !no_rt && ( // Depth is always pass/fail (no read) and write are discarded (tekken 5). (Note: DATE is currently implemented with a stencil buffer => a depth/stencil buffer) (zm != 0 && m_context->TEST.ZTST <= ZTST_ALWAYS && !m_context->TEST.DATE) || // Depth will be written through the RT (context->FRAME.FBP == context->ZBUF.ZBP && !PRIM->TME && zm == 0 && fm == 0 && context->TEST.ZTE) ); const bool draw_sprite_tex = PRIM->TME && (m_vt.m_primclass == GS_SPRITE_CLASS); const GSVector4 delta_p = m_vt.m_max.p - m_vt.m_min.p; bool single_page = (delta_p.x <= 64.0f) && (delta_p.y <= 64.0f); if (m_channel_shuffle) { m_channel_shuffle = draw_sprite_tex && (m_context->TEX0.PSM == PSM_PSMT8) && single_page; if (m_channel_shuffle) { GL_CACHE("Channel shuffle effect detected SKIP"); return; } } else if (draw_sprite_tex && m_context->FRAME.Block() == m_context->TEX0.TBP0) { // Special post-processing effect if ((m_context->TEX0.PSM == PSM_PSMT8) && single_page) { GL_INS("Channel shuffle effect detected"); m_channel_shuffle = true; } else { GL_DBG("Special post-processing effect not supported"); m_channel_shuffle = false; } } else { m_channel_shuffle = false; } GIFRegTEX0 TEX0; TEX0.TBP0 = context->FRAME.Block(); TEX0.TBW = context->FRAME.FBW; TEX0.PSM = context->FRAME.PSM; GSTextureCache::Target* rt = NULL; GSTexture* rt_tex = NULL; if (!no_rt) { rt = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::RenderTarget, true, fm); rt_tex = rt->m_texture; } TEX0.TBP0 = context->ZBUF.Block(); TEX0.TBW = context->FRAME.FBW; TEX0.PSM = context->ZBUF.PSM; GSTextureCache::Target* ds = NULL; GSTexture* ds_tex = NULL; if (!no_ds) { ds = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::DepthStencil, context->DepthWrite()); ds_tex = ds->m_texture; } GSTextureCache::Source* tex = NULL; m_texture_shuffle = false; if(PRIM->TME) { GIFRegCLAMP MIP_CLAMP = context->CLAMP; int mxl = std::min((int)m_context->TEX1.MXL, 6); m_lod = GSVector2i(0, 0); // Code from the SW renderer if (IsMipMapActive()) { int interpolation = (context->TEX1.MMIN & 1) + 1; // 1: round, 2: tri int k = (m_context->TEX1.K + 8) >> 4; int lcm = m_context->TEX1.LCM; if ((int)m_vt.m_lod.x >= mxl) { k = mxl; // set lod to max level lcm = 1; // constant lod } if (PRIM->FST) { ASSERT(lcm == 1); ASSERT(((m_vt.m_min.t.uph(m_vt.m_max.t) == GSVector4::zero()).mask() & 3) == 3); // ratchet and clank (menu) lcm = 1; } if (lcm == 1) { m_lod.x = std::max(k, 0); m_lod.y = m_lod.x; } else { // Not constant but who care ! if (interpolation == 2) { // Mipmap Linear. Both layers are sampled, only take the big one m_lod.x = std::max((int)floor(m_vt.m_lod.x), 0); } else { // On GS lod is a fixed float number 7:4 (4 bit for the frac part) #if 0 m_lod.x = std::max((int)round(m_vt.m_lod.x + 0.0625), 0); #else // Same as above with a bigger margin on rounding // The goal is to avoid 1 undrawn pixels around the edge which trigger the load of the big // layer. if (ceil(m_vt.m_lod.x) < m_vt.m_lod.y) m_lod.x = std::max((int)round(m_vt.m_lod.x + 0.0625 + 0.01), 0); else m_lod.x = std::max((int)round(m_vt.m_lod.x + 0.0625), 0); #endif } m_lod.y = std::max((int)ceil(m_vt.m_lod.y), 0); } m_lod.x = std::min(m_lod.x, mxl); m_lod.y = std::min(m_lod.y, mxl); TEX0 = GetTex0Layer(m_lod.x); MIP_CLAMP.MINU >>= m_lod.x; MIP_CLAMP.MINV >>= m_lod.x; MIP_CLAMP.MAXU >>= m_lod.x; MIP_CLAMP.MAXV >>= m_lod.x; for (int i = 0; i < m_lod.x; i++) { m_vt.m_min.t *= 0.5f; m_vt.m_max.t *= 0.5f; } GL_CACHE("Mipmap LOD %d %d (%f %f) new size %dx%d (K %d L %u)", m_lod.x, m_lod.y, m_vt.m_lod.x, m_vt.m_lod.y, 1 << TEX0.TW, 1 << TEX0.TH, m_context->TEX1.K, m_context->TEX1.L); } else { TEX0 = GetTex0Layer(0); } m_context->offset.tex = m_mem.GetOffset(TEX0.TBP0, TEX0.TBW, TEX0.PSM); GSVector4i r; GetTextureMinMax(r, TEX0, MIP_CLAMP, m_vt.IsLinear()); tex = tex_psm.depth ? m_tc->LookupDepthSource(TEX0, env.TEXA, r) : m_tc->LookupSource(TEX0, env.TEXA, r); // Round 2 if (IsMipMapActive() && m_mipmap == 2 && !tex_psm.depth) { // Upload remaining texture layers GSVector4 tmin = m_vt.m_min.t; GSVector4 tmax = m_vt.m_max.t; for (int layer = m_lod.x + 1; layer <= m_lod.y; layer++) { const GIFRegTEX0& MIP_TEX0 = GetTex0Layer(layer); m_context->offset.tex = m_mem.GetOffset(MIP_TEX0.TBP0, MIP_TEX0.TBW, MIP_TEX0.PSM); MIP_CLAMP.MINU >>= 1; MIP_CLAMP.MINV >>= 1; MIP_CLAMP.MAXU >>= 1; MIP_CLAMP.MAXV >>= 1; m_vt.m_min.t *= 0.5f; m_vt.m_max.t *= 0.5f; GetTextureMinMax(r, MIP_TEX0, MIP_CLAMP, m_vt.IsLinear()); tex->UpdateLayer(MIP_TEX0, r, layer - m_lod.x); } m_vt.m_min.t = tmin; m_vt.m_max.t = tmax; } // Hypothesis: texture shuffle is used as a postprocessing effect so texture will be an old target. // Initially code also tested the RT but it gives too much false-positive // // Both input and output are 16 bits and texture was initially 32 bits! m_texture_shuffle = (GSLocalMemory::m_psm[context->FRAME.PSM].bpp == 16) && (tex_psm.bpp == 16) && draw_sprite_tex && tex->m_32_bits_fmt; // Texture shuffle is not yet supported with strange clamp mode ASSERT(!m_texture_shuffle || (context->CLAMP.WMS < 3 && context->CLAMP.WMT < 3)); if (tex->m_target && m_context->TEX0.PSM == PSM_PSMT8 && single_page && draw_sprite_tex) { GL_INS("Channel shuffle effect detected (2nd shot)"); m_channel_shuffle = true; } else { m_channel_shuffle = false; } } if (rt) { // Be sure texture shuffle detection is properly propagated // Otherwise set or clear the flag (Code in texture cache only set the flag) // Note: it is important to clear the flag when RT is used as a real 16 bits target. rt->m_32_bits_fmt = m_texture_shuffle || (GSLocalMemory::m_psm[context->FRAME.PSM].bpp != 16); } if(s_dump) { uint64 frame = m_perfmon.GetFrame(); string s; if (s_n >= s_saven) { // Dump Register state s = format("%05d_context.txt", s_n); m_env.Dump(m_dump_root+s); m_context->Dump(m_dump_root+s); } if(s_savet && s_n >= s_saven && tex) { s = format("%05d_f%lld_itex_%05x_%s_%d%d_%02x_%02x_%02x_%02x.dds", s_n, frame, (int)context->TEX0.TBP0, psm_str(context->TEX0.PSM), (int)context->CLAMP.WMS, (int)context->CLAMP.WMT, (int)context->CLAMP.MINU, (int)context->CLAMP.MAXU, (int)context->CLAMP.MINV, (int)context->CLAMP.MAXV); tex->m_texture->Save(m_dump_root+s, true); if(tex->m_palette) { s = format("%05d_f%lld_itpx_%05x_%s.dds", s_n, frame, context->TEX0.CBP, psm_str(context->TEX0.CPSM)); tex->m_palette->Save(m_dump_root+s, true); } } if(s_save && s_n >= s_saven) { s = format("%05d_f%lld_rt0_%05x_%s.bmp", s_n, frame, context->FRAME.Block(), psm_str(context->FRAME.PSM)); if (rt) rt->m_texture->Save(m_dump_root+s); } if(s_savez && s_n >= s_saven) { s = format("%05d_f%lld_rz0_%05x_%s.bmp", s_n, frame, context->ZBUF.Block(), psm_str(context->ZBUF.PSM)); if (ds_tex) ds_tex->Save(m_dump_root+s); } } // The rectangle of the draw GSVector4i r = GSVector4i(m_vt.m_min.p.xyxy(m_vt.m_max.p)).rintersect(GSVector4i(context->scissor.in)); if(m_hacks.m_oi && !(this->*m_hacks.m_oi)(rt_tex, ds_tex, tex)) { GL_INS("Warning skipping a draw call (%d)", s_n); return; } if (!OI_BlitFMV(rt, tex, r)) { GL_INS("Warning skipping a draw call (%d)", s_n); return; } if (!m_userhacks_disable_gs_mem_clear) { // Constant Direct Write without texture/test/blending (aka a GS mem clear) if ((m_vt.m_primclass == GS_SPRITE_CLASS) && !PRIM->TME // Direct write && (!PRIM->ABE || m_context->ALPHA.IsOpaque()) // No transparency && (m_context->FRAME.FBMSK == 0) // no color mask && !m_context->TEST.ATE // no alpha test && (!m_context->TEST.ZTE || m_context->TEST.ZTST == ZTST_ALWAYS) // no depth test && (m_vt.m_eq.rgba == 0xFFFF) // constant color write && r.x == 0 && r.y == 0) { // Likely full buffer write OI_GsMemClear(); OI_DoubleHalfClear(rt_tex, ds_tex); } } // A couple of hack to avoid upscaling issue. So far it seems to impacts mostly sprite // Note: first hack corrects both position and texture coordinate // Note: second hack corrects only the texture coordinate if ((m_upscale_multiplier > 1) && (m_vt.m_primclass == GS_SPRITE_CLASS)) { size_t count = m_vertex.next; GSVertex* v = &m_vertex.buff[0]; // Hack to avoid vertical black line in various games (ace combat/tekken) if (m_userhacks_align_sprite_X) { // Note for performance reason I do the check only once on the first // primitive int win_position = v[1].XYZ.X - context->XYOFFSET.OFX; const bool unaligned_position = ((win_position & 0xF) == 8); const bool unaligned_texture = ((v[1].U & 0xF) == 0) && PRIM->FST; // I'm not sure this check is useful const bool hole_in_vertex = (count < 4) || (v[1].XYZ.X != v[2].XYZ.X); if (hole_in_vertex && unaligned_position && (unaligned_texture || !PRIM->FST)) { // Normaly vertex are aligned on full pixels and texture in half // pixels. Let's extend the coverage of an half-pixel to avoid // hole after upscaling for(size_t i = 0; i < count; i += 2) { v[i+1].XYZ.X += 8; // I really don't know if it is a good idea. Neither what to do for !PRIM->FST if (unaligned_texture) v[i+1].U += 8; } } } // Noting to do if no texture is sampled if (PRIM->FST && draw_sprite_tex) { if ((m_userhacks_round_sprite_offset > 1) || (m_userhacks_round_sprite_offset == 1 && !m_vt.IsLinear())) { if (m_vt.IsLinear()) RoundSpriteOffset(); else RoundSpriteOffset(); } } else { ; // vertical line in Yakuza (note check m_userhacks_align_sprite_X behavior) } } // DrawPrims(rt_tex, ds_tex, tex); // context->TEST = TEST; context->FRAME = FRAME; context->ZBUF = ZBUF; // // Help to detect rendering outside of the framebuffer #if _DEBUG if (m_upscale_multiplier * r.z > m_width) { GL_INS("ERROR: RT width is too small only %d but require %d", m_width, m_upscale_multiplier * r.z); } if (m_upscale_multiplier * r.w > m_height) { GL_INS("ERROR: RT height is too small only %d but require %d", m_height, m_upscale_multiplier * r.w); } #endif if(fm != 0xffffffff && rt) { //rt->m_valid = rt->m_valid.runion(r); rt->UpdateValidity(r); m_tc->InvalidateVideoMem(context->offset.fb, r, false); m_tc->InvalidateVideoMemType(GSTextureCache::DepthStencil, context->FRAME.Block()); } if(zm != 0xffffffff && ds) { //ds->m_valid = ds->m_valid.runion(r); ds->UpdateValidity(r); m_tc->InvalidateVideoMem(context->offset.zb, r, false); m_tc->InvalidateVideoMemType(GSTextureCache::RenderTarget, context->ZBUF.Block()); } // if(m_hacks.m_oo) { (this->*m_hacks.m_oo)(); } if(s_dump) { uint64 frame = m_perfmon.GetFrame(); string s; if(s_save && s_n >= s_saven) { s = format("%05d_f%lld_rt1_%05x_%s.bmp", s_n, frame, context->FRAME.Block(), psm_str(context->FRAME.PSM)); if (rt) rt->m_texture->Save(m_dump_root+s); } if(s_savez && s_n >= s_saven) { s = format("%05d_f%lld_rz1_%05x_%s.bmp", s_n, frame, context->ZBUF.Block(), psm_str(context->ZBUF.PSM)); if (ds_tex) ds_tex->Save(m_dump_root+s); } if(s_savel > 0 && (s_n - s_saven) > s_savel) { s_dump = 0; } } #ifdef DISABLE_HW_TEXTURE_CACHE if (rt) m_tc->Read(rt, r); #endif } // hacks GSRendererHW::Hacks::Hacks() : m_oi_map(m_oi_list) , m_oo_map(m_oo_list) , m_cu_map(m_cu_list) , m_oi(NULL) , m_oo(NULL) , m_cu(NULL) { bool is_opengl = theApp.GetCurrentRendererType() == GSRendererType::OGL_HW; bool can_handle_depth = (!theApp.GetConfigB("UserHacks") || !theApp.GetConfigB("UserHacks_DisableDepthSupport")) && is_opengl; m_oi_list.push_back(HackEntry(CRC::FFXII, CRC::EU, &GSRendererHW::OI_FFXII)); m_oi_list.push_back(HackEntry(CRC::FFX, CRC::RegionCount, &GSRendererHW::OI_FFX)); m_oi_list.push_back(HackEntry(CRC::MetalSlug6, CRC::RegionCount, &GSRendererHW::OI_MetalSlug6)); m_oi_list.push_back(HackEntry(CRC::RozenMaidenGebetGarden, CRC::RegionCount, &GSRendererHW::OI_RozenMaidenGebetGarden)); m_oi_list.push_back(HackEntry(CRC::StarWarsForceUnleashed, CRC::RegionCount, &GSRendererHW::OI_StarWarsForceUnleashed)); m_oi_list.push_back(HackEntry(CRC::SpyroNewBeginning, CRC::RegionCount, &GSRendererHW::OI_SpyroNewBeginning)); m_oi_list.push_back(HackEntry(CRC::SpyroEternalNight, CRC::RegionCount, &GSRendererHW::OI_SpyroEternalNight)); m_oi_list.push_back(HackEntry(CRC::SuperManReturns, CRC::RegionCount, &GSRendererHW::OI_SuperManReturns)); m_oi_list.push_back(HackEntry(CRC::TalesOfLegendia, CRC::RegionCount, &GSRendererHW::OI_TalesOfLegendia)); m_oi_list.push_back(HackEntry(CRC::ArTonelico2, CRC::RegionCount, &GSRendererHW::OI_ArTonelico2)); m_oi_list.push_back(HackEntry(CRC::ItadakiStreet, CRC::RegionCount, &GSRendererHW::OI_ItadakiStreet)); if (!can_handle_depth) { m_oi_list.push_back(HackEntry(CRC::SMTNocturne, CRC::RegionCount, &GSRendererHW::OI_SMTNocturne)); m_oi_list.push_back(HackEntry(CRC::GodOfWar2, CRC::RegionCount, &GSRendererHW::OI_GodOfWar2)); } m_oo_list.push_back(HackEntry(CRC::DBZBT2, CRC::RegionCount, &GSRendererHW::OO_DBZBT2)); m_oo_list.push_back(HackEntry(CRC::MajokkoALaMode2, CRC::RegionCount, &GSRendererHW::OO_MajokkoALaMode2)); m_oo_list.push_back(HackEntry(CRC::Jak2, CRC::RegionCount, &GSRendererHW::OO_Jak)); m_oo_list.push_back(HackEntry(CRC::Jak3, CRC::RegionCount, &GSRendererHW::OO_Jak)); m_oo_list.push_back(HackEntry(CRC::JakX, CRC::RegionCount, &GSRendererHW::OO_Jak)); m_cu_list.push_back(HackEntry(CRC::DBZBT2, CRC::RegionCount, &GSRendererHW::CU_DBZBT2)); m_cu_list.push_back(HackEntry(CRC::MajokkoALaMode2, CRC::RegionCount, &GSRendererHW::CU_MajokkoALaMode2)); m_cu_list.push_back(HackEntry(CRC::TalesOfAbyss, CRC::RegionCount, &GSRendererHW::CU_TalesOfAbyss)); } void GSRendererHW::Hacks::SetGameCRC(const CRC::Game& game) { uint32 hash = (uint32)((game.region << 24) | game.title); m_oi = m_oi_map[hash]; m_oo = m_oo_map[hash]; m_cu = m_cu_map[hash]; if (game.flags & CRC::PointListPalette) { ASSERT(m_oi == NULL); m_oi = &GSRendererHW::OI_PointListPalette; } } // Trick to do a fast clear on the GS // Set frame buffer pointer on the start of the buffer. Set depth buffer pointer on the half buffer // FB + depth write will fill the full buffer. void GSRendererHW::OI_DoubleHalfClear(GSTexture* rt, GSTexture* ds) { // Note gs mem clear must be tested before calling this function // Limit further to unmask Z write if (!m_context->ZBUF.ZMSK && rt && ds) { const GSVertex* v = &m_vertex.buff[0]; const GSLocalMemory::psm_t& frame_psm = GSLocalMemory::m_psm[m_context->FRAME.PSM]; //const GSLocalMemory::psm_t& depth_psm = GSLocalMemory::m_psm[m_context->ZBUF.PSM]; // Z and color must be constant and the same if (m_vt.m_eq.rgba != 0xFFFF || !m_vt.m_eq.z || v[1].XYZ.Z != v[1].RGBAQ.u32[0]) return; // Format doesn't have the same size. It smells fishy (xmen...) //if (frame_psm.trbpp != depth_psm.trbpp) // return; // Size of the current draw uint32 w_pages = static_cast(roundf(m_vt.m_max.p.x / frame_psm.pgs.x)); uint32 h_pages = static_cast(roundf(m_vt.m_max.p.y / frame_psm.pgs.y)); uint32 written_pages = w_pages * h_pages; // Frame and depth pointer can be inverted uint32 base; uint32 half; if (m_context->FRAME.FBP > m_context->ZBUF.ZBP) { base = m_context->ZBUF.ZBP; half = m_context->FRAME.FBP; } else { base = m_context->FRAME.FBP; half = m_context->ZBUF.ZBP; } // If both buffers are side by side we can expect a fast clear in on-going if (half <= (base + written_pages)) { uint32 color = v[1].RGBAQ.u32[0]; GL_INS("OI_DoubleHalfClear: base %x half %x. w_pages %d h_pages %d fbw %d. Color %x", base << 5, half << 5, w_pages, h_pages, m_context->FRAME.FBW, color); if (m_context->FRAME.FBP > m_context->ZBUF.ZBP) { // Only pure clear are supported for depth ASSERT(color == 0); m_dev->ClearDepth(ds); } else { m_dev->ClearRenderTarget(rt, color); } } } } // Note: hack is safe, but it could impact the perf a little (normally games do only a couple of clear by frame) void GSRendererHW::OI_GsMemClear() { // Note gs mem clear must be tested before calling this function // Limit it further to a full screen 0 write if ((m_vertex.next == 2) && m_vt.m_min.c.eq(GSVector4i(0))) { GSOffset* off = m_context->offset.fb; GSVector4i r = GSVector4i(m_vt.m_min.p.xyxy(m_vt.m_max.p)).rintersect(GSVector4i(m_context->scissor.in)); // Limit the hack to a single fullscreen clear. Some games might use severals column to clear a screen // but hopefully it will be enough. if (r.width() <= 128 || r.height() <= 128) return; GL_INS("OI_GsMemClear (%d,%d => %d,%d)", r.x, r.y, r.z, r.w); int format = GSLocalMemory::m_psm[m_context->FRAME.PSM].fmt; // FIXME: loop can likely be optimized with AVX/SSE. Pixels aren't // linear but the value will be done for all pixels of a block. // FIXME: maybe we could limit the write to the top and bottom row page. if (format == 0) { // Based on WritePixel32 for(int y = r.top; y < r.bottom; y++) { uint32* RESTRICT d = &m_mem.m_vm32[off->pixel.row[y]]; int* RESTRICT col = off->pixel.col[0]; for(int x = r.left; x < r.right; x++) { d[col[x]] = 0; // Here the constant color } } } else if (format == 1) { // Based on WritePixel24 for(int y = r.top; y < r.bottom; y++) { uint32* RESTRICT d = &m_mem.m_vm32[off->pixel.row[y]]; int* RESTRICT col = off->pixel.col[0]; for(int x = r.left; x < r.right; x++) { d[col[x]] &= 0xff000000; // Clear the color } } } else if (format == 2) { ; // Hack is used for FMV which are likely 24/32 bits. Let's keep the for reference #if 0 // Based on WritePixel16 for(int y = r.top; y < r.bottom; y++) { uint32* RESTRICT d = &m_mem.m_vm16[off->pixel.row[y]]; int* RESTRICT col = off->pixel.col[0]; for(int x = r.left; x < r.right; x++) { d[col[x]] = 0; // Here the constant color } } #endif } } } bool GSRendererHW::OI_BlitFMV(GSTextureCache::Target* _rt, GSTextureCache::Source* tex, const GSVector4i& r_draw) { if (r_draw.w > 1024 && (m_vt.m_primclass == GS_SPRITE_CLASS) && (m_vertex.next == 2) && PRIM->TME && !PRIM->ABE && tex && !tex->m_target && m_context->TEX0.TBW > 0) { GL_PUSH("OI_BlitFMV"); GL_INS("OI_BlitFMV"); // The draw is done past the RT at the location of the texture. To avoid various upscaling mess // We will blit the data from the top to the bottom of the texture manually. // Expected memory representation // ----------------------------------------------------------------- // RT (2 half frame) // ----------------------------------------------------------------- // Top of Texture (full height frame) // // Bottom of Texture (half height frame, will be the copy of Top texture after the draw) // ----------------------------------------------------------------- // sRect is the top of texture int tw = (int)(1 << m_context->TEX0.TW); int th = (int)(1 << m_context->TEX0.TH); GSVector4 sRect; sRect.x = m_vt.m_min.t.x / tw; sRect.y = m_vt.m_min.t.y / th; sRect.z = m_vt.m_max.t.x / tw; sRect.w = m_vt.m_max.t.y / th; // Compute the Bottom of texture rectangle ASSERT(m_context->TEX0.TBP0 > m_context->FRAME.Block()); int offset = (m_context->TEX0.TBP0 - m_context->FRAME.Block()) / m_context->TEX0.TBW; GSVector4i r_texture(r_draw); r_texture.y -= offset; r_texture.w -= offset; GSVector4 dRect(r_texture); // Do the blit. With a Copy mess to avoid issue with limited API (dx) // m_dev->StretchRect(tex->m_texture, sRect, tex->m_texture, dRect); GSVector4i r_full(0, 0, tw, th); if (GSTexture* rt = m_dev->CreateRenderTarget(tw, th, false)) { m_dev->CopyRect(tex->m_texture, rt, r_full); m_dev->StretchRect(tex->m_texture, sRect, rt, dRect); m_dev->CopyRect(rt, tex->m_texture, r_full); m_dev->Recycle(rt); } // Copy back the texture into the GS mem. I don't know why but it will be // reuploaded again later m_tc->Read(tex, r_texture); m_tc->InvalidateVideoMemSubTarget(_rt); return false; // skip current draw } // Nothing to see keep going return true; } // OI (others input?/implementation?) hacks replace current draw call bool GSRendererHW::OI_FFXII(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { static uint32* video = NULL; static size_t lines = 0; if(lines == 0) { if(m_vt.m_primclass == GS_LINE_CLASS && (m_vertex.next == 448 * 2 || m_vertex.next == 512 * 2)) { lines = m_vertex.next / 2; } } else { if(m_vt.m_primclass == GS_POINT_CLASS) { if(m_vertex.next >= 16 * 512) { // incoming pixels are stored in columns, one column is 16x512, total res 448x512 or 448x454 if(!video) video = new uint32[512 * 512]; int ox = m_context->XYOFFSET.OFX - 8; int oy = m_context->XYOFFSET.OFY - 8; const GSVertex* RESTRICT v = m_vertex.buff; for(int i = (int)m_vertex.next; i > 0; i--, v++) { int x = (v->XYZ.X - ox) >> 4; int y = (v->XYZ.Y - oy) >> 4; if (x < 0 || x >= 448 || y < 0 || y >= (int)lines) return false; // le sigh video[(y << 8) + (y << 7) + (y << 6) + x] = v->RGBAQ.u32[0]; } return false; } else { lines = 0; } } else if(m_vt.m_primclass == GS_LINE_CLASS) { if(m_vertex.next == lines * 2) { // normally, this step would copy the video onto screen with 512 texture mapped horizontal lines, // but we use the stored video data to create a new texture, and replace the lines with two triangles m_dev->Recycle(t->m_texture); t->m_texture = m_dev->CreateTexture(512, 512); t->m_texture->Update(GSVector4i(0, 0, 448, lines), video, 448 * 4); m_vertex.buff[2] = m_vertex.buff[m_vertex.next - 2]; m_vertex.buff[3] = m_vertex.buff[m_vertex.next - 1]; m_index.buff[0] = 0; m_index.buff[1] = 1; m_index.buff[2] = 2; m_index.buff[3] = 1; m_index.buff[4] = 2; m_index.buff[5] = 3; m_vertex.head = m_vertex.tail = m_vertex.next = 4; m_index.tail = 6; m_vt.Update(m_vertex.buff, m_index.buff, m_vertex.tail, m_index.tail, GS_TRIANGLE_CLASS); } else { lines = 0; } } } return true; } bool GSRendererHW::OI_FFX(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 ZBP = m_context->ZBUF.Block(); uint32 TBP = m_context->TEX0.TBP0; if((FBP == 0x00d00 || FBP == 0x00000) && ZBP == 0x02100 && PRIM->TME && TBP == 0x01a00 && m_context->TEX0.PSM == PSM_PSMCT16S) { // random battle transition (z buffer written directly, clear it now) m_dev->ClearDepth(ds); } return true; } bool GSRendererHW::OI_MetalSlug6(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { // missing red channel fix (looks alright in pcsx2 r5000+) GSVertex* RESTRICT v = m_vertex.buff; for(int i = (int)m_vertex.next; i > 0; i--, v++) { uint32 c = v->RGBAQ.u32[0]; uint32 r = (c >> 0) & 0xff; uint32 g = (c >> 8) & 0xff; uint32 b = (c >> 16) & 0xff; if(r == 0 && g != 0 && b != 0) { v->RGBAQ.u32[0] = (c & 0xffffff00) | ((g + b + 1) >> 1); } } m_vt.Update(m_vertex.buff, m_index.buff, m_vertex.tail, m_index.tail, m_vt.m_primclass); return true; } bool GSRendererHW::OI_GodOfWar2(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 FBW = m_context->FRAME.FBW; uint32 FPSM = m_context->FRAME.PSM; if((FBP == 0x00f00 || FBP == 0x00100 || FBP == 0x01280) && FPSM == PSM_PSMZ24) // ntsc 0xf00, pal 0x100, ntsc "HD" 0x1280 { // z buffer clear GIFRegTEX0 TEX0; TEX0.TBP0 = FBP; TEX0.TBW = FBW; TEX0.PSM = FPSM; if(GSTextureCache::Target* tmp_ds = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::DepthStencil, true)) { m_dev->ClearDepth(tmp_ds->m_texture); } return false; } return true; } bool GSRendererHW::OI_RozenMaidenGebetGarden(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { if(!PRIM->TME) { uint32 FBP = m_context->FRAME.Block(); uint32 ZBP = m_context->ZBUF.Block(); if(FBP == 0x008c0 && ZBP == 0x01a40) { // frame buffer clear, atst = fail, afail = write z only, z buffer points to frame buffer GIFRegTEX0 TEX0; TEX0.TBP0 = ZBP; TEX0.TBW = m_context->FRAME.FBW; TEX0.PSM = m_context->FRAME.PSM; if(GSTextureCache::Target* tmp_rt = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::RenderTarget, true)) { m_dev->ClearRenderTarget(tmp_rt->m_texture, 0); } return false; } else if(FBP == 0x00000 && m_context->ZBUF.Block() == 0x01180) { // z buffer clear, frame buffer now points to the z buffer (how can they be so clever?) GIFRegTEX0 TEX0; TEX0.TBP0 = FBP; TEX0.TBW = m_context->FRAME.FBW; TEX0.PSM = m_context->ZBUF.PSM; if(GSTextureCache::Target* tmp_ds = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::DepthStencil, true)) { m_dev->ClearDepth(tmp_ds->m_texture); } return false; } } return true; } bool GSRendererHW::OI_StarWarsForceUnleashed(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 FPSM = m_context->FRAME.PSM; if(!PRIM->TME) { if(FPSM == PSM_PSMCT24 && FBP == 0x2bc0) { m_dev->ClearDepth(ds); return false; } } else if(PRIM->TME) { if((FBP == 0x0 || FBP == 0x01180) && FPSM == PSM_PSMCT32 && (m_vt.m_eq.z && m_vt.m_max.p.z == 0)) { m_dev->ClearDepth(ds); } } return true; } bool GSRendererHW::OI_SpyroNewBeginning(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 FPSM = m_context->FRAME.PSM; if(PRIM->TME) { if((FBP == 0x0 || FBP == 0x01180) && FPSM == PSM_PSMCT32 && (m_vt.m_eq.z && m_vt.m_min.p.z == 0)) { m_dev->ClearDepth(ds); } } return true; } bool GSRendererHW::OI_SpyroEternalNight(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 FPSM = m_context->FRAME.PSM; if(PRIM->TME) { if((FBP == 0x0 || FBP == 0x01180) && FPSM == PSM_PSMCT32 && (m_vt.m_eq.z && m_vt.m_min.p.z == 0)) { m_dev->ClearDepth(ds); } } return true; } bool GSRendererHW::OI_TalesOfLegendia(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBP = m_context->FRAME.Block(); uint32 FPSM = m_context->FRAME.PSM; if (FPSM == PSM_PSMCT32 && FBP == 0x01c00 && !m_context->TEST.ATE && m_vt.m_eq.z) { m_context->TEST.ZTST = ZTST_ALWAYS; //m_dev->ClearDepth(ds); } return true; } bool GSRendererHW::OI_SMTNocturne(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { uint32 FBMSK = m_context->FRAME.FBMSK; uint32 FBP = m_context->FRAME.Block(); uint32 FBW = m_context->FRAME.FBW; uint32 FPSM = m_context->FRAME.PSM; if(FBMSK == 16777215 && m_vertex.head != 2 && m_vertex.tail != 4 && m_vertex.next != 4) { GIFRegTEX0 TEX0; TEX0.TBP0 = FBP; TEX0.TBW = FBW; TEX0.PSM = FPSM; if (GSTextureCache::Target* tmp_ds = m_tc->LookupTarget(TEX0, m_width, m_height, GSTextureCache::DepthStencil, true)) { m_dev->ClearDepth(tmp_ds->m_texture); } return false; } return true; } bool GSRendererHW::OI_PointListPalette(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { if(m_vt.m_primclass == GS_POINT_CLASS && !PRIM->TME) { uint32 FBP = m_context->FRAME.Block(); uint32 FBW = m_context->FRAME.FBW; if(FBP >= 0x03f40 && (FBP & 0x1f) == 0) { if(m_vertex.next == 16) { GSVertex* RESTRICT v = m_vertex.buff; for(int i = 0; i < 16; i++, v++) { uint32 c = v->RGBAQ.u32[0]; uint32 a = c >> 24; c = (a >= 0x80 ? 0xff000000 : (a << 25)) | (c & 0x00ffffff); v->RGBAQ.u32[0] = c; m_mem.WritePixel32(i & 7, i >> 3, c, FBP, FBW); } m_mem.m_clut.Invalidate(); return false; } else if(m_vertex.next == 256) { GSVertex* RESTRICT v = m_vertex.buff; for(int i = 0; i < 256; i++, v++) { uint32 c = v->RGBAQ.u32[0]; uint32 a = c >> 24; c = (a >= 0x80 ? 0xff000000 : (a << 25)) | (c & 0x00ffffff); v->RGBAQ.u32[0] = c; m_mem.WritePixel32(i & 15, i >> 4, c, FBP, FBW); } m_mem.m_clut.Invalidate(); return false; } else { ASSERT(0); } } } return true; } bool GSRendererHW::OI_SuperManReturns(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { // Instead to use a fullscreen rectangle they use a 32 pixels, 4096 pixels with a FBW of 1. // Technically the FB wrap/overlap on itself... GSDrawingContext* ctx = m_context; #ifndef NDEBUG GSVertex* v = &m_vertex.buff[0]; #endif if (!(ctx->FRAME.FBP == ctx->ZBUF.ZBP && !PRIM->TME && !ctx->ZBUF.ZMSK && !ctx->FRAME.FBMSK && m_vt.m_eq.rgba == 0xFFFF)) return true; // Please kill those crazy devs! ASSERT(m_vertex.next == 2); ASSERT(m_vt.m_primclass == GS_SPRITE_CLASS); ASSERT((v->RGBAQ.A << 24 | v->RGBAQ.B << 16 | v->RGBAQ.G << 8 | v->RGBAQ.R) == (int)v->XYZ.Z); // Do a direct write m_dev->ClearRenderTarget(rt, GSVector4(m_vt.m_min.c)); m_tc->InvalidateVideoMemType(GSTextureCache::DepthStencil, ctx->FRAME.Block()); return false; } bool GSRendererHW::OI_ArTonelico2(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { // world map clipping // // The bad draw call is a sprite rendering to clear the z buffer /* Depth buffer description * width is 10 pages * texture/scissor size is 640x448 * depth is 16 bits so it writes 70 (10w * 7h) pages of data. following draw calls will use the buffer as 6 pages width with a scissor test of 384x672. So the above texture can be seen as a * texture width: 6 pages * 64 pixels/page = 384 * texture height: 70/6 pages * 64 pixels/page =746 So as you can see the GS issue a write of 640x448 but actually it expects to clean a 384x746 area. Ideally the fix will transform the buffer to adapt the page width properly. */ GSVertex* v = &m_vertex.buff[0]; if (m_vertex.next == 2 && !PRIM->TME && m_context->FRAME.FBW == 10 && v->XYZ.Z == 0 && m_context->TEST.ZTST == ZTST_ALWAYS) { GL_INS("OI_ArTonelico2"); m_dev->ClearDepth(ds); } return true; } bool GSRendererHW::OI_ItadakiStreet(GSTexture* rt, GSTexture* ds, GSTextureCache::Source* t) { if (m_context->TEST.ATST == ATST_NOTEQUAL && m_context->TEST.AREF == 0) { // It is also broken on the SW renderer. Issue appears because fragment alpha is 0 // I suspect the game expect low value of alpha, and due to bad rounding on the core // you have wrongly 0. // Otherwise some draws calls are empty (all pixels are discarded). // It fixes missing element on the board GL_INS("OI_ItadakiStreetSpecial disable alpha test"); m_context->TEST.ATST = ATST_ALWAYS; #if 0 // Not enough uint32 dummy_fm; uint32 dummy_zm; if (!TryAlphaTest(dummy_fm, dummy_zm)) { GL_INS("OI_ItadakiStreetSpecial disable alpha test"); m_context->TEST.ATST = ATST_ALWAYS; } #endif } return true; } // OO (others output?) hacks: invalidate extra local memory after the draw call void GSRendererHW::OO_DBZBT2() { // palette readback (cannot detect yet, when fetching the texture later) uint32 FBP = m_context->FRAME.Block(); uint32 TBP0 = m_context->TEX0.TBP0; if(PRIM->TME && (FBP == 0x03c00 && TBP0 == 0x03c80 || FBP == 0x03ac0 && TBP0 == 0x03b40)) { GIFRegBITBLTBUF BITBLTBUF; BITBLTBUF.SBP = FBP; BITBLTBUF.SBW = 1; BITBLTBUF.SPSM = PSM_PSMCT32; InvalidateLocalMem(BITBLTBUF, GSVector4i(0, 0, 64, 64)); } } void GSRendererHW::OO_MajokkoALaMode2() { // palette readback uint32 FBP = m_context->FRAME.Block(); if(!PRIM->TME && FBP == 0x03f40) { GIFRegBITBLTBUF BITBLTBUF; BITBLTBUF.SBP = FBP; BITBLTBUF.SBW = 1; BITBLTBUF.SPSM = PSM_PSMCT32; InvalidateLocalMem(BITBLTBUF, GSVector4i(0, 0, 16, 16)); } } void GSRendererHW::OO_Jak() { // FIXME might need a CU_Jak too GSVector4i r = GSVector4i(m_vt.m_min.p.xyxy(m_vt.m_max.p)).rintersect(GSVector4i(m_context->scissor.in)); GSVector4i r_p = GSVector4i(0, 0, 16, 16); if(!PRIM->FST && PRIM->TME && (r == r_p).alltrue() && m_context->TEX0.TW == 4 && m_context->TEX0.TH == 4 && m_context->TEX0.PSM == PSM_PSMCT32) { // Game will render a texture directly into a palette. uint32 FBP = m_context->FRAME.Block(); GL_INS("OO_Jak read back 0x%x", FBP); GIFRegBITBLTBUF BITBLTBUF; BITBLTBUF.SBP = FBP; BITBLTBUF.SBW = 1; BITBLTBUF.SPSM = PSM_PSMCT32; InvalidateLocalMem(BITBLTBUF, GSVector4i(0, 0, 16, 16)); } } // Can Upscale hacks: disable upscaling for some draw calls bool GSRendererHW::CU_DBZBT2() { // palette should stay 64 x 64 uint32 FBP = m_context->FRAME.Block(); return FBP != 0x03c00 && FBP != 0x03ac0; } bool GSRendererHW::CU_MajokkoALaMode2() { // palette should stay 16 x 16 uint32 FBP = m_context->FRAME.Block(); return FBP != 0x03f40; } bool GSRendererHW::CU_TalesOfAbyss() { // full image blur and brightening uint32 FBP = m_context->FRAME.Block(); return FBP != 0x036e0 && FBP != 0x03560 && FBP != 0x038e0; }