/* * 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 "GSDrawScanlineCodeGenerator.h" #include "GSVertexSW.h" #if _M_SSE < 0x501 && (defined(_M_AMD64) || defined(_WIN64)) // Ease the reading of the code #define _m_local r12 #define _m_local__gd r13 #define _m_local__gd__vm a1 #define _m_local__gd__clut r11 #define _m_local__gd__tex a3 // More pretty name #define _z xmm8 #define _f xmm9 #define _s xmm10 #define _t xmm11 #define _q xmm12 #define _f_rb xmm13 #define _f_ga xmm14 #define _test xmm15 // Extra bonus #define _rb xmm2 #define _ga xmm3 #define _fm xmm4 #define _zm xmm5 #define _fd xmm6 #define _rip_local(field) (m_rip ? ptr[rip + &m_local.field] : ptr[_m_local + offsetof(GSScanlineLocalData, field)]) #define _rip_global(field) (m_rip ? ptr[rip + &m_local.gd->field] : ptr[_m_local__gd + offsetof(GSScanlineGlobalData, field)]) #ifdef _WIN64 #else static const int _rz_rbx = -8 * 1; static const int _rz_r12 = -8 * 2; static const int _rz_r13 = -8 * 3; static const int _rz_r14 = -8 * 4; static const int _rz_r15 = -8 * 5; static const int _rz_top = -8 * 6; static const int _rz_zs = -8 * 8; static const int _rz_zd = -8 * 10; static const int _rz_cov = -8 * 12; #endif void GSDrawScanlineCodeGenerator::Generate_AVX() { bool need_tex = m_sel.fb && m_sel.tfx != TFX_NONE; bool need_clut = need_tex && m_sel.tlu; m_rip = (size_t)getCurr() < 0x80000000; m_rip &= (size_t)&m_local < 0x80000000; m_rip &= (size_t)&m_local.gd < 0x80000000; #ifdef _WIN64 push(rbx); push(rsi); push(rdi); push(rbp); push(r12); push(r13); sub(rsp, 8 + 10 * 16); for(int i = 6; i < 16; i++) { vmovdqa(ptr[rsp + (i - 6) * 16], Xmm(i)); } #else // No reservation on the stack as a red zone is available push(rbp); mov(ptr[rsp + _rz_rbx], rbx); if (!m_rip) { mov(ptr[rsp + _rz_r12], r12); mov(ptr[rsp + _rz_r13], r13); } #endif mov(r10, (size_t)&m_test[0]); if (!m_rip) { mov(_m_local, (size_t)&m_local); mov(_m_local__gd, _rip_local(gd)); } if(need_clut) mov(_m_local__gd__clut, _rip_global(clut)); Init_AVX(); // a0 = steps // t1 = fza_base // t0 = fza_offset // r10 = &m_test[0] // _m_local = &m_local // _m_local__gd = m_local->gd // _m_local__gd__vm = m_local->gd.vm // xmm7 = vf (sprite && ltf) // xmm8 = z // xmm9 = f // xmm10 = s // xmm11 = t // xmm12 = q // xmm13 = rb // xmm14 = ga // xmm15 = test if(!m_sel.edge) { align(16); } L("loop"); TestZ_AVX(xmm5, xmm6); // ebp = za if(m_sel.mmin) { SampleTextureLOD_AVX(); } else { SampleTexture_AVX(); } // ebp = za // xmm2 = rb // xmm3 = ga AlphaTFX_AVX(); // ebp = za // xmm2 = rb // xmm3 = ga ReadMask_AVX(); // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm TestAlpha_AVX(); // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm ColorTFX_AVX(); // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm Fog_AVX(); // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm ReadFrame_AVX(); // ebx = fa // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm // xmm6 = fd TestDestAlpha_AVX(); // ebx = fa // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm // xmm6 = fd WriteMask_AVX(); // ebx = fa // edx = fzm // ebp = za // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm5 = zm // xmm6 = fd WriteZBuf_AVX(); // ebx = fa // edx = fzm // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm6 = fd AlphaBlend_AVX(); // ebx = fa // edx = fzm // xmm2 = rb // xmm3 = ga // xmm4 = fm // xmm6 = fd WriteFrame_AVX(); L("step"); // if(steps <= 0) break; if(!m_sel.edge) { test(a0, a0); jle("exit", T_NEAR); Step_AVX(); jmp("loop", T_NEAR); } L("exit"); #ifdef _WIN64 for(int i = 6; i < 16; i++) { vmovdqa(Xmm(i), ptr[rsp + (i - 6) * 16]); } add(rsp, 8 + 10 * 16); pop(r13); pop(r12); pop(rbp); pop(rdi); pop(rsi); pop(rbx); #else mov(rbx, ptr[rsp + _rz_rbx]); if (!m_rip) { mov(r12, ptr[rsp + _rz_r12]); mov(r13, ptr[rsp + _rz_r13]); } pop(rbp); #endif ret(); } void GSDrawScanlineCodeGenerator::Init_AVX() { if(!m_sel.notest) { // int skip = left & 3; mov(ebx, a1.cvt32()); and(a1.cvt32(), 3); // left -= skip; sub(ebx, a1.cvt32()); // int steps = pixels + skip - 4; lea(a0, ptr[a0 + a1 - 4]); // GSVector4i test = m_test[skip] | m_test[7 + (steps & (steps >> 31))]; shl(a1.cvt32(), 4); // * sizeof(m_test[0]) vmovdqa(_test, ptr[a1 + r10]); mov(rax, a0); sar(rax, 63); // GH: 63 to extract the sign of the register and(rax, a0); shl(rax, 4); // * sizeof(m_test[0]) vpor(_test, ptr[rax + r10 + 7 * 16]); } else { mov(ebx, a1.cvt32()); // left xor(a1.cvt32(), a1.cvt32()); // skip lea(a0, ptr[a0 - 4]); // steps } // a0 = steps // a1 = skip // rbx = left // GSVector2i* fza_base = &m_local.gd->fzbr[top]; mov(rax, _rip_global(fzbr)); lea(t1, ptr[rax + a2 * 8]); // GSVector2i* fza_offset = &m_local.gd->fzbc[left >> 2]; mov(rax, _rip_global(fzbc)); lea(t0, ptr[rax + rbx * 2]); if(m_sel.prim != GS_SPRITE_CLASS && (m_sel.fwrite && m_sel.fge || m_sel.zb) || m_sel.fb && (m_sel.edge || m_sel.tfx != TFX_NONE || m_sel.iip)) { // a1 = &m_local.d[skip] // note a1 was (skip << 4) // FIXME //lea(a1, ptr[a1 * 8 + _m_local + offsetof(GSScanlineLocalData, d)]); lea(rax, _rip_local(d)); lea(a1, ptr[rax + a1 * 8]); } if(m_sel.prim != GS_SPRITE_CLASS) { if(m_sel.fwrite && m_sel.fge || m_sel.zb) { vmovaps(xmm0, ptr[a3 + offsetof(GSVertexSW, p)]); // v.p if(m_sel.fwrite && m_sel.fge) { // f = GSVector4i(vp).zzzzh().zzzz().add16(m_local.d[skip].f); vcvttps2dq(_f, xmm0); vpshufhw(_f, _f, _MM_SHUFFLE(2, 2, 2, 2)); vpshufd(_f, _f, _MM_SHUFFLE(2, 2, 2, 2)); vpaddw(_f, ptr[a1 + 16 * 6]); } if(m_sel.zb) { // z = vp.zzzz() + m_local.d[skip].z; vshufps(_z, xmm0, xmm0, _MM_SHUFFLE(2, 2, 2, 2)); vaddps(_z, ptr[a1]); } } } else { if(m_sel.ztest) { vmovdqa(_z, _rip_local(p.z)); } if(m_sel.fwrite && m_sel.fge) vmovdqa(_f, _rip_local(p.f)); } if(m_sel.fb) { if(m_sel.edge || m_sel.tfx != TFX_NONE) { vmovaps(xmm0, ptr[a3 + offsetof(GSVertexSW, t)]); // v.t } if(m_sel.edge) { // m_local.temp.cov = GSVector4i::cast(v.t).zzzzh().wwww().srl16(9); vpshufhw(xmm1, xmm0, _MM_SHUFFLE(2, 2, 2, 2)); vpshufd(xmm1, xmm1, _MM_SHUFFLE(3, 3, 3, 3)); vpsrlw(xmm1, 9); #ifdef _WIN64 vmovdqa(_rip_local(temp.cov), xmm1); #else vmovdqa(ptr[rsp + _rz_cov], xmm1); #endif } if(m_sel.tfx != TFX_NONE) { // a1 = &m_local.d[skip] if(m_sel.fst) { // GSVector4i vti(vt); vcvttps2dq(xmm0, xmm0); // s = vti.xxxx() + m_local.d[skip].s; // t = vti.yyyy(); if(!sprite) t += m_local.d[skip].t; vpshufd(_s, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vpshufd(_t, xmm0, _MM_SHUFFLE(1, 1, 1, 1)); vpaddd(_s, ptr[a1 + offsetof(GSScanlineLocalData::skip, s)]); if(m_sel.prim != GS_SPRITE_CLASS || m_sel.mmin) { vpaddd(_t, ptr[a1 + offsetof(GSScanlineLocalData::skip, t)]); } else if(m_sel.ltf) { vpshuflw(xmm7, _t, _MM_SHUFFLE(2, 2, 0, 0)); vpshufhw(xmm7, xmm7, _MM_SHUFFLE(2, 2, 0, 0)); vpsrlw(xmm7, 12); } } else { // s = vt.xxxx() + m_local.d[skip].s; // t = vt.yyyy() + m_local.d[skip].t; // q = vt.zzzz() + m_local.d[skip].q; vshufps(_s, xmm0, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vshufps(_t, xmm0, xmm0, _MM_SHUFFLE(1, 1, 1, 1)); vshufps(_q, xmm0, xmm0, _MM_SHUFFLE(2, 2, 2, 2)); vaddps(_s, ptr[a1 + offsetof(GSScanlineLocalData::skip, s)]); vaddps(_t, ptr[a1 + offsetof(GSScanlineLocalData::skip, t)]); vaddps(_q, ptr[a1 + offsetof(GSScanlineLocalData::skip, q)]); } } if(!(m_sel.tfx == TFX_DECAL && m_sel.tcc)) { if(m_sel.iip) { // GSVector4i vc = GSVector4i(v.c); vcvttps2dq(xmm0, ptr[a3 + offsetof(GSVertexSW, c)]); // v.c // vc = vc.upl16(vc.zwxy()); vpshufd(xmm1, xmm0, _MM_SHUFFLE(1, 0, 3, 2)); vpunpcklwd(xmm0, xmm1); // rb = vc.xxxx().add16(m_local.d[skip].rb); // ga = vc.zzzz().add16(m_local.d[skip].ga); vpshufd(_f_rb, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vpshufd(_f_ga, xmm0, _MM_SHUFFLE(2, 2, 2, 2)); vpaddw(_f_rb, ptr[a1 + offsetof(GSScanlineLocalData::skip, rb)]); vpaddw(_f_ga, ptr[a1 + offsetof(GSScanlineLocalData::skip, ga)]); } else { vmovdqa(_f_rb, _rip_local(c.rb)); vmovdqa(_f_ga, _rip_local(c.ga)); } vmovdqa(_rb, _f_rb); vmovdqa(_ga, _f_ga); } } if(m_sel.fwrite && m_sel.fpsm == 2 && m_sel.dthe) { // On linux, a2 is edx which will be used for fzm // In all case, it will require a mov in dthe code, so let's keep the value on the stack #ifdef _WIN64 ASSERT(0); #else mov(ptr[rsp + _rz_top], a2); #endif } mov(_m_local__gd__vm, _rip_global(vm)); if(m_sel.fb && m_sel.tfx != TFX_NONE) mov(_m_local__gd__tex, _rip_global(tex)); } void GSDrawScanlineCodeGenerator::Step_AVX() { // steps -= 4; sub(a0, 4); // fza_offset++; add(t0, 8); if(m_sel.prim != GS_SPRITE_CLASS) { // z += m_local.d4.z; if(m_sel.zb) { vaddps(_z, _rip_local(d4.z)); } // f = f.add16(m_local.d4.f); if(m_sel.fwrite && m_sel.fge) { vpaddw(_f, _rip_local(d4.f)); } } else { if(m_sel.ztest) { } } if(m_sel.fb) { if(m_sel.tfx != TFX_NONE) { if(m_sel.fst) { // GSVector4i st = m_local.d4.st; // si += st.xxxx(); // if(!sprite) ti += st.yyyy(); vmovdqa(xmm0, _rip_local(d4.stq)); vpshufd(xmm1, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vpaddd(_s, xmm1); if(m_sel.prim != GS_SPRITE_CLASS || m_sel.mmin) { vpshufd(xmm1, xmm0, _MM_SHUFFLE(1, 1, 1, 1)); vpaddd(_t, xmm1); } } else { // GSVector4 stq = m_local.d4.stq; // s += stq.xxxx(); // t += stq.yyyy(); // q += stq.zzzz(); vmovaps(xmm0, _rip_local(d4.stq)); vshufps(xmm1, xmm0, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vshufps(xmm2, xmm0, xmm0, _MM_SHUFFLE(1, 1, 1, 1)); vshufps(xmm3, xmm0, xmm0, _MM_SHUFFLE(2, 2, 2, 2)); vaddps(_s, xmm1); vaddps(_t, xmm2); vaddps(_q, xmm3); } } if(!(m_sel.tfx == TFX_DECAL && m_sel.tcc)) { if(m_sel.iip) { // GSVector4i c = m_local.d4.c; // rb = rb.add16(c.xxxx()); // ga = ga.add16(c.yyyy()); vmovdqa(xmm0, _rip_local(d4.c)); vpshufd(xmm1, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vpshufd(xmm2, xmm0, _MM_SHUFFLE(1, 1, 1, 1)); vpaddw(_f_rb, xmm1); vpaddw(_f_ga, xmm2); // FIXME: color may underflow and roll over at the end of the line, if decreasing vpxor(xmm0, xmm0); vpmaxsw(_f_rb, xmm0); vpmaxsw(_f_ga, xmm0); } else { if(m_sel.tfx == TFX_NONE) { } } vmovdqa(_rb, _f_rb); vmovdqa(_ga, _f_ga); } } if(!m_sel.notest) { // test = m_test[7 + (steps & (steps >> 31))]; mov(rax, a0); sar(rax, 63); // GH: 63 to extract the sign of the register and(rax, a0); shl(rax, 4); vmovdqa(_test, ptr[rax + r10 + 7 * 16]); } } void GSDrawScanlineCodeGenerator::TestZ_AVX(const Xmm& temp1, const Xmm& temp2) { if(!m_sel.zb) { return; } // int za = fza_base.y + fza_offset->y; mov(ebp, dword[t1 + 4]); add(ebp, dword[t0 + 4]); and(ebp, HALF_VM_SIZE - 1); // GSVector4i zs = zi; if(m_sel.prim != GS_SPRITE_CLASS) { if(m_sel.zoverflow) { // zs = (GSVector4i(z * 0.5f) << 1) | (GSVector4i(z) & GSVector4i::x00000001()); mov(rax, (size_t)&GSVector4::m_half); vbroadcastss(xmm0, ptr[rax]); vmulps(xmm0, _z); vcvttps2dq(xmm0, xmm0); vpslld(xmm0, 1); vcvttps2dq(xmm1, _z); vpcmpeqd(xmm2, xmm2); vpsrld(xmm2, 31); vpand(xmm1, xmm2); vpor(xmm0, xmm1); } else { // zs = GSVector4i(z); vcvttps2dq(xmm0, _z); } if(m_sel.zwrite) { #ifdef _WIN64 vmovdqa(_rip_local(temp.zs), xmm0); #else vmovdqa(ptr[rsp + _rz_zs], xmm0); #endif } } else { movdqa(xmm0, _z); } if(m_sel.ztest) { ReadPixel_AVX(xmm1, rbp); if(m_sel.zwrite && m_sel.zpsm < 2) { #ifdef _WIN64 vmovdqa(_rip_local(temp.zd), xmm1); #else vmovdqa(ptr[rsp + _rz_zd], xmm1); #endif } // zd &= 0xffffffff >> m_sel.zpsm * 8; if(m_sel.zpsm) { vpslld(xmm1, m_sel.zpsm * 8); vpsrld(xmm1, m_sel.zpsm * 8); } if(m_sel.zoverflow || m_sel.zpsm == 0) { // GSVector4i o = GSVector4i::x80000000(); vpcmpeqd(xmm2, xmm2); vpslld(xmm2, 31); // GSVector4i zso = zs - o; // GSVector4i zdo = zd - o; vpsubd(xmm0, xmm2); vpsubd(xmm1, xmm2); } switch(m_sel.ztst) { case ZTST_GEQUAL: // test |= zso < zdo; // ~(zso >= zdo) vpcmpgtd(xmm1, xmm0); vpor(_test, xmm1); break; case ZTST_GREATER: // TODO: tidus hair and chocobo wings only appear fully when this is tested as ZTST_GEQUAL // test |= zso <= zdo; // ~(zso > zdo) vpcmpgtd(xmm0, xmm1); vpcmpeqd(xmm2, xmm2); vpxor(xmm0, xmm2); vpor(_test, xmm0); break; } alltrue(); } } void GSDrawScanlineCodeGenerator::SampleTexture_AVX() { if(!m_sel.fb || m_sel.tfx == TFX_NONE) { return; } if(!m_sel.fst) { vrcpps(xmm0, _q); vmulps(xmm4, _s, xmm0); vmulps(xmm5, _t, xmm0); vcvttps2dq(xmm4, xmm4); vcvttps2dq(xmm5, xmm5); if(m_sel.ltf) { // u -= 0x8000; // v -= 0x8000; mov(eax, 0x8000); vmovd(xmm0, eax); vpshufd(xmm0, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); vpsubd(xmm4, xmm0); vpsubd(xmm5, xmm0); } } else { vmovdqa(xmm4, _s); vmovdqa(xmm5, _t); } if(m_sel.ltf) { // GSVector4i uf = u.xxzzlh().srl16(12); vpshuflw(xmm6, xmm4, _MM_SHUFFLE(2, 2, 0, 0)); vpshufhw(xmm6, xmm6, _MM_SHUFFLE(2, 2, 0, 0)); vpsrlw(xmm6, 12); if(m_sel.prim != GS_SPRITE_CLASS) { // GSVector4i vf = v.xxzzlh().srl16(12); vpshuflw(xmm7, xmm5, _MM_SHUFFLE(2, 2, 0, 0)); vpshufhw(xmm7, xmm7, _MM_SHUFFLE(2, 2, 0, 0)); vpsrlw(xmm7, 12); } } // GSVector4i uv0 = u.sra32(16).ps32(v.sra32(16)); vpsrad(xmm4, 16); vpsrad(xmm5, 16); vpackssdw(xmm4, xmm5); if(m_sel.ltf) { // GSVector4i uv1 = uv0.add16(GSVector4i::x0001()); vpcmpeqd(xmm0, xmm0); vpsrlw(xmm0, 15); vpaddw(xmm5, xmm4, xmm0); // uv0 = Wrap(uv0); // uv1 = Wrap(uv1); Wrap_AVX(xmm4, xmm5); } else { // uv0 = Wrap(uv0); Wrap_AVX(xmm4); } // xmm4 = uv0 // xmm5 = uv1 (ltf) // xmm6 = uf // xmm7 = vf // GSVector4i x0 = uv0.upl16(); // GSVector4i y0 = uv0.uph16() << tw; vpxor(xmm0, xmm0); vpunpcklwd(xmm2, xmm4, xmm0); vpunpckhwd(xmm3, xmm4, xmm0); vpslld(xmm3, m_sel.tw + 3); // xmm0 = 0 // xmm2 = x0 // xmm3 = y0 // xmm5 = uv1 (ltf) // xmm6 = uf // xmm7 = vf if(m_sel.ltf) { // GSVector4i x1 = uv1.upl16(); // GSVector4i y1 = uv1.uph16() << tw; vpunpcklwd(xmm4, xmm5, xmm0); vpunpckhwd(xmm5, xmm5, xmm0); vpslld(xmm5, m_sel.tw + 3); // xmm2 = x0 // xmm3 = y0 // xmm4 = x1 // xmm5 = y1 // xmm6 = uf // xmm7 = vf // GSVector4i addr00 = y0 + x0; // GSVector4i addr01 = y0 + x1; // GSVector4i addr10 = y1 + x0; // GSVector4i addr11 = y1 + x1; vpaddd(xmm0, xmm3, xmm2); vpaddd(xmm1, xmm3, xmm4); vpaddd(xmm2, xmm5, xmm2); vpaddd(xmm3, xmm5, xmm4); // xmm0 = addr00 // xmm1 = addr01 // xmm2 = addr10 // xmm3 = addr11 // xmm6 = uf // xmm7 = vf // c00 = addr00.gather32_32((const uint32/uint8*)tex[, clut]); // c01 = addr01.gather32_32((const uint32/uint8*)tex[, clut]); // c10 = addr10.gather32_32((const uint32/uint8*)tex[, clut]); // c11 = addr11.gather32_32((const uint32/uint8*)tex[, clut]); ReadTexel_AVX(4, 0); // xmm0 = c10 // xmm1 = c11 // xmm4 = c00 // xmm5 = c01 // xmm6 = uf // xmm7 = vf // GSVector4i rb00 = c00 & mask; // GSVector4i ga00 = (c00 >> 8) & mask; split16_2x8(xmm2, xmm3, xmm4); // GSVector4i rb01 = c01 & mask; // GSVector4i ga01 = (c01 >> 8) & mask; split16_2x8(xmm4, xmm5, xmm5); // xmm0 = c10 // xmm1 = c11 // xmm2 = rb00 // xmm3 = ga00 // xmm4 = rb01 // xmm5 = ga01 // xmm6 = uf // xmm7 = vf // rb00 = rb00.lerp16_4(rb01, uf); // ga00 = ga00.lerp16_4(ga01, uf); lerp16_4(xmm4, xmm2, xmm6); lerp16_4(xmm5, xmm3, xmm6); // xmm0 = c10 // xmm1 = c11 // xmm4 = rb00 // xmm5 = ga00 // xmm6 = uf // xmm7 = vf // GSVector4i rb10 = c10 & mask; // GSVector4i ga10 = (c10 >> 8) & mask; split16_2x8(xmm2, xmm3, xmm0); // GSVector4i rb11 = c11 & mask; // GSVector4i ga11 = (c11 >> 8) & mask; split16_2x8(xmm0, xmm1, xmm1); // xmm0 = rb11 // xmm1 = ga11 // xmm2 = rb10 // xmm3 = ga10 // xmm4 = rb00 // xmm5 = ga00 // xmm6 = uf // xmm7 = vf // rb10 = rb10.lerp16_4(rb11, uf); // ga10 = ga10.lerp16_4(ga11, uf); lerp16_4(xmm0, xmm2, xmm6); lerp16_4(xmm1, xmm3, xmm6); // xmm0 = rb10 // xmm1 = ga10 // xmm4 = rb00 // xmm5 = ga00 // xmm7 = vf // rb00 = rb00.lerp16_4(rb10, vf); // ga00 = ga00.lerp16_4(ga10, vf); lerp16_4(xmm0, xmm4, xmm7); lerp16_4(xmm1, xmm5, xmm7); // FIXME not ideal (but allow different source in ReadTexel and less register dependency) vmovdqa(xmm2, xmm0); vmovdqa(xmm3, xmm1); } else { // GSVector4i addr00 = y0 + x0; vpaddd(xmm0, xmm3, xmm2); // c00 = addr00.gather32_32((const uint32/uint8*)tex[, clut]); ReadTexel_AVX(1, 0); // GSVector4i mask = GSVector4i::x00ff(); // c[0] = c00 & mask; // c[1] = (c00 >> 8) & mask; split16_2x8(_rb, _ga, xmm4); } // xmm2 = rb // xmm3 = ga } void GSDrawScanlineCodeGenerator::Wrap_AVX(const Xmm& uv) { // xmm0, xmm1, xmm2, xmm3 = free int wms_clamp = ((m_sel.wms + 1) >> 1) & 1; int wmt_clamp = ((m_sel.wmt + 1) >> 1) & 1; int region = ((m_sel.wms | m_sel.wmt) >> 1) & 1; if(wms_clamp == wmt_clamp) { if(wms_clamp) { if(region) { vpmaxsw(uv, _rip_global(t.min)); } else { vpxor(xmm0, xmm0); vpmaxsw(uv, xmm0); } vpminsw(uv, _rip_global(t.max)); } else { vpand(uv, _rip_global(t.min)); if(region) { vpor(uv, _rip_global(t.max)); } } } else { vmovdqa(xmm2, _rip_global(t.min)); vmovdqa(xmm3, _rip_global(t.max)); vmovdqa(xmm0, _rip_global(t.mask)); // GSVector4i repeat = (t & m_local.gd->t.min) | m_local.gd->t.max; vpand(xmm1, uv, xmm2); if(region) { vpor(xmm1, xmm3); } // GSVector4i clamp = t.sat_i16(m_local.gd->t.min, m_local.gd->t.max); vpmaxsw(uv, xmm2); vpminsw(uv, xmm3); // clamp.blend8(repeat, m_local.gd->t.mask); vpblendvb(uv, xmm1, xmm0); } } void GSDrawScanlineCodeGenerator::Wrap_AVX(const Xmm& uv0, const Xmm& uv1) { // xmm0, xmm1, xmm2, xmm3 = free int wms_clamp = ((m_sel.wms + 1) >> 1) & 1; int wmt_clamp = ((m_sel.wmt + 1) >> 1) & 1; int region = ((m_sel.wms | m_sel.wmt) >> 1) & 1; if(wms_clamp == wmt_clamp) { if(wms_clamp) { if(region) { vmovdqa(xmm0, _rip_global(t.min)); vpmaxsw(uv0, xmm0); vpmaxsw(uv1, xmm0); } else { vpxor(xmm0, xmm0); vpmaxsw(uv0, xmm0); vpmaxsw(uv1, xmm0); } vmovdqa(xmm0, _rip_global(t.max)); vpminsw(uv0, xmm0); vpminsw(uv1, xmm0); } else { vmovdqa(xmm0, _rip_global(t.min)); vpand(uv0, xmm0); vpand(uv1, xmm0); if(region) { vmovdqa(xmm0, _rip_global(t.max)); vpor(uv0, xmm0); vpor(uv1, xmm0); } } } else { vmovdqa(xmm2, _rip_global(t.min)); vmovdqa(xmm3, _rip_global(t.max)); vmovdqa(xmm0, _rip_global(t.mask)); // uv0 // GSVector4i repeat = (t & m_local.gd->t.min) | m_local.gd->t.max; vpand(xmm1, uv0, xmm2); if(region) { vpor(xmm1, xmm3); } // GSVector4i clamp = t.sat_i16(m_local.gd->t.min, m_local.gd->t.max); vpmaxsw(uv0, xmm2); vpminsw(uv0, xmm3); // clamp.blend8(repeat, m_local.gd->t.mask); vpblendvb(uv0, xmm1, xmm0); // uv1 // GSVector4i repeat = (t & m_local.gd->t.min) | m_local.gd->t.max; vpand(xmm1, uv1, xmm2); if(region) { vpor(xmm1, xmm3); } // GSVector4i clamp = t.sat_i16(m_local.gd->t.min, m_local.gd->t.max); vpmaxsw(uv1, xmm2); vpminsw(uv1, xmm3); // clamp.blend8(repeat, m_local.gd->t.mask); vpblendvb(uv1, xmm1, xmm0); } } void GSDrawScanlineCodeGenerator::SampleTextureLOD_AVX() { } void GSDrawScanlineCodeGenerator::WrapLOD_AVX(const Xmm& uv) { } void GSDrawScanlineCodeGenerator::WrapLOD_AVX(const Xmm& uv0, const Xmm& uv1) { } void GSDrawScanlineCodeGenerator::AlphaTFX_AVX() { if(!m_sel.fb) { return; } switch(m_sel.tfx) { case TFX_MODULATE: // gat = gat.modulate16<1>(ga).clamp8(); modulate16(_ga, _f_ga, 1); clamp16(_ga, xmm0); // if(!tcc) gat = gat.mix16(ga.srl16(7)); if(!m_sel.tcc) { vpsrlw(xmm1, _f_ga, 7); mix16(_ga, xmm1, xmm0); } break; case TFX_DECAL: // if(!tcc) gat = gat.mix16(ga.srl16(7)); if(!m_sel.tcc) { vpsrlw(xmm1, _f_ga, 7); mix16(_ga, xmm1, xmm0); } break; case TFX_HIGHLIGHT: // gat = gat.mix16(!tcc ? ga.srl16(7) : gat.addus8(ga.srl16(7))); vpsrlw(xmm1, _f_ga, 7); if(m_sel.tcc) { vpaddusb(xmm1, _ga); } mix16(_ga, xmm1, xmm0); break; case TFX_HIGHLIGHT2: // if(!tcc) gat = gat.mix16(ga.srl16(7)); if(!m_sel.tcc) { vpsrlw(xmm1, _f_ga, 7); mix16(_ga, xmm1, xmm0); } break; case TFX_NONE: // gat = iip ? ga.srl16(7) : ga; if(m_sel.iip) { vpsrlw(_ga, _f_ga, 7); } break; } if(m_sel.aa1) { // gs_user figure 3-2: anti-aliasing after tfx, before tests, modifies alpha // FIXME: bios config screen cubes if(!m_sel.abe) { // a = cov if(m_sel.edge) { #ifdef _WIN64 vmovdqa(xmm0, _rip_local(temp.cov)); #else vmovdqa(xmm0, ptr[rsp + _rz_cov]); #endif } else { vpcmpeqd(xmm0, xmm0); vpsllw(xmm0, 15); vpsrlw(xmm0, 8); } mix16(_ga, xmm0, xmm1); } else { // a = a == 0x80 ? cov : a vpcmpeqd(xmm0, xmm0); vpsllw(xmm0, 15); vpsrlw(xmm0, 8); if(m_sel.edge) { #ifdef _WIN64 vmovdqa(xmm1, _rip_local(temp.cov)); #else vmovdqa(xmm1, ptr[rsp + _rz_cov]); #endif } else { vmovdqa(xmm1, xmm0); } vpcmpeqw(xmm0, _ga); vpsrld(xmm0, 16); vpslld(xmm0, 16); vpblendvb(_ga, xmm1, xmm0); } } } void GSDrawScanlineCodeGenerator::ReadMask_AVX() { if(m_sel.fwrite) { vmovdqa(_fm, _rip_global(fm)); } if(m_sel.zwrite) { vmovdqa(_zm, _rip_global(zm)); } } void GSDrawScanlineCodeGenerator::TestAlpha_AVX() { switch(m_sel.atst) { case ATST_NEVER: // t = GSVector4i::xffffffff(); vpcmpeqd(xmm1, xmm1); break; case ATST_ALWAYS: return; case ATST_LESS: case ATST_LEQUAL: // t = (ga >> 16) > m_local.gd->aref; vpsrld(xmm1, _ga, 16); vpcmpgtd(xmm1, _rip_global(aref)); break; case ATST_EQUAL: // t = (ga >> 16) != m_local.gd->aref; vpsrld(xmm1, _ga, 16); vpcmpeqd(xmm1, _rip_global(aref)); vpcmpeqd(xmm0, xmm0); vpxor(xmm1, xmm0); break; case ATST_GEQUAL: case ATST_GREATER: // t = (ga >> 16) < m_local.gd->aref; vpsrld(xmm0, _ga, 16); vmovdqa(xmm1, _rip_global(aref)); vpcmpgtd(xmm1, xmm0); break; case ATST_NOTEQUAL: // t = (ga >> 16) == m_local.gd->aref; vpsrld(xmm1, _ga, 16); vpcmpeqd(xmm1, _rip_global(aref)); break; } switch(m_sel.afail) { case AFAIL_KEEP: // test |= t; vpor(_test, xmm1); alltrue(); break; case AFAIL_FB_ONLY: // zm |= t; vpor(_zm, xmm1); break; case AFAIL_ZB_ONLY: // fm |= t; vpor(_fm, xmm1); break; case AFAIL_RGB_ONLY: // zm |= t; vpor(_zm, xmm1); // fm |= t & GSVector4i::xff000000(); vpsrld(xmm1, 24); vpslld(xmm1, 24); vpor(_fm, xmm1); break; } } void GSDrawScanlineCodeGenerator::ColorTFX_AVX() { if(!m_sel.fwrite) { return; } switch(m_sel.tfx) { case TFX_MODULATE: // rbt = rbt.modulate16<1>(rb).clamp8(); modulate16(_rb, _f_rb, 1); clamp16(_rb, xmm0); break; case TFX_DECAL: break; case TFX_HIGHLIGHT: case TFX_HIGHLIGHT2: // gat = gat.modulate16<1>(ga).add16(af).clamp8().mix16(gat); vmovdqa(xmm1, _ga); modulate16(_ga, _f_ga, 1); vpshuflw(xmm6, _f_ga, _MM_SHUFFLE(3, 3, 1, 1)); vpshufhw(xmm6, xmm6, _MM_SHUFFLE(3, 3, 1, 1)); vpsrlw(xmm6, 7); vpaddw(_ga, xmm6); clamp16(_ga, xmm0); mix16(_ga, xmm1, xmm0); // rbt = rbt.modulate16<1>(rb).add16(af).clamp8(); modulate16(_rb, _f_rb, 1); vpaddw(_rb, xmm6); clamp16(_rb, xmm0); break; case TFX_NONE: // rbt = iip ? rb.srl16(7) : rb; if(m_sel.iip) { vpsrlw(_rb, _f_rb, 7); } break; } } void GSDrawScanlineCodeGenerator::Fog_AVX() { if(!m_sel.fwrite || !m_sel.fge) { return; } // rb = m_local.gd->frb.lerp16<0>(rb, f); // ga = m_local.gd->fga.lerp16<0>(ga, f).mix16(ga); vmovdqa(xmm6, _ga); vmovdqa(xmm0, _rip_global(frb)); vmovdqa(xmm1, _rip_global(fga)); lerp16(_rb, xmm0, _f, 0); lerp16(_ga, xmm1, _f, 0); mix16(_ga, xmm6, _f); } void GSDrawScanlineCodeGenerator::ReadFrame_AVX() { if(!m_sel.fb) { return; } // int fa = fza_base.x + fza_offset->x; mov(ebx, dword[t1]); add(ebx, dword[t0]); and(ebx, HALF_VM_SIZE - 1); if(!m_sel.rfb) { return; } ReadPixel_AVX(_fd, rbx); } void GSDrawScanlineCodeGenerator::TestDestAlpha_AVX() { if(!m_sel.date || m_sel.fpsm != 0 && m_sel.fpsm != 2) { return; } // test |= ((fd [<< 16]) ^ m_local.gd->datm).sra32(31); if(m_sel.datm) { if(m_sel.fpsm == 2) { vpxor(xmm0, xmm0); //vpsrld(xmm1, _fd, 15); vpslld(xmm1, _fd, 16); vpsrad(xmm1, 31); vpcmpeqd(xmm1, xmm0); } else { vpcmpeqd(xmm0, xmm0); vpxor(xmm1, _fd, xmm0); vpsrad(xmm1, 31); } } else { if(m_sel.fpsm == 2) { vpslld(xmm1, _fd, 16); vpsrad(xmm1, 31); } else { vpsrad(xmm1, _fd, 31); } } vpor(_test, xmm1); alltrue(); } void GSDrawScanlineCodeGenerator::WriteMask_AVX() { if(m_sel.notest) { return; } // fm |= test; // zm |= test; if(m_sel.fwrite) { vpor(_fm, _test); } if(m_sel.zwrite) { vpor(_zm, _test); } // int fzm = ~(fm == GSVector4i::xffffffff()).ps32(zm == GSVector4i::xffffffff()).mask(); vpcmpeqd(xmm1, xmm1); if(m_sel.fwrite && m_sel.zwrite) { vpcmpeqd(xmm0, xmm1, _zm); vpcmpeqd(xmm1, _fm); vpackssdw(xmm1, xmm0); } else if(m_sel.fwrite) { vpcmpeqd(xmm1, _fm); vpackssdw(xmm1, xmm1); } else if(m_sel.zwrite) { vpcmpeqd(xmm1, _zm); vpackssdw(xmm1, xmm1); } vpmovmskb(edx, xmm1); not(edx); } void GSDrawScanlineCodeGenerator::WriteZBuf_AVX() { if(!m_sel.zwrite) { return; } if (m_sel.prim != GS_SPRITE_CLASS) #ifdef _WIN64 vmovdqa(xmm1, _rip_local(temp.zs)); #else vmovdqa(xmm1, ptr[rsp + _rz_zs]); #endif else vmovdqa(xmm1, _rip_local(p.z)); if(m_sel.ztest && m_sel.zpsm < 2) { // zs = zs.blend8(zd, zm); #ifdef _WIN64 vpblendvb(xmm1, _rip_local(temp.zd), _zm); #else vpblendvb(xmm1, ptr[rsp + _rz_zd], _zm); #endif } bool fast = m_sel.ztest ? m_sel.zpsm < 2 : m_sel.zpsm == 0 && m_sel.notest; WritePixel_AVX(xmm1, rbp, dh, fast, m_sel.zpsm, 1); } void GSDrawScanlineCodeGenerator::AlphaBlend_AVX() { if(!m_sel.fwrite) { return; } if(m_sel.abe == 0 && m_sel.aa1 == 0) { return; } const Xmm& _dst_rb = xmm0; const Xmm& _dst_ga = xmm1; if((m_sel.aba != m_sel.abb) && (m_sel.aba == 1 || m_sel.abb == 1 || m_sel.abc == 1) || m_sel.abd == 1) { switch(m_sel.fpsm) { case 0: case 1: // c[2] = fd & mask; // c[3] = (fd >> 8) & mask; split16_2x8(_dst_rb, _dst_ga, _fd); break; case 2: // c[2] = ((fd & 0x7c00) << 9) | ((fd & 0x001f) << 3); // c[3] = ((fd & 0x8000) << 8) | ((fd & 0x03e0) >> 2); vpcmpeqd(xmm15, xmm15); vpsrld(xmm15, 27); // 0x0000001f vpand(_dst_rb, _fd, xmm15); vpslld(_dst_rb, 3); vpslld(xmm15, 10); // 0x00007c00 vpand(xmm5, _fd, xmm15); vpslld(xmm5, 9); vpor(_dst_rb, xmm5); vpsrld(xmm15, 5); // 0x000003e0 vpand(_dst_ga, _fd, xmm15); vpsrld(_dst_ga, 2); vpsllw(xmm15, 10); // 0x00008000 vpand(xmm5, _fd, xmm15); vpslld(xmm5, 8); vpor(_dst_ga, xmm5); break; } } // xmm2, xmm3 = src rb, ga // xmm0, xmm1 = dst rb, ga // xmm5, xmm15 = free if(m_sel.pabe || (m_sel.aba != m_sel.abb) && (m_sel.abb == 0 || m_sel.abd == 0)) { vmovdqa(xmm5, _rb); } if(m_sel.aba != m_sel.abb) { // rb = c[aba * 2 + 0]; switch(m_sel.aba) { case 0: break; case 1: vmovdqa(_rb, _dst_rb); break; case 2: vpxor(_rb, _rb); break; } // rb = rb.sub16(c[abb * 2 + 0]); switch(m_sel.abb) { case 0: vpsubw(_rb, xmm5); break; case 1: vpsubw(_rb, _dst_rb); break; case 2: break; } if(!(m_sel.fpsm == 1 && m_sel.abc == 1)) { // GSVector4i a = abc < 2 ? c[abc * 2 + 1].yywwlh().sll16(7) : m_local.gd->afix; switch(m_sel.abc) { case 0: case 1: vpshuflw(xmm15, m_sel.abc ? _dst_ga : _ga, _MM_SHUFFLE(3, 3, 1, 1)); vpshufhw(xmm15, xmm15, _MM_SHUFFLE(3, 3, 1, 1)); vpsllw(xmm15, 7); break; case 2: vmovdqa(xmm15, _rip_global(afix)); break; } // rb = rb.modulate16<1>(a); modulate16(_rb, xmm15, 1); } // rb = rb.add16(c[abd * 2 + 0]); switch(m_sel.abd) { case 0: vpaddw(_rb, xmm5); break; case 1: vpaddw(_rb, _dst_rb); break; case 2: break; } } else { // rb = c[abd * 2 + 0]; switch(m_sel.abd) { case 0: break; case 1: vmovdqa(_rb, _dst_rb); break; case 2: vpxor(_rb, _rb); break; } } if(m_sel.pabe) { // mask = (c[1] << 8).sra32(31); vpslld(xmm0, _ga, 8); vpsrad(xmm0, 31); // rb = c[0].blend8(rb, mask); vpblendvb(_rb, xmm5, _rb, xmm0); } // xmm0 = pabe mask // xmm3 = src ga // xmm1 = dst ga // xmm2 = rb // xmm15 = a // xmm5 = free vmovdqa(xmm5, _ga); if(m_sel.aba != m_sel.abb) { // ga = c[aba * 2 + 1]; switch(m_sel.aba) { case 0: break; case 1: vmovdqa(_ga, _dst_ga); break; case 2: vpxor(_ga, _ga); break; } // ga = ga.sub16(c[abeb * 2 + 1]); switch(m_sel.abb) { case 0: vpsubw(_ga, xmm5); break; case 1: vpsubw(_ga, _dst_ga); break; case 2: break; } if(!(m_sel.fpsm == 1 && m_sel.abc == 1)) { // ga = ga.modulate16<1>(a); modulate16(_ga, xmm15, 1); } // ga = ga.add16(c[abd * 2 + 1]); switch(m_sel.abd) { case 0: vpaddw(_ga, xmm5); break; case 1: vpaddw(_ga, _dst_ga); break; case 2: break; } } else { // ga = c[abd * 2 + 1]; switch(m_sel.abd) { case 0: break; case 1: vmovdqa(_ga, _dst_ga); break; case 2: vpxor(_ga, _ga); break; } } // xmm0 = pabe mask // xmm5 = src ga // xmm2 = rb // xmm3 = ga // xmm1, xmm15 = free if(m_sel.pabe) { vpsrld(xmm0, 16); // zero out high words to select the source alpha in blend (so it also does mix16) // ga = c[1].blend8(ga, mask).mix16(c[1]); vpblendvb(_ga, xmm5, _ga, xmm0); } else { if(m_sel.fpsm != 1) // TODO: fm == 0xffxxxxxx { mix16(_ga, xmm5, xmm15); } } } void GSDrawScanlineCodeGenerator::WriteFrame_AVX() { if(!m_sel.fwrite) { return; } if(m_sel.fpsm == 2 && m_sel.dthe) { // y = (top & 3) << 5 #ifdef _WIN64 ASSERT(0); #else mov(eax, ptr[rsp + _rz_top]); #endif and(eax, 3); shl(eax, 5); // rb = rb.add16(m_global.dimx[0 + y]); // ga = ga.add16(m_global.dimx[1 + y]); add(rax, _rip_global(dimx)); vpaddw(xmm2, ptr[rax + sizeof(GSVector4i) * 0]); vpaddw(xmm3, ptr[rax + sizeof(GSVector4i) * 1]); } if(m_sel.colclamp == 0) { // c[0] &= 0x00ff00ff; // c[1] &= 0x00ff00ff; vpcmpeqd(xmm15, xmm15); vpsrlw(xmm15, 8); vpand(xmm2, xmm15); vpand(xmm3, xmm15); } // GSVector4i fs = c[0].upl16(c[1]).pu16(c[0].uph16(c[1])); vpunpckhwd(xmm15, xmm2, xmm3); vpunpcklwd(xmm2, xmm3); vpackuswb(xmm2, xmm15); if(m_sel.fba && m_sel.fpsm != 1) { // fs |= 0x80000000; vpcmpeqd(xmm15, xmm15); vpslld(xmm15, 31); vpor(xmm2, xmm15); } // xmm2 = fs // xmm4 = fm // xmm6 = fd if(m_sel.fpsm == 2) { // GSVector4i rb = fs & 0x00f800f8; // GSVector4i ga = fs & 0x8000f800; mov(eax, 0x00f800f8); vmovd(xmm0, eax); vpshufd(xmm0, xmm0, _MM_SHUFFLE(0, 0, 0, 0)); mov(eax, 0x8000f800); vmovd(xmm1, eax); vpshufd(xmm1, xmm1, _MM_SHUFFLE(0, 0, 0, 0)); vpand(xmm0, xmm2); vpand(xmm1, xmm2); // fs = (ga >> 16) | (rb >> 9) | (ga >> 6) | (rb >> 3); vpsrld(xmm2, xmm0, 9); vpsrld(xmm0, 3); vpsrld(xmm3, xmm1, 16); vpsrld(xmm1, 6); vpor(xmm0, xmm1); vpor(xmm2, xmm3); vpor(xmm2, xmm0); } if(m_sel.rfb) { // fs = fs.blend(fd, fm); blend(xmm2, _fd, _fm); // TODO: could be skipped in certain cases, depending on fpsm and fm } bool fast = m_sel.rfb ? m_sel.fpsm < 2 : m_sel.fpsm == 0 && m_sel.notest; WritePixel_AVX(xmm2, rbx, dl, fast, m_sel.fpsm, 0); } void GSDrawScanlineCodeGenerator::ReadPixel_AVX(const Xmm& dst, const Reg64& addr) { vmovq(dst, qword[_m_local__gd__vm + addr * 2]); vmovhps(dst, qword[_m_local__gd__vm + addr * 2 + 8 * 2]); } void GSDrawScanlineCodeGenerator::WritePixel_AVX(const Xmm& src, const Reg64& addr, const Reg8& mask, bool fast, int psm, int fz) { if(m_sel.notest) { if(fast) { vmovq(qword[_m_local__gd__vm + addr * 2], src); vmovhps(qword[_m_local__gd__vm + addr * 2 + 8 * 2], src); } else { WritePixel_AVX(src, addr, 0, psm); WritePixel_AVX(src, addr, 1, psm); WritePixel_AVX(src, addr, 2, psm); WritePixel_AVX(src, addr, 3, psm); } } else { if(fast) { // if(fzm & 0x0f) GSVector4i::storel(&vm16[addr + 0], fs); // if(fzm & 0xf0) GSVector4i::storeh(&vm16[addr + 8], fs); test(mask, 0x0f); je("@f"); vmovq(qword[_m_local__gd__vm + addr * 2], src); L("@@"); test(mask, 0xf0); je("@f"); vmovhps(qword[_m_local__gd__vm + addr * 2 + 8 * 2], src); L("@@"); // vmaskmovps? } else { // if(fzm & 0x03) WritePixel(fpsm, &vm16[addr + 0], fs.extract32<0>()); // if(fzm & 0x0c) WritePixel(fpsm, &vm16[addr + 2], fs.extract32<1>()); // if(fzm & 0x30) WritePixel(fpsm, &vm16[addr + 8], fs.extract32<2>()); // if(fzm & 0xc0) WritePixel(fpsm, &vm16[addr + 10], fs.extract32<3>()); test(mask, 0x03); je("@f"); WritePixel_AVX(src, addr, 0, psm); L("@@"); test(mask, 0x0c); je("@f"); WritePixel_AVX(src, addr, 1, psm); L("@@"); test(mask, 0x30); je("@f"); WritePixel_AVX(src, addr, 2, psm); L("@@"); test(mask, 0xc0); je("@f"); WritePixel_AVX(src, addr, 3, psm); L("@@"); } } } static const int s_offsets[4] = {0, 2, 8, 10}; void GSDrawScanlineCodeGenerator::WritePixel_AVX(const Xmm& src, const Reg64& addr, uint8 i, int psm) { Address dst = ptr[_m_local__gd__vm + addr * 2 + s_offsets[i] * 2]; switch(psm) { case 0: if(i == 0) vmovd(dst, src); else vpextrd(dst, src, i); break; case 1: if(i == 0) vmovd(eax, src); else vpextrd(eax, src, i); xor(eax, dst); and(eax, 0xffffff); xor(dst, eax); break; case 2: vpextrw(eax, src, i * 2); mov(dst, ax); break; } } void GSDrawScanlineCodeGenerator::ReadTexel_AVX(int pixels, int mip_offset) { const int in[] = {0, 1, 2, 3}; const int out[] = {4, 5, 0, 1}; for(int i = 0; i < pixels; i++) { for(int j = 0; j < 4; j++) { ReadTexel_AVX(Xmm(out[i]), Xmm(in[i]), j); } } } void GSDrawScanlineCodeGenerator::ReadTexel_AVX(const Xmm& dst, const Xmm& addr, uint8 i) { const Address& src = m_sel.tlu ? ptr[_m_local__gd__clut + rax * 4] : ptr[_m_local__gd__tex + rax * 4]; // Extract address offset if(i == 0) vmovd(eax, addr); else vpextrd(eax, addr, i); // If clut, load the value as a byte index if(m_sel.tlu) movzx(eax, byte[_m_local__gd__tex + rax]); if(i == 0) vmovd(dst, src); else vpinsrd(dst, src, i); } // Gather example (AVX2). Not faster on Haswell but potentially better on recent CPU // Worst case reduce Icache. // // Current limitation requires 1 extra free register for the mask. // And palette need zero masking. // It is not possible to use same source/destination so linear interpolation must be updated #if 0 void GSDrawScanlineCodeGenerator::ReadTexel_AVX(int pixels, int mip_offset) { const int in[] = {0, 1, 2, 3}; const int out[] = {4, 5, 0, 1}; const int mask[] = {5, 0, 1, 2}; if (m_sel.tlu) { for(int i = 0; i < pixels; i++) { // FIXME can't use same dst and add register Gather4Texel(Xmm(in[i]), _m_local__gd__tex, Xmm(in[i]), Xmm(mask[i])); // FIXME need a memory and could be faster vpslld(Xmm(in[i]), 24); vpsrld(Xmm(in[i]), 24); Gather4Texel(Xmm(out[i]), _m_local__gd__clut, Xmm(in[i]), Xmm(mask[i])); } } else { for(int i = 0; i < pixels; i++) { Gather4Texel(Xmm(out[i]), _m_local__gd__tex, Xmm(in[i]), Xmm(mask[i])); } } } static void Gather4Texel(const Xmm& dst, const Reg64& base, const Xmm& addr, const Xmm& Mask) { //void vpgatherdd(const Xmm& x1, const Address& addr, const Xmm& x2) vpcmpeqd(Mask, Mask); vpgatherdd(dst, ptr[base + addr * 4], Mask); } #endif #endif