#include "stdafx.h" #include "SPUASMJITRecompiler.h" #include "Emu/system_config.h" #include "Emu/IdManager.h" #include "Emu/Cell/timers.hpp" #include "SPUDisAsm.h" #include "SPUThread.h" #include "SPUInterpreter.h" #include "PPUAnalyser.h" #include "Crypto/sha1.h" #include "util/asm.hpp" #include "util/v128.hpp" #include "util/v128sse.hpp" #include "util/sysinfo.hpp" #include #include #define SPU_OFF_128(x, ...) asmjit::x86::oword_ptr(*cpu, offset32(&spu_thread::x, ##__VA_ARGS__)) #define SPU_OFF_64(x, ...) asmjit::x86::qword_ptr(*cpu, offset32(&spu_thread::x, ##__VA_ARGS__)) #define SPU_OFF_32(x, ...) asmjit::x86::dword_ptr(*cpu, offset32(&spu_thread::x, ##__VA_ARGS__)) #define SPU_OFF_16(x, ...) asmjit::x86::word_ptr(*cpu, offset32(&spu_thread::x, ##__VA_ARGS__)) #define SPU_OFF_8(x, ...) asmjit::x86::byte_ptr(*cpu, offset32(&spu_thread::x, ##__VA_ARGS__)) extern const spu_decoder g_spu_interpreter_fast{}; // TODO: avoid const spu_decoder s_spu_decoder; std::unique_ptr spu_recompiler_base::make_asmjit_recompiler() { return std::make_unique(); } spu_recompiler::spu_recompiler() { } void spu_recompiler::init() { // Initialize if necessary if (!m_spurt) { m_spurt = &g_fxo->get(); } } spu_function_t spu_recompiler::compile(spu_program&& _func) { const u32 start0 = _func.entry_point; const auto add_loc = m_spurt->add_empty(std::move(_func)); if (!add_loc) { return nullptr; } if (add_loc->compiled) { return add_loc->compiled; } const spu_program& func = add_loc->data; if (func.entry_point != start0) { // Wait for the duplicate while (!add_loc->compiled) { add_loc->compiled.wait(nullptr); } return add_loc->compiled; } if (auto& cache = g_fxo->get(); cache && g_cfg.core.spu_cache && !add_loc->cached.exchange(1)) { cache.add(func); } { sha1_context ctx; u8 output[20]; sha1_starts(&ctx); sha1_update(&ctx, reinterpret_cast(func.data.data()), func.data.size() * 4); sha1_finish(&ctx, output); be_t hash_start; std::memcpy(&hash_start, output, sizeof(hash_start)); m_hash_start = hash_start; } using namespace asmjit; StringLogger logger; logger.addFlags(FormatFlags::kMachineCode); std::string log; CodeHolder code; code.init(m_asmrt.environment()); x86::Assembler compiler(&code); compiler.addEncodingOptions(EncodingOptions::kOptimizedAlign); this->c = &compiler; if (g_cfg.core.spu_debug && !add_loc->logged.exchange(1)) { // Dump analyser data this->dump(func, log); fs::file(m_spurt->get_cache_path() + "spu.log", fs::write + fs::append).write(log); // Set logger code.setLogger(&logger); } // Initialize args this->cpu = &x86::r13; this->ls = &x86::rbp; this->rip = &x86::r12; this->pc0 = &x86::r15; this->addr = &x86::eax; #ifdef _WIN32 this->arg0 = &x86::rcx; this->arg1 = &x86::rdx; this->qw0 = &x86::r8; this->qw1 = &x86::r9; #else this->arg0 = &x86::rdi; this->arg1 = &x86::rsi; this->qw0 = &x86::rdx; this->qw1 = &x86::rcx; #endif const std::array vec_vars { &x86::xmm0, &x86::xmm1, &x86::xmm2, &x86::xmm3, &x86::xmm4, &x86::xmm5, &x86::xmm6, &x86::xmm7, &x86::xmm8, &x86::xmm9, &x86::xmm10, &x86::xmm11, &x86::xmm12, &x86::xmm13, &x86::xmm14, &x86::xmm15, }; for (u32 i = 0; i < vec_vars.size(); i++) { vec[i] = vec_vars[i]; } label_stop = c->newLabel(); Label label_diff = c->newLabel(); Label label_code = c->newLabel(); std::vector words; u32 words_align = 8; // Start compilation m_pos = func.lower_bound; m_base = func.entry_point; m_size = ::size32(func.data) * 4; const u32 start = m_pos; const u32 end = start + m_size; // Create block labels for (u32 i = 0; i < func.data.size(); i++) { if (func.data[i] && m_block_info[i + start / 4]) { instr_labels[i * 4 + start] = c->newLabel(); } } // Load actual PC and check status c->sub(x86::rsp, 0x28); c->mov(pc0->r32(), SPU_OFF_32(pc)); c->cmp(SPU_OFF_32(state), 0); c->jnz(label_stop); if (g_cfg.core.spu_prof && g_cfg.core.spu_verification) { c->mov(x86::rax, m_hash_start & -0xffff); c->mov(SPU_OFF_64(block_hash), x86::rax); } if (utils::has_avx()) { // How to check dirty AVX state //c->pxor(x86::xmm0, x86::xmm0); //c->vptest(x86::ymm0, x86::ymm0); //c->jnz(label_stop); } // Get bit mask of valid code words for a given range (up to 128 bytes) auto get_code_mask = [&](u32 starta, u32 enda) -> u32 { u32 result = 0; for (u32 addr = starta, m = 1; addr < enda && m; addr += 4, m <<= 1) { // Filter out if out of range, or is a hole if (addr >= start && addr < end && func.data[(addr - start) / 4]) { result |= m; } } return result; }; // Check code u32 starta = start; // Skip holes at the beginning (giga only) for (u32 j = start; j < end; j += 4) { if (!func.data[(j - start) / 4]) { starta += 4; } else { break; } } auto get_pc_ptr = [&]() { // Get data start address if (starta != m_base) { c->lea(x86::rax, get_pc(starta)); c->and_(x86::eax, 0x3fffc); return x86::qword_ptr(*ls, x86::rax); } else { return x86::qword_ptr(*ls, *pc0); } }; if (!g_cfg.core.spu_verification) { // Disable check (unsafe) if (utils::has_avx()) { c->vzeroupper(); } } else if (m_size == 8) { c->mov(x86::rax, static_cast(func.data[1]) << 32 | func.data[0]); c->cmp(x86::rax, x86::qword_ptr(*ls, *pc0)); c->jnz(label_diff); if (utils::has_avx()) { c->vzeroupper(); } } else if (m_size == 4) { c->cmp(x86::dword_ptr(*ls, *pc0), func.data[0]); c->jnz(label_diff); if (utils::has_avx()) { c->vzeroupper(); } } else if (utils::has_avx512() && false) { // AVX-512 optimized check using 512-bit registers (disabled) words_align = 64; const u32 starta = start & -64; const u32 enda = utils::align(end, 64); const u32 sizea = (enda - starta) / 64; ensure(sizea); // Initialize pointers c->lea(x86::rax, x86::qword_ptr(label_code)); u32 code_off = 0; u32 ls_off = -8192; for (u32 j = starta; j < enda; j += 64) { const u32 cmask = get_code_mask(j, j + 64); if (cmask == 0) [[unlikely]] { continue; } const bool first = ls_off == u32{} - 8192; // Ensure small distance for disp8*N if (j - ls_off >= 8192) { c->lea(*qw1, x86::qword_ptr(*ls, j)); ls_off = j; } if (code_off >= 8192) { c->lea(x86::rax, x86::qword_ptr(x86::rax, 8192)); code_off -= 8192; } if (cmask != 0xffff) { // Generate k-mask for the block Label label = c->newLabel(); c->kmovw(x86::k7, x86::word_ptr(label)); consts.emplace_back([=, this] { c->bind(label); c->dq(cmask); }); c->setExtraReg(x86::k7); c->z().vmovdqa32(x86::zmm0, x86::zmmword_ptr(*qw1, j - ls_off)); } else { c->vmovdqa32(x86::zmm0, x86::zmmword_ptr(*qw1, j - ls_off)); } if (first) { c->vpcmpud(x86::k1, x86::zmm0, x86::zmmword_ptr(x86::rax, code_off), 4); } else { c->vpcmpud(x86::k3, x86::zmm0, x86::zmmword_ptr(x86::rax, code_off), 4); c->korw(x86::k1, x86::k3, x86::k1); } for (u32 i = j; i < j + 64; i += 4) { words.push_back(i >= start && i < end ? func.data[(i - start) / 4] : 0); } code_off += 64; } c->ktestw(x86::k1, x86::k1); c->jnz(label_diff); c->vzeroupper(); } else if (0 && utils::has_avx512()) { // AVX-512 optimized check using 256-bit registers words_align = 32; const u32 starta = start & -32; const u32 enda = utils::align(end, 32); const u32 sizea = (enda - starta) / 32; ensure(sizea); if (sizea == 1) { const u32 cmask = get_code_mask(starta, enda); if (cmask == 0xff) { c->vmovdqa(x86::ymm0, x86::ymmword_ptr(*ls, starta)); } else { c->vpxor(x86::ymm0, x86::ymm0, x86::ymm0); c->vpblendd(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta), cmask); } c->vpxor(x86::ymm0, x86::ymm0, x86::ymmword_ptr(label_code)); c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); for (u32 i = starta; i < enda; i += 4) { words.push_back(i >= start && i < end ? func.data[(i - start) / 4] : 0); } } else if (sizea == 2 && (end - start) <= 32) { const u32 cmask0 = get_code_mask(starta, starta + 32); const u32 cmask1 = get_code_mask(starta + 32, enda); c->vpxor(x86::ymm0, x86::ymm0, x86::ymm0); c->vpblendd(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta), cmask0); c->vpblendd(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta + 32), cmask1); c->vpxor(x86::ymm0, x86::ymm0, x86::ymmword_ptr(label_code)); c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); for (u32 i = starta; i < starta + 32; i += 4) { words.push_back(i >= start ? func.data[(i - start) / 4] : i + 32 < end ? func.data[(i + 32 - start) / 4] : 0); } } else { bool xmm2z = false; // Initialize pointers c->lea(x86::rax, x86::qword_ptr(label_code)); u32 code_off = 0; u32 ls_off = -4096; for (u32 j = starta; j < enda; j += 32) { const u32 cmask = get_code_mask(j, j + 32); if (cmask == 0) [[unlikely]] { continue; } const bool first = ls_off == u32{0} - 4096; // Ensure small distance for disp8*N if (j - ls_off >= 4096) { c->lea(*qw1, x86::qword_ptr(*ls, j)); ls_off = j; } if (code_off >= 4096) { c->lea(x86::rax, x86::qword_ptr(x86::rax, 4096)); code_off -= 4096; } if (cmask != 0xff) { if (!xmm2z) { c->vpxor(x86::xmm2, x86::xmm2, x86::xmm2); xmm2z = true; } c->vpblendd(x86::ymm1, x86::ymm2, x86::ymmword_ptr(*qw1, j - ls_off), cmask); } else { c->vmovdqa32(x86::ymm1, x86::ymmword_ptr(*qw1, j - ls_off)); } // Perform bitwise comparison and accumulate if (first) { c->vpxor(x86::ymm0, x86::ymm1, x86::ymmword_ptr(x86::rax, code_off)); } else { c->vpternlogd(x86::ymm0, x86::ymm1, x86::ymmword_ptr(x86::rax, code_off), 0xf6 /* orAxorBC */); } for (u32 i = j; i < j + 32; i += 4) { words.push_back(i >= start && i < end ? func.data[(i - start) / 4] : 0); } code_off += 32; } c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); } c->vzeroupper(); } else if (0 && utils::has_avx()) { // Mainstream AVX words_align = 32; const u32 starta = start & -32; const u32 enda = utils::align(end, 32); const u32 sizea = (enda - starta) / 32; ensure(sizea); if (sizea == 1) { const u32 cmask = get_code_mask(starta, enda); if (cmask == 0xff) { c->vmovaps(x86::ymm0, x86::ymmword_ptr(*ls, starta)); } else { c->vxorps(x86::ymm0, x86::ymm0, x86::ymm0); c->vblendps(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta), cmask); } c->vxorps(x86::ymm0, x86::ymm0, x86::ymmword_ptr(label_code)); c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); for (u32 i = starta; i < enda; i += 4) { words.push_back(i >= start && i < end ? func.data[(i - start) / 4] : 0); } } else if (sizea == 2 && (end - start) <= 32) { const u32 cmask0 = get_code_mask(starta, starta + 32); const u32 cmask1 = get_code_mask(starta + 32, enda); c->vxorps(x86::ymm0, x86::ymm0, x86::ymm0); c->vblendps(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta), cmask0); c->vblendps(x86::ymm0, x86::ymm0, x86::ymmword_ptr(*ls, starta + 32), cmask1); c->vxorps(x86::ymm0, x86::ymm0, x86::ymmword_ptr(label_code)); c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); for (u32 i = starta; i < starta + 32; i += 4) { words.push_back(i >= start ? func.data[(i - start) / 4] : i + 32 < end ? func.data[(i + 32 - start) / 4] : 0); } } else { bool xmm2z = false; // Initialize pointers c->add(*ls, starta); c->lea(x86::rax, x86::qword_ptr(label_code)); u32 code_off = 0; u32 ls_off = starta; u32 order0 = 0; u32 order1 = 0; for (u32 j = starta; j < enda; j += 32) { const u32 cmask = get_code_mask(j, j + 32); if (cmask == 0) [[unlikely]] { continue; } // Interleave two threads auto& order = order0 > order1 ? order1 : order0; const auto& reg0 = order0 > order1 ? x86::ymm3 : x86::ymm0; const auto& reg1 = order0 > order1 ? x86::ymm4 : x86::ymm1; // Ensure small distance for disp8 if (j - ls_off >= 256) { c->add(*ls, j - ls_off); ls_off = j; } else if (j - ls_off >= 128) { c->sub(*ls, -128); ls_off += 128; } if (code_off >= 128) { c->sub(x86::rax, -128); code_off -= 128; } if (cmask != 0xff) { if (!xmm2z) { c->vxorps(x86::xmm2, x86::xmm2, x86::xmm2); xmm2z = true; } c->vblendps(reg1, x86::ymm2, x86::ymmword_ptr(*ls, j - ls_off), cmask); } else { c->vmovaps(reg1, x86::ymmword_ptr(*ls, j - ls_off)); } // Perform bitwise comparison and accumulate if (!order++) { c->vxorps(reg0, reg1, x86::ymmword_ptr(x86::rax, code_off)); } else { c->vxorps(reg1, reg1, x86::ymmword_ptr(x86::rax, code_off)); c->vorps(reg0, reg1, reg0); } for (u32 i = j; i < j + 32; i += 4) { words.push_back(i >= start && i < end ? func.data[(i - start) / 4] : 0); } code_off += 32; } c->sub(*ls, ls_off); if (order1) { c->vorps(x86::ymm0, x86::ymm3, x86::ymm0); } c->vptest(x86::ymm0, x86::ymm0); c->jnz(label_diff); } c->vzeroupper(); } else { if (utils::has_avx()) { c->vzeroupper(); } // Compatible SSE2 words_align = 16; // Initialize pointers c->lea(x86::rcx, get_pc_ptr()); c->lea(x86::rax, x86::qword_ptr(label_code)); u32 code_off = 0; u32 ls_off = starta; u32 order0 = 0; u32 order1 = 0; for (u32 j = starta; j < end; j += 16) { const u32 cmask = get_code_mask(j, j + 16); if (cmask == 0) [[unlikely]] { continue; } // Interleave two threads auto& order = order0 > order1 ? order1 : order0; const auto& reg0 = order0 > order1 ? x86::xmm3 : x86::xmm0; const auto& reg1 = order0 > order1 ? x86::xmm4 : x86::xmm1; // Ensure small distance for disp8 if (j - ls_off >= 256) { c->add(x86::rcx, j - ls_off); ls_off = j; } else if (j - ls_off >= 128) { c->sub(x86::rcx, -128); ls_off += 128; } if (code_off >= 128) { c->sub(x86::rax, -128); code_off -= 128; } // Determine which value will be duplicated at hole positions const u32 w3 = func.data.at((j - start + ~static_cast(std::countl_zero(cmask)) % 4 * 4) / 4); words.push_back(cmask & 1 ? func.data[(j - start + 0) / 4] : w3); words.push_back(cmask & 2 ? func.data[(j - start + 4) / 4] : w3); words.push_back(cmask & 4 ? func.data[(j - start + 8) / 4] : w3); words.push_back(w3); // PSHUFD immediate table for all possible hole mask values, holes repeat highest valid word static constexpr s32 s_pshufd_imm[16] { -1, // invalid index 0b00000000, // copy 0 0b01010101, // copy 1 0b01010100, // copy 1 0b10101010, // copy 2 0b10101000, // copy 2 0b10100110, // copy 2 0b10100100, // copy 2 0b11111111, // copy 3 0b11111100, // copy 3 0b11110111, // copy 3 0b11110100, // copy 3 0b11101111, // copy 3 0b11101100, // copy 3 0b11100111, // copy 3 0b11100100, // full }; const bool first = !order++; const auto& dest = first ? reg0 : reg1; // Load unaligned code block from LS if (cmask != 0xf) { if (utils::has_avx()) { c->vpshufd(dest, x86::dqword_ptr(x86::rcx, j - ls_off), s_pshufd_imm[cmask]); } else { c->movups(dest, x86::dqword_ptr(x86::rcx, j - ls_off)); c->pshufd(dest, dest, s_pshufd_imm[cmask]); } } else { c->movups(dest, x86::dqword_ptr(x86::rcx, j - ls_off)); } // Perform bitwise comparison and accumulate c->xorps(dest, x86::dqword_ptr(x86::rax, code_off)); if (!first) { c->orps(reg0, dest); } code_off += 16; } if (order1) { c->orps(x86::xmm0, x86::xmm3); } if (utils::has_sse41()) { c->ptest(x86::xmm0, x86::xmm0); c->jnz(label_diff); } else { c->packssdw(x86::xmm0, x86::xmm0); c->movq(x86::rax, x86::xmm0); c->test(x86::rax, x86::rax); c->jne(label_diff); } } // Acknowledge success and add statistics c->add(SPU_OFF_64(block_counter), ::size32(words) / (words_align / 4)); // Set block hash for profiling (if enabled) if (g_cfg.core.spu_prof) { c->mov(x86::rax, m_hash_start | 0xffff); c->mov(SPU_OFF_64(block_hash), x86::rax); } if (m_pos != start) { // Jump to the entry point if necessary c->jmp(instr_labels[m_pos]); m_pos = -1; } for (u32 i = 0; i < func.data.size(); i++) { const u32 pos = start + i * 4; const u32 op = std::bit_cast>(func.data[i]); if (!op) { // Ignore hole if (m_pos + 1) { spu_log.error("Unexpected fallthrough to 0x%x", pos); branch_fixed(spu_branch_target(pos)); m_pos = -1; } continue; } // Update position m_pos = pos; // Bind instruction label if necessary const auto found = instr_labels.find(pos); if (found != instr_labels.end()) { if (m_preds.count(pos)) { c->align(AlignMode::kCode, 16); } c->bind(found->second); } if (g_cfg.core.spu_debug) { // Write the instruction address inside the ASMJIT log compiler.comment(fmt::format("[0x%05x]", m_pos).c_str()); } // Tracing //c->lea(x86::r14, get_pc(m_pos)); // Execute recompiler function (this->*s_spu_decoder.decode(op))({op}); // Collect allocated xmm vars for (u32 i = 0; i < vec_vars.size(); i++) { vec[i] = vec_vars[i]; } } // Make fallthrough if necessary if (m_pos + 1) { branch_fixed(spu_branch_target(end)); } // Simply return c->align(AlignMode::kCode, 16); c->bind(label_stop); c->add(x86::rsp, 0x28); c->ret(); if (g_cfg.core.spu_verification) { // Dispatch c->align(AlignMode::kCode, 16); c->bind(label_diff); c->inc(SPU_OFF_64(block_failure)); c->add(x86::rsp, 0x28); c->jmp(imm_ptr(spu_runtime::tr_dispatch)); } for (auto&& work : ::as_rvalue(std::move(after))) { work(); } // Build instruction dispatch table if (instr_table.isValid()) { c->align(AlignMode::kData, 8); c->bind(instr_table); // Get actual instruction table bounds const u32 start = instr_labels.begin()->first; const u32 end = instr_labels.rbegin()->first + 4; for (u32 addr = start; addr < end; addr += 4) { const auto found = instr_labels.find(addr); if (found != instr_labels.end()) { c->embedLabel(found->second); } else { c->embedLabel(label_stop); } } } c->align(AlignMode::kData, words_align); c->bind(label_code); for (u32 d : words) c->dd(d); for (auto&& work : ::as_rvalue(std::move(consts))) { work(); } label_stop.reset(); instr_table.reset(); instr_labels.clear(); xmm_consts.clear(); // Compile and get function address spu_function_t fn = reinterpret_cast(m_asmrt._add(&code)); if (!fn) { spu_log.fatal("Failed to build a function"); } else { jit_announce(fn, code.codeSize(), fmt::format("spu-b-%s", fmt::base57(be_t(m_hash_start)))); } // Install compiled function pointer const bool added = !add_loc->compiled && add_loc->compiled.compare_and_swap_test(nullptr, fn); // Rebuild trampoline if necessary if (!m_spurt->rebuild_ubertrampoline(func.data[0])) { return nullptr; } if (added) { add_loc->compiled.notify_all(); } if (g_cfg.core.spu_debug && added) { // Add ASMJIT logs fmt::append(log, "Address: %p\n\n", fn); log.append(logger._content.data(), logger._content.size()); log += "\n\n\n"; // Append log file fs::file(m_spurt->get_cache_path() + "spu-ir.log", fs::write + fs::append).write(log); } return fn; } spu_recompiler::XmmLink spu_recompiler::XmmAlloc() // get empty xmm register { for (auto& v : vec) { if (v) return{ v }; } fmt::throw_exception("Out of Xmm Vars"); } spu_recompiler::XmmLink spu_recompiler::XmmGet(s8 reg, XmmType type) // get xmm register with specific SPU reg { XmmLink result = XmmAlloc(); switch (type) { case XmmType::Int: c->movdqa(result, SPU_OFF_128(gpr, reg)); break; case XmmType::Float: c->movaps(result, SPU_OFF_128(gpr, reg)); break; case XmmType::Double: c->movapd(result, SPU_OFF_128(gpr, reg)); break; default: fmt::throw_exception("Invalid XmmType"); } return result; } inline asmjit::x86::Mem spu_recompiler::XmmConst(const v128& data) { // Find existing const auto& xmm_label = xmm_consts[std::make_pair(data._u64[0], data._u64[1])]; if (!xmm_label.isValid()) { xmm_label = c->newLabel(); consts.emplace_back([=, this] { c->align(asmjit::AlignMode::kData, 16); c->bind(xmm_label); c->dq(data._u64[0]); c->dq(data._u64[1]); }); } return asmjit::x86::oword_ptr(xmm_label); } inline asmjit::x86::Mem spu_recompiler::XmmConst(const __m128& data) { return XmmConst(v128::fromF(data)); } inline asmjit::x86::Mem spu_recompiler::XmmConst(const __m128i& data) { return XmmConst(v128::fromV(data)); } inline asmjit::x86::Mem spu_recompiler::get_pc(u32 addr) { return asmjit::x86::qword_ptr(*pc0, addr - m_base); } static void check_state(spu_thread* _spu) { if (_spu->state && _spu->check_state()) { spu_runtime::g_escape(_spu); } } void spu_recompiler::branch_fixed(u32 target, bool absolute) { using namespace asmjit; // Check local branch const auto local = instr_labels.find(target); if (local != instr_labels.end() && local->second.isValid()) { Label fail; if (absolute) { fail = c->newLabel(); c->cmp(pc0->r32(), m_base); c->jne(fail); } c->cmp(SPU_OFF_32(state), 0); c->jz(local->second); c->lea(addr->r64(), get_pc(target)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(*arg0, *cpu); c->call(imm_ptr(&check_state)); c->jmp(local->second); if (absolute) { c->bind(fail); } else { return; } } const auto ppptr = !g_cfg.core.spu_verification ? nullptr : m_spurt->make_branch_patchpoint(); if (absolute) { c->mov(SPU_OFF_32(pc), target); } else { c->lea(addr->r64(), get_pc(target)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); } c->xor_(rip->r32(), rip->r32()); c->cmp(SPU_OFF_32(state), 0); c->jnz(label_stop); if (ppptr) { c->add(x86::rsp, 0x28); c->jmp(imm_ptr(ppptr)); } else { c->jmp(label_stop); } } void spu_recompiler::branch_indirect(spu_opcode_t op, bool jt, bool ret) { using namespace asmjit; // Initialize third arg to zero c->xor_(rip->r32(), rip->r32()); if (op.d) { c->mov(SPU_OFF_8(interrupts_enabled), 0); } else if (op.e) { auto _throw = [](spu_thread* _spu) { _spu->state += cpu_flag::dbg_pause; spu_log.fatal("SPU Interrupts not implemented (mask=0x%x)", +_spu->ch_events.load().mask); spu_runtime::g_escape(_spu); }; Label no_intr = c->newLabel(); Label intr = c->newLabel(); Label fail = c->newLabel(); c->mov(*qw1, SPU_OFF_64(ch_events)); c->ror(*qw1, 32); c->test(qw1->r32(), ~SPU_EVENT_INTR_IMPLEMENTED); c->ror(*qw1, 32); c->jnz(fail); c->mov(SPU_OFF_8(interrupts_enabled), 1); c->bt(qw1->r32(), 31); c->jc(intr); c->jmp(no_intr); c->bind(fail); c->mov(SPU_OFF_32(pc), *addr); c->mov(*arg0, *cpu); c->add(x86::rsp, 0x28); c->jmp(imm_ptr(+_throw)); // Save addr in srr0 and disable interrupts c->bind(intr); c->mov(SPU_OFF_8(interrupts_enabled), 0); c->mov(SPU_OFF_32(srr0), *addr); // Test for BR/BRA instructions (they are equivalent at zero pc) c->mov(*addr, x86::dword_ptr(*ls)); c->and_(*addr, 0xfffffffd); c->xor_(*addr, 0x30); c->bswap(*addr); c->test(*addr, 0xff80007f); c->cmovnz(*addr, rip->r32()); c->shr(*addr, 5); c->align(AlignMode::kCode, 16); c->bind(no_intr); } c->mov(SPU_OFF_32(pc), *addr); c->cmp(SPU_OFF_32(state), 0); c->jnz(label_stop); if (g_cfg.core.spu_block_size != spu_block_size_type::safe && ret) { // Get stack pointer, try to use native return address (check SPU return address) Label fail = c->newLabel(); c->mov(qw1->r32(), SPU_OFF_32(gpr, 1, &v128::_u32, 3)); c->and_(qw1->r32(), 0x3fff0); c->lea(*qw1, x86::qword_ptr(*cpu, *qw1, 0, ::offset32(&spu_thread::stack_mirror))); c->cmp(x86::dword_ptr(*qw1, 8), *addr); c->jne(fail); c->mov(pc0->r32(), x86::dword_ptr(*qw1, 12)); c->jmp(x86::qword_ptr(*qw1)); c->bind(fail); } if (jt || g_cfg.core.spu_block_size == spu_block_size_type::giga) { if (!instr_table.isValid()) { // Request instruction table instr_table = c->newLabel(); } // Get actual instruction table bounds const u32 start = instr_labels.begin()->first; const u32 end = instr_labels.rbegin()->first + 4; // Load local indirect jump address, check local bounds ensure(start == m_base); Label fail = c->newLabel(); c->mov(qw1->r32(), *addr); c->sub(qw1->r32(), pc0->r32()); c->cmp(qw1->r32(), end - start); c->jae(fail); c->lea(addr->r64(), x86::qword_ptr(instr_table)); c->jmp(x86::qword_ptr(addr->r64(), *qw1, 1, 0)); c->bind(fail); } // Simply external call (return or indirect call) const auto ppptr = !g_cfg.core.spu_verification ? nullptr : m_spurt->make_branch_patchpoint(); if (ppptr) { c->add(x86::rsp, 0x28); c->jmp(imm_ptr(ppptr)); } else { c->jmp(label_stop); } } void spu_recompiler::branch_set_link(u32 target) { using namespace asmjit; if (g_cfg.core.spu_block_size != spu_block_size_type::safe) { // Find instruction at target const auto local = instr_labels.find(target); if (local != instr_labels.end() && local->second.isValid()) { Label ret = c->newLabel(); // Get stack pointer, write native and SPU return addresses into the stack mirror c->mov(qw1->r32(), SPU_OFF_32(gpr, 1, &v128::_u32, 3)); c->and_(qw1->r32(), 0x3fff0); c->lea(*qw1, x86::qword_ptr(*cpu, *qw1, 0, ::offset32(&spu_thread::stack_mirror))); c->lea(x86::r10, x86::qword_ptr(ret)); c->mov(x86::qword_ptr(*qw1, 0), x86::r10); c->lea(x86::r10, get_pc(target)); c->and_(x86::r10d, 0x3fffc); c->mov(x86::dword_ptr(*qw1, 8), x86::r10d); c->mov(x86::dword_ptr(*qw1, 12), pc0->r32()); after.emplace_back([=, this, target = local->second] { // Clear return info after use c->align(AlignMode::kCode, 16); c->bind(ret); c->mov(qw1->r32(), SPU_OFF_32(gpr, 1, &v128::_u32, 3)); c->and_(qw1->r32(), 0x3fff0); c->pcmpeqd(x86::xmm0, x86::xmm0); c->movdqa(x86::dqword_ptr(*cpu, *qw1, 0, ::offset32(&spu_thread::stack_mirror)), x86::xmm0); // Set block hash for profiling (if enabled) if (g_cfg.core.spu_prof) { c->mov(x86::rax, m_hash_start | 0xffff); c->mov(SPU_OFF_64(block_hash), x86::rax); } c->jmp(target); }); } } } void spu_recompiler::fall(spu_opcode_t op) { auto gate = [](spu_thread* _spu, u32 opcode, spu_inter_func_t _func) { if (!_func(*_spu, {opcode})) { _spu->state += cpu_flag::dbg_pause; spu_log.fatal("spu_recompiler::fall(): unexpected interpreter call (op=0x%08x)", opcode); spu_runtime::g_escape(_spu); } }; c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), op.opcode); c->mov(*qw0, asmjit::imm_ptr(g_spu_interpreter_fast.decode(op.opcode))); c->mov(*arg0, *cpu); c->call(asmjit::imm_ptr(+gate)); } void spu_recompiler::UNK(spu_opcode_t op) { auto gate = [](spu_thread* _spu, u32 op) { _spu->state += cpu_flag::dbg_pause; spu_log.fatal("Unknown/Illegal instruction (0x%08x)", op); spu_runtime::g_escape(_spu); }; c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), op.opcode); c->mov(*arg0, *cpu); c->add(asmjit::x86::rsp, 0x28); c->jmp(asmjit::imm_ptr(+gate)); m_pos = -1; } void spu_stop(spu_thread* _spu, u32 code) { if (!_spu->stop_and_signal(code)) { spu_runtime::g_escape(_spu); } if (_spu->test_stopped()) { _spu->pc += 4; spu_runtime::g_escape(_spu); } } void spu_recompiler::STOP(spu_opcode_t op) { using namespace asmjit; Label ret = c->newLabel(); c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), op.opcode & 0x3fff); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_stop)); c->align(AlignMode::kCode, 16); c->bind(ret); c->add(SPU_OFF_32(pc), 4); if (g_cfg.core.spu_block_size == spu_block_size_type::safe) { c->jmp(label_stop); m_pos = -1; } } void spu_recompiler::LNOP(spu_opcode_t) { } void spu_recompiler::SYNC(spu_opcode_t) { // This instruction must be used following a store instruction that modifies the instruction stream. c->lock().or_(asmjit::x86::dword_ptr(asmjit::x86::rsp), 0); if (g_cfg.core.spu_block_size == spu_block_size_type::safe) { c->lea(addr->r64(), get_pc(m_pos + 4)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->jmp(label_stop); m_pos = -1; } } void spu_recompiler::DSYNC(spu_opcode_t) { // This instruction forces all earlier load, store, and channel instructions to complete before proceeding. c->lock().or_(asmjit::x86::dword_ptr(asmjit::x86::rsp), 0); } void spu_recompiler::MFSPR(spu_opcode_t op) { // Check SPUInterpreter for notes. const XmmLink& vr = XmmAlloc(); c->pxor(vr, vr); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } static u32 spu_rdch(spu_thread* _spu, u32 ch) { const s64 result = _spu->get_ch_value(ch); if (result < 0) { spu_runtime::g_escape(_spu); } if (_spu->test_stopped()) { _spu->pc += 4; spu_runtime::g_escape(_spu); } return static_cast(result & 0xffffffff); } void spu_recompiler::RDCH(spu_opcode_t op) { using namespace asmjit; auto read_channel = [&](x86::Mem channel_ptr, bool sync = true) { Label wait = c->newLabel(); Label again = c->newLabel(); Label ret = c->newLabel(); c->mov(addr->r64(), channel_ptr); c->xor_(qw0->r32(), qw0->r32()); c->align(AlignMode::kCode, 16); c->bind(again); c->bt(addr->r64(), spu_channel::off_count); c->jnc(wait); after.emplace_back([=, this, pos = m_pos] { c->bind(wait); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_rdch)); c->jmp(ret); }); if (sync) { // Channel is externally accessible c->lock().cmpxchg(channel_ptr, *qw0); c->jnz(again); } else { // Just write zero c->mov(channel_ptr, *qw0); } c->bind(ret); c->movd(x86::xmm0, *addr); c->pslldq(x86::xmm0, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), x86::xmm0); }; switch (op.ra) { case SPU_RdSRR0: { const XmmLink& vr = XmmAlloc(); c->movd(vr, SPU_OFF_32(srr0)); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case SPU_RdInMbox: { // TODO break; } case MFC_RdTagStat: { read_channel(SPU_OFF_64(ch_tag_stat), false); return; } case MFC_RdTagMask: { const XmmLink& vr = XmmAlloc(); c->movd(vr, SPU_OFF_32(ch_tag_mask)); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case SPU_RdSigNotify1: { read_channel(SPU_OFF_64(ch_snr1)); return; } case SPU_RdSigNotify2: { read_channel(SPU_OFF_64(ch_snr2)); return; } case MFC_RdAtomicStat: { read_channel(SPU_OFF_64(ch_atomic_stat), false); return; } case MFC_RdListStallStat: { read_channel(SPU_OFF_64(ch_stall_stat), false); return; } case SPU_RdDec: { spu_log.warning("[0x%x] RDCH: RdDec", m_pos); auto sub1 = [](spu_thread* _spu, v128* _res) { const u32 out = _spu->ch_dec_value - static_cast(get_timebased_time() - _spu->ch_dec_start_timestamp); if (out > 1500) { _spu->state += cpu_flag::wait; std::this_thread::yield(); if (_spu->test_stopped()) { _spu->pc += 4; spu_runtime::g_escape(_spu); } } *_res = v128::from32r(out); }; auto sub2 = [](spu_thread* _spu, v128* _res) { const u32 out = _spu->ch_dec_value - static_cast(get_timebased_time() - _spu->ch_dec_start_timestamp); *_res = v128::from32r(out); }; c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->lea(*arg1, SPU_OFF_128(gpr, op.rt)); c->mov(*arg0, *cpu); c->call(asmjit::imm_ptr(g_cfg.core.spu_loop_detection ? +sub1 : +sub2)); return; } case SPU_RdEventMask: { const XmmLink& vr = XmmAlloc(); c->movq(vr, SPU_OFF_64(ch_events)); c->psrldq(vr, 4); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case SPU_RdEventStat: { spu_log.warning("[0x%x] RDCH: RdEventStat", m_pos); break; // TODO } case SPU_RdMachStat: { const XmmLink& vr = XmmAlloc(); c->movzx(*addr, SPU_OFF_8(interrupts_enabled)); c->mov(arg1->r32(), SPU_OFF_32(thread_type)); c->and_(arg1->r32(), 2); c->or_(addr->r32(), arg1->r32()); c->movd(vr, *addr); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } default: break; } c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_rdch)); c->movd(x86::xmm0, *addr); c->pslldq(x86::xmm0, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), x86::xmm0); } static u32 spu_rchcnt(spu_thread* _spu, u32 ch) { return _spu->get_ch_count(ch); } void spu_recompiler::RCHCNT(spu_opcode_t op) { using namespace asmjit; auto ch_cnt = [&](x86::Mem channel_ptr, bool inv = false) { // Load channel count const XmmLink& vr = XmmAlloc(); c->movq(vr, channel_ptr); c->psrlq(vr, spu_channel::off_count); if (inv) c->pxor(vr, XmmConst(_mm_set1_epi32(1))); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); }; switch (op.ra) { case SPU_WrOutMbox: return ch_cnt(SPU_OFF_64(ch_out_mbox), true); case SPU_WrOutIntrMbox: return ch_cnt(SPU_OFF_64(ch_out_intr_mbox), true); case MFC_RdTagStat: return ch_cnt(SPU_OFF_64(ch_tag_stat)); case MFC_RdListStallStat: return ch_cnt(SPU_OFF_64(ch_stall_stat)); case SPU_RdSigNotify1: return ch_cnt(SPU_OFF_64(ch_snr1)); case SPU_RdSigNotify2: return ch_cnt(SPU_OFF_64(ch_snr2)); case MFC_RdAtomicStat: return ch_cnt(SPU_OFF_64(ch_atomic_stat)); case MFC_WrTagUpdate: { const XmmLink& vr = XmmAlloc(); c->mov(addr->r32(), 1); c->movd(vr, addr->r32()); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case MFC_Cmd: { const XmmLink& vr = XmmAlloc(); const XmmLink& v1 = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi32(16))); c->movd(v1, SPU_OFF_32(mfc_size)); c->psubd(vr, v1); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case SPU_RdInMbox: { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, SPU_OFF_128(ch_in_mbox)); c->pslldq(vr, 14); c->psrldq(vr, 3); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } // Channels with a constant count of 1: case SPU_WrEventMask: case SPU_WrEventAck: case SPU_WrDec: case SPU_RdDec: case SPU_RdEventMask: case SPU_RdMachStat: case SPU_WrSRR0: case SPU_RdSRR0: case SPU_Set_Bkmk_Tag: case SPU_PM_Start_Ev: case SPU_PM_Stop_Ev: case MFC_RdTagMask: case MFC_LSA: case MFC_EAH: case MFC_EAL: case MFC_Size: case MFC_TagID: case MFC_WrTagMask: case MFC_WrListStallAck: { const XmmLink& vr = XmmAlloc(); c->mov(addr->r32(), 1); c->movd(vr, addr->r32()); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); return; } case SPU_RdEventStat: { spu_log.warning("[0x%x] RCHCNT: RdEventStat", m_pos); [[fallthrough]]; // fallback } default: { c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_rchcnt)); break; } } // Use result from the third argument c->movd(x86::xmm0, *addr); c->pslldq(x86::xmm0, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), x86::xmm0); } void spu_recompiler::SF(spu_opcode_t op) { // sub from const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->psubd(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::OR(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->por(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::BG(spu_opcode_t op) { // compare if-greater-than const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vi = XmmAlloc(); if (utils::has_avx512()) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->vpsubd(vi, vb, va); c->vpternlogd(va, vb, vi, 0x4d /* B?nandAC:norAC */); c->psrld(va, 31); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } c->movdqa(vi, XmmConst(_mm_set1_epi32(0x80000000))); c->pxor(va, vi); c->pxor(vi, SPU_OFF_128(gpr, op.rb)); c->pcmpgtd(va, vi); c->paddd(va, XmmConst(_mm_set1_epi32(1))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SFH(spu_opcode_t op) { // sub from (halfword) const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->psubw(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::NOR(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); if (utils::has_avx512()) { c->vpternlogd(va, va, SPU_OFF_128(gpr, op.rb), 0x11 /* norCB */); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } c->por(va, SPU_OFF_128(gpr, op.rb)); c->pxor(va, XmmConst(_mm_set1_epi32(0xffffffff))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ABSDB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vm = XmmAlloc(); c->movdqa(vm, va); c->pmaxub(va, vb); c->pminub(vb, vm); c->psubb(va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROT(spu_opcode_t op) { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->vprolvd(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); c->movdqa(v4, XmmConst(_mm_set1_epi32(0x1f))); c->pand(vb, v4); c->vpsllvd(vt, va, vb); c->psubd(vb, XmmConst(_mm_set1_epi32(1))); c->pandn(vb, v4); c->vpsrlvd(va, va, vb); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->vprotd(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 4; i++) // unrolled loop { c->mov(qw0->r32(), SPU_OFF_32(gpr, op.ra, &v128::_u32, i)); c->mov(asmjit::x86::ecx, SPU_OFF_32(gpr, op.rb, &v128::_u32, i)); c->rol(qw0->r32(), asmjit::x86::cl); c->mov(SPU_OFF_32(gpr, op.rt, &v128::_u32, i), qw0->r32()); } } void spu_recompiler::ROTM(spu_opcode_t op) { if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubd(vb, XmmConst(_mm_set1_epi32(1))); c->pandn(vb, XmmConst(_mm_set1_epi32(0x3f))); c->vpsrlvd(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubd(vb, XmmConst(_mm_set1_epi32(1))); c->pandn(vb, XmmConst(_mm_set1_epi32(0x3f))); c->pxor(vt, vt); c->psubd(vt, vb); c->pcmpgtd(vb, XmmConst(_mm_set1_epi32(31))); c->vpshld(vt, va, vt); c->vpandn(vt, vb, vt); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 4; i++) // unrolled loop { c->mov(qw0->r32(), SPU_OFF_32(gpr, op.ra, &v128::_u32, i)); c->mov(asmjit::x86::ecx, SPU_OFF_32(gpr, op.rb, &v128::_u32, i)); c->neg(asmjit::x86::ecx); c->shr(*qw0, asmjit::x86::cl); c->mov(SPU_OFF_32(gpr, op.rt, &v128::_u32, i), qw0->r32()); } } void spu_recompiler::ROTMA(spu_opcode_t op) { if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubd(vb, XmmConst(_mm_set1_epi32(1))); c->pandn(vb, XmmConst(_mm_set1_epi32(0x3f))); c->vpsravd(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubd(vb, XmmConst(_mm_set1_epi32(1))); c->pandn(vb, XmmConst(_mm_set1_epi32(0x3f))); c->pxor(vt, vt); c->pminud(vb, XmmConst(_mm_set1_epi32(31))); c->psubd(vt, vb); c->vpshad(vt, va, vt); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 4; i++) // unrolled loop { c->movsxd(*qw0, SPU_OFF_32(gpr, op.ra, &v128::_u32, i)); c->mov(asmjit::x86::ecx, SPU_OFF_32(gpr, op.rb, &v128::_u32, i)); c->neg(asmjit::x86::ecx); c->sar(*qw0, asmjit::x86::cl); c->mov(SPU_OFF_32(gpr, op.rt, &v128::_u32, i), qw0->r32()); } } void spu_recompiler::SHL(spu_opcode_t op) { if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->pand(vb, XmmConst(_mm_set1_epi32(0x3f))); c->vpsllvd(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->pand(vb, XmmConst(_mm_set1_epi32(0x3f))); c->vpcmpgtd(vt, vb, XmmConst(_mm_set1_epi32(31))); c->vpshld(vb, va, vb); c->pandn(vt, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 4; i++) // unrolled loop { c->mov(qw0->r32(), SPU_OFF_32(gpr, op.ra, &v128::_u32, i)); c->mov(asmjit::x86::ecx, SPU_OFF_32(gpr, op.rb, &v128::_u32, i)); c->shl(*qw0, asmjit::x86::cl); c->mov(SPU_OFF_32(gpr, op.rt, &v128::_u32, i), qw0->r32()); } } void spu_recompiler::ROTH(spu_opcode_t op) //nf { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); c->vmovdqa(v4, XmmConst(_mm_set_epi32(0x0d0c0d0c, 0x09080908, 0x05040504, 0x01000100))); c->vpshufb(vt, va, v4); // duplicate low word c->vpsrld(va, va, 16); c->vpshufb(va, va, v4); c->vpsrld(v4, vb, 16); c->vprolvd(va, va, v4); c->vprolvd(vb, vt, vb); c->vpblendw(vt, vb, va, 0xaa); c->vmovdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->vprotw(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 8; i++) // unrolled loop { c->movzx(qw0->r32(), SPU_OFF_16(gpr, op.ra, &v128::_u16, i)); c->movzx(asmjit::x86::ecx, SPU_OFF_16(gpr, op.rb, &v128::_u16, i)); c->rol(qw0->r16(), asmjit::x86::cl); c->mov(SPU_OFF_16(gpr, op.rt, &v128::_u16, i), qw0->r16()); } } void spu_recompiler::ROTHM(spu_opcode_t op) { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->pandn(vb, XmmConst(_mm_set1_epi16(0x1f))); c->vpsrlvw(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); const XmmLink& v5 = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->pandn(vb, XmmConst(_mm_set1_epi16(0x1f))); c->movdqa(vt, XmmConst(_mm_set1_epi32(0xffff0000))); // mask: select high words c->vpsrld(v4, vb, 16); c->vpsubusw(v5, vb, vt); // clear high words (using saturation sub for throughput) c->vpandn(vb, vt, va); // clear high words c->vpsrlvd(va, va, v4); c->vpsrlvd(vb, vb, v5); c->vpblendw(vt, vb, va, 0xaa); // can use vpblendvb with 0xffff0000 mask (vt) c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->pandn(vb, XmmConst(_mm_set1_epi16(0x1f))); c->pxor(vt, vt); c->psubw(vt, vb); c->pcmpgtw(vb, XmmConst(_mm_set1_epi16(15))); c->vpshlw(vt, va, vt); c->vpandn(vt, vb, vt); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 8; i++) // unrolled loop { c->movzx(qw0->r32(), SPU_OFF_16(gpr, op.ra, &v128::_u16, i)); c->movzx(asmjit::x86::ecx, SPU_OFF_16(gpr, op.rb, &v128::_u16, i)); c->neg(asmjit::x86::ecx); c->shr(qw0->r32(), asmjit::x86::cl); c->mov(SPU_OFF_16(gpr, op.rt, &v128::_u16, i), qw0->r16()); } } void spu_recompiler::ROTMAH(spu_opcode_t op) { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->pandn(vb, XmmConst(_mm_set1_epi16(0x1f))); c->vpsravw(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); const XmmLink& v5 = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->movdqa(vt, XmmConst(_mm_set1_epi16(0x1f))); c->vpandn(v4, vb, vt); c->vpand(v5, vb, vt); c->movdqa(vt, XmmConst(_mm_set1_epi32(0x2f))); c->vpsrld(v4, v4, 16); c->vpsubusw(v5, vt, v5); // clear high word and add 16 to low word c->vpslld(vb, va, 16); c->vpsravd(va, va, v4); c->vpsravd(vb, vb, v5); c->vpblendw(vt, vb, va, 0xaa); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->psubw(vb, XmmConst(_mm_set1_epi16(1))); c->pandn(vb, XmmConst(_mm_set1_epi16(0x1f))); c->pxor(vt, vt); c->pminuw(vb, XmmConst(_mm_set1_epi16(15))); c->psubw(vt, vb); c->vpshaw(vt, va, vt); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 8; i++) // unrolled loop { c->movsx(qw0->r32(), SPU_OFF_16(gpr, op.ra, &v128::_u16, i)); c->movzx(asmjit::x86::ecx, SPU_OFF_16(gpr, op.rb, &v128::_u16, i)); c->neg(asmjit::x86::ecx); c->sar(qw0->r32(), asmjit::x86::cl); c->mov(SPU_OFF_16(gpr, op.rt, &v128::_u16, i), qw0->r16()); } } void spu_recompiler::SHLH(spu_opcode_t op) { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->pand(vb, XmmConst(_mm_set1_epi16(0x1f))); c->vpsllvw(vt, va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_avx2()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); const XmmLink& v5 = XmmAlloc(); c->pand(vb, XmmConst(_mm_set1_epi16(0x1f))); c->movdqa(vt, XmmConst(_mm_set1_epi32(0xffff0000))); // mask: select high words c->vpsrld(v4, vb, 16); c->vpsubusw(v5, vb, vt); // clear high words (using saturation sub for throughput) c->vpand(vb, vt, va); // clear low words c->vpsllvd(va, va, v5); c->vpsllvd(vb, vb, v4); c->vpblendw(vt, vb, va, 0x55); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->pand(vb, XmmConst(_mm_set1_epi16(0x1f))); c->vpcmpgtw(vt, vb, XmmConst(_mm_set1_epi16(15))); c->vpshlw(vb, va, vb); c->pandn(vt, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } for (u32 i = 0; i < 8; i++) // unrolled loop { c->movzx(qw0->r32(), SPU_OFF_16(gpr, op.ra, &v128::_u16, i)); c->movzx(asmjit::x86::ecx, SPU_OFF_16(gpr, op.rb, &v128::_u16, i)); c->shl(qw0->r32(), asmjit::x86::cl); c->mov(SPU_OFF_16(gpr, op.rt, &v128::_u16, i), qw0->r16()); } } void spu_recompiler::ROTI(spu_opcode_t op) { // rotate left const int s = op.i7 & 0x1f; if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->vprold(va, va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } if (utils::has_xop()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->vprotd(va, va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v1 = XmmAlloc(); c->movdqa(v1, va); c->pslld(va, s); c->psrld(v1, 32 - s); c->por(va, v1); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTMI(spu_opcode_t op) { // shift right logical const int s = (0 - op.i7) & 0x3f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psrld(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTMAI(spu_opcode_t op) { // shift right arithmetical const int s = (0 - op.i7) & 0x3f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psrad(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SHLI(spu_opcode_t op) { // shift left const int s = op.i7 & 0x3f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pslld(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTHI(spu_opcode_t op) { // rotate left (halfword) const int s = op.i7 & 0xf; const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v1 = XmmAlloc(); c->movdqa(v1, va); c->psllw(va, s); c->psrlw(v1, 16 - s); c->por(va, v1); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTHMI(spu_opcode_t op) { // shift right logical const int s = (0 - op.i7) & 0x1f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psrlw(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTMAHI(spu_opcode_t op) { // shift right arithmetical (halfword) const int s = (0 - op.i7) & 0x1f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psraw(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SHLHI(spu_opcode_t op) { // shift left (halfword) const int s = op.i7 & 0x1f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psllw(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::A(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->paddd(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::AND(spu_opcode_t op) { // and const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->pand(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::CG(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vi = XmmAlloc(); if (utils::has_avx512()) { c->vpaddd(vi, vb, va); c->vpternlogd(vi, va, vb, 0x8e /* A?andBC:orBC */); c->psrld(vi, 31); c->movdqa(SPU_OFF_128(gpr, op.rt), vi); return; } c->movdqa(vi, XmmConst(_mm_set1_epi32(0x80000000))); c->paddd(vb, va); c->pxor(va, vi); c->pxor(vb, vi); c->pcmpgtd(va, vb); c->psrld(va, 31); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::AH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->paddw(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::NAND(spu_opcode_t op) { // nand const XmmLink& va = XmmGet(op.ra, XmmType::Int); if (utils::has_avx512()) { c->vpternlogd(va, va, SPU_OFF_128(gpr, op.rb), 0x77 /* nandCB */); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } c->pand(va, SPU_OFF_128(gpr, op.rb)); c->pxor(va, XmmConst(_mm_set1_epi32(0xffffffff))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::AVGB(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->pavgb(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::MTSPR(spu_opcode_t) { // Check SPUInterpreter for notes. } static void spu_wrch(spu_thread* _spu, u32 ch, u32 value) { if (!_spu->set_ch_value(ch, value)) { spu_runtime::g_escape(_spu); } if (_spu->test_stopped()) { _spu->pc += 4; spu_runtime::g_escape(_spu); } } static void spu_wrch_mfc(spu_thread* _spu) { if (!_spu->process_mfc_cmd()) { spu_runtime::g_escape(_spu); } if (_spu->test_stopped()) { _spu->pc += 4; spu_runtime::g_escape(_spu); } } void spu_recompiler::WRCH(spu_opcode_t op) { using namespace asmjit; switch (op.ra) { case SPU_WrSRR0: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(srr0), *addr); return; } case SPU_WrOutIntrMbox: { // Can't seemingly be optimized break; } case SPU_WrOutMbox: { Label wait = c->newLabel(); Label again = c->newLabel(); Label ret = c->newLabel(); c->mov(qw0->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(addr->r64(), SPU_OFF_64(ch_out_mbox)); c->align(AlignMode::kCode, 16); c->bind(again); c->mov(qw0->r32(), qw0->r32()); c->bt(addr->r64(), spu_channel::off_count); c->jc(wait); after.emplace_back([=, this, pos = m_pos] { c->bind(wait); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_wrch)); c->jmp(ret); }); c->bts(*qw0, spu_channel::off_count); c->lock().cmpxchg(SPU_OFF_64(ch_out_mbox), *qw0); c->jnz(again); c->bind(ret); return; } case MFC_WrTagMask: { Label upd = c->newLabel(); Label ret = c->newLabel(); c->mov(qw0->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_32(ch_tag_mask), qw0->r32()); c->cmp(SPU_OFF_32(ch_tag_upd), MFC_TAG_UPDATE_IMMEDIATE); c->jnz(upd); after.emplace_back([=, this, pos = m_pos] { c->bind(upd); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), MFC_WrTagMask); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_wrch)); c->jmp(ret); }); c->bind(ret); return; } case MFC_WrTagUpdate: { Label fail = c->newLabel(); Label zero = c->newLabel(); Label ret = c->newLabel(); c->mov(qw0->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->cmp(qw0->r32(), 2); c->ja(fail); after.emplace_back([=, this, pos = m_pos] { c->bind(fail); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_wrch)); c->jmp(ret); c->bind(zero); c->mov(SPU_OFF_32(ch_tag_upd), qw0->r32()); c->jmp(ret); }); // addr = completed mask, will be compared with qw1 c->mov(*addr, SPU_OFF_32(mfc_fence)); c->not_(*addr); c->and_(*addr, SPU_OFF_32(ch_tag_mask)); c->mov(qw1->r32(), *addr); c->test(*addr, *addr); c->cmovz(qw1->r32(), qw0->r32()); c->cmp(qw0->r32(), 1); c->cmovb(qw1->r32(), *addr); c->cmova(qw1->r32(), SPU_OFF_32(ch_tag_mask)); c->cmp(*addr, qw1->r32()); c->jne(zero); c->bts(addr->r64(), spu_channel::off_count); c->mov(SPU_OFF_32(ch_tag_upd), 0); c->mov(SPU_OFF_64(ch_tag_stat), addr->r64()); c->bind(ret); return; } case MFC_LSA: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_32(ch_mfc_cmd, &spu_mfc_cmd::lsa), *addr); return; } case MFC_EAH: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_32(ch_mfc_cmd, &spu_mfc_cmd::eah), *addr); return; } case MFC_EAL: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_32(ch_mfc_cmd, &spu_mfc_cmd::eal), *addr); return; } case MFC_Size: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->and_(*addr, 0x7fff); c->mov(SPU_OFF_16(ch_mfc_cmd, &spu_mfc_cmd::size), addr->r16()); return; } case MFC_TagID: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->and_(*addr, 0x1f); c->mov(SPU_OFF_8(ch_mfc_cmd, &spu_mfc_cmd::tag), addr->r8()); return; } case MFC_Cmd: { c->mov(*addr, SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_8(ch_mfc_cmd, &spu_mfc_cmd::cmd), addr->r8()); c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_wrch_mfc)); return; } case MFC_WrListStallAck: { auto sub = [](spu_thread* _spu, u32 tag) { for (u32 i = 0; i < _spu->mfc_size; i++) { if (_spu->mfc_queue[i].tag == (tag | 0x80)) { // Unset stall bit _spu->mfc_queue[i].tag &= 0x7f; } } _spu->do_mfc(true); }; Label ret = c->newLabel(); c->mov(arg1->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->and_(arg1->r32(), 0x1f); c->btr(SPU_OFF_32(ch_stall_mask), arg1->r32()); c->jnc(ret); c->mov(*arg0, *cpu); c->call(imm_ptr(+sub)); c->bind(ret); return; } case SPU_WrDec: { auto sub = [](spu_thread* _spu) { _spu->ch_dec_start_timestamp = get_timebased_time(); }; c->mov(*arg0, *cpu); c->call(imm_ptr(+sub)); c->mov(qw0->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(SPU_OFF_32(ch_dec_value), qw0->r32()); return; } case SPU_WrEventMask: { // TODO break; } case SPU_WrEventAck: { // TODO break; } case SPU_Set_Bkmk_Tag: case SPU_PM_Start_Ev: case SPU_PM_Stop_Ev: { return; } default: break; } c->lea(addr->r64(), get_pc(m_pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(arg1->r32(), +op.ra); c->mov(qw0->r32(), SPU_OFF_32(gpr, op.rt, &v128::_u32, 3)); c->mov(*arg0, *cpu); c->call(imm_ptr(spu_wrch)); } void spu_recompiler::BIZ(spu_opcode_t op) { asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_32(gpr, op.rt, &v128::_u32, 3), 0); c->je(branch_label); after.emplace_back([=, this, jt = m_targets[m_pos].size() > 1] { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); branch_indirect(op, jt); }); } void spu_recompiler::BINZ(spu_opcode_t op) { asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_32(gpr, op.rt, &v128::_u32, 3), 0); c->jne(branch_label); after.emplace_back([=, this, jt = m_targets[m_pos].size() > 1] { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); branch_indirect(op, jt); }); } void spu_recompiler::BIHZ(spu_opcode_t op) { asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_16(gpr, op.rt, &v128::_u16, 6), 0); c->je(branch_label); after.emplace_back([=, this, jt = m_targets[m_pos].size() > 1] { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); branch_indirect(op, jt); }); } void spu_recompiler::BIHNZ(spu_opcode_t op) { asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_16(gpr, op.rt, &v128::_u16, 6), 0); c->jne(branch_label); after.emplace_back([=, this, jt = m_targets[m_pos].size() > 1] { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); branch_indirect(op, jt); }); } void spu_recompiler::STOPD(spu_opcode_t) { STOP(spu_opcode_t{0x3fff}); } void spu_recompiler::STQX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(asmjit::x86::oword_ptr(*ls, addr->r64()), vt); } else { c->mov(*qw0, SPU_OFF_64(gpr, op.rt, &v128::_u64, 0)); c->mov(*qw1, SPU_OFF_64(gpr, op.rt, &v128::_u64, 1)); c->bswap(*qw0); c->bswap(*qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0), *qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8), *qw0); } } void spu_recompiler::BI(spu_opcode_t op) { const auto found = m_targets.find(m_pos); const auto is_jt = found == m_targets.end() || found->second.size() > 1; if (found == m_targets.end()) { spu_log.error("[0x%x] BI: no targets", m_pos); } c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); branch_indirect(op, is_jt, !is_jt); m_pos = -1; } void spu_recompiler::BISL(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->and_(*addr, 0x3fffc); const XmmLink& vr = XmmAlloc(); c->lea(*qw0, get_pc(m_pos + 4)); c->and_(qw0->r32(), 0x3fffc); c->movd(vr, qw0->r32()); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); branch_set_link(m_pos + 4); branch_indirect(op, true, false); m_pos = -1; } void spu_recompiler::IRET(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(srr0)); branch_indirect(op); m_pos = -1; } void spu_recompiler::BISLED(spu_opcode_t op) { auto get_events = [](spu_thread* _spu) -> u32 { return _spu->get_events(_spu->ch_events.load().mask).count; }; c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); const XmmLink& vr = XmmAlloc(); c->lea(*qw0, get_pc(m_pos + 4)); c->movd(vr, qw0->r32()); c->pand(vr, XmmConst(_mm_set1_epi32(0x3fffc))); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); asmjit::Label branch_label = c->newLabel(); c->mov(*arg0, *cpu); c->call(asmjit::imm_ptr(+get_events)); c->test(*addr, 1); c->jne(branch_label); after.emplace_back([=, this]() { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); c->and_(*addr, 0x3fffc); branch_indirect(op, true, false); }); } void spu_recompiler::HBR([[maybe_unused]] spu_opcode_t op) { } void spu_recompiler::GB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pslld(va, 31); c->movmskps(*addr, va); c->pxor(va, va); c->pinsrw(va, *addr, 6); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::GBH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psllw(va, 15); c->packsswb(va, XmmConst(_mm_setzero_si128())); c->pmovmskb(*addr, va); c->pxor(va, va); c->pinsrw(va, *addr, 6); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::GBB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psllq(va, 7); c->pmovmskb(*addr, va); c->pxor(va, va); c->pinsrw(va, *addr, 6); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FSM(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vm = XmmAlloc(); c->pshufd(va, va, 0xff); c->movdqa(vm, XmmConst(_mm_set_epi32(8, 4, 2, 1))); c->pand(va, vm); c->pcmpeqd(va, vm); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FSMH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vm = XmmAlloc(); c->punpckhwd(va, va); c->pshufd(va, va, 0xaa); c->movdqa(vm, XmmConst(_mm_set_epi16(128, 64, 32, 16, 8, 4, 2, 1))); c->pand(va, vm); c->pcmpeqw(va, vm); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FSMB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vm = XmmAlloc(); if (utils::has_ssse3()) { c->pshufb(va, XmmConst(_mm_set_epi8(13, 13, 13, 13, 13, 13, 13, 13, 12, 12, 12, 12, 12, 12, 12, 12))); } else { c->punpckhbw(va, va); c->pshufhw(va, va, 0x50); c->pshufd(va, va, 0xfa); } c->movdqa(vm, XmmConst(_mm_set_epi8(-128, 64, 32, 16, 8, 4, 2, 1, -128, 64, 32, 16, 8, 4, 2, 1))); c->pand(va, vm); c->pcmpeqb(va, vm); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FREST(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); c->rcpps(va, va); c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FRSQEST(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); c->andps(va, XmmConst(_mm_set1_epi32(0x7fffffff))); // abs c->rsqrtps(va, va); c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::LQX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmAlloc(); c->movdqa(vt, asmjit::x86::oword_ptr(*ls, addr->r64())); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } else { c->mov(*qw0, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0)); c->mov(*qw1, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8)); c->bswap(*qw0); c->bswap(*qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 0), *qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 1), *qw0); } } void spu_recompiler::ROTQBYBI(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.rldq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0xf << 3); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64(), 1)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTQMBYBI(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.srdq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x1f << 3); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64(), 1)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SHLQBYBI(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.sldq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x1f << 3); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64(), 1)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CBX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->not_(*addr); c->and_(*addr, 0xf); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::byte_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x03); } void spu_recompiler::CHX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->not_(*addr); c->and_(*addr, 0xe); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::word_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x0203); } void spu_recompiler::CWX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->not_(*addr); c->and_(*addr, 0xc); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::dword_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x00010203); } void spu_recompiler::CDX(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->add(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->not_(*addr); c->and_(*addr, 0x8); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(*qw0, asmjit::Imm(0x0001020304050607ull)); c->mov(asmjit::x86::qword_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), *qw0); } void spu_recompiler::ROTQBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); c->psrldq(vb, 12); c->pand(vb, XmmConst(_mm_set_epi64x(0, 7))); c->movdqa(v4, XmmConst(_mm_set_epi64x(0, 64))); c->pshufd(vt, va, 0x4e); c->psubq(v4, vb); c->psllq(va, vb); c->psrlq(vt, v4); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::ROTQMBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmAlloc(); const XmmLink& vt = XmmGet(op.rb, XmmType::Int); const XmmLink& v4 = XmmAlloc(); c->psrldq(vt, 12); c->pxor(vb, vb); c->psubq(vb, vt); c->pand(vb, XmmConst(_mm_set_epi64x(0, 7))); c->movdqa(v4, XmmConst(_mm_set_epi64x(0, 64))); c->movdqa(vt, va); c->psrldq(vt, 8); c->psubq(v4, vb); c->psrlq(va, vb); c->psllq(vt, v4); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::SHLQBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& v4 = XmmAlloc(); c->psrldq(vb, 12); c->pand(vb, XmmConst(_mm_set_epi64x(0, 7))); c->movdqa(v4, XmmConst(_mm_set_epi64x(0, 64))); c->movdqa(vt, va); c->pslldq(vt, 8); c->psubq(v4, vb); c->psllq(va, vb); c->psrlq(vt, v4); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::ROTQBY(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.rldq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0xf); c->shl(*addr, 4); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64())); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTQMBY(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.srdq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x1f); c->shl(*addr, 4); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64())); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SHLQBY(spu_opcode_t op) { if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->mov(*qw0, asmjit::imm_ptr(+g_spu_imm.sldq_pshufb)); c->mov(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); c->and_(*addr, 0x1f); c->shl(*addr, 4); c->pshufb(va, asmjit::x86::oword_ptr(*qw0, addr->r64())); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ORX(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v1 = XmmAlloc(); c->pshufd(v1, va, 0xb1); c->por(va, v1); c->pshufd(v1, va, 0x4e); c->por(va, v1); c->pslldq(va, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CBD(spu_opcode_t op) { //if (op.ra == 1) //{ // // assuming that SP % 16 is always zero // const XmmLink& vr = XmmAlloc(); // v128 value = v128::fromV(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f)); // value.u8r[op.i7 & 0xf] = 0x03; // c->movdqa(vr, XmmConst(value)); // c->movdqa(SPU_OFF_128(gpr, op.rt), vr); // return; //} c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.i7) c->add(*addr, +op.i7); c->not_(*addr); c->and_(*addr, 0xf); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::byte_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x03); } void spu_recompiler::CHD(spu_opcode_t op) { //if (op.ra == 1) //{ // // assuming that SP % 16 is always zero // const XmmLink& vr = XmmAlloc(); // v128 value = v128::fromV(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f)); // value.u16r[(op.i7 >> 1) & 0x7] = 0x0203; // c->movdqa(vr, XmmConst(value)); // c->movdqa(SPU_OFF_128(gpr, op.rt), vr); // return; //} c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.i7) c->add(*addr, +op.i7); c->not_(*addr); c->and_(*addr, 0xe); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::word_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x0203); } void spu_recompiler::CWD(spu_opcode_t op) { //if (op.ra == 1) //{ // // assuming that SP % 16 is always zero // const XmmLink& vr = XmmAlloc(); // v128 value = v128::fromV(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f)); // value.u32r[(op.i7 >> 2) & 0x3] = 0x00010203; // c->movdqa(vr, XmmConst(value)); // c->movdqa(SPU_OFF_128(gpr, op.rt), vr); // return; //} c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.i7) c->add(*addr, +op.i7); c->not_(*addr); c->and_(*addr, 0xc); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(asmjit::x86::dword_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), 0x00010203); } void spu_recompiler::CDD(spu_opcode_t op) { //if (op.ra == 1) //{ // // assuming that SP % 16 is always zero // const XmmLink& vr = XmmAlloc(); // v128 value = v128::fromV(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f)); // value.u64r[(op.i7 >> 3) & 0x1] = 0x0001020304050607ull; // c->movdqa(vr, XmmConst(value)); // c->movdqa(SPU_OFF_128(gpr, op.rt), vr); // return; //} c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.i7) c->add(*addr, +op.i7); c->not_(*addr); c->and_(*addr, 0x8); const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set_epi32(0x10111213, 0x14151617, 0x18191a1b, 0x1c1d1e1f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); c->mov(*qw0, asmjit::Imm(0x0001020304050607ull)); c->mov(asmjit::x86::qword_ptr(*cpu, addr->r64(), 0, offset32(&spu_thread::gpr, op.rt)), *qw0); } void spu_recompiler::ROTQBII(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->pshufd(vt, va, 0x4e); // swap 64-bit parts c->psllq(va, (op.i7 & 0x7)); c->psrlq(vt, 64 - (op.i7 & 0x7)); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::ROTQMBII(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->movdqa(vt, va); c->psrldq(vt, 8); c->psrlq(va, ((0 - op.i7) & 0x7)); c->psllq(vt, 64 - ((0 - op.i7) & 0x7)); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::SHLQBII(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->movdqa(vt, va); c->pslldq(vt, 8); c->psllq(va, (op.i7 & 0x7)); c->psrlq(vt, 64 - (op.i7 & 0x7)); c->por(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::ROTQBYI(spu_opcode_t op) { const int s = op.i7 & 0xf; const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v2 = XmmAlloc(); if (s == 0) { } else if (s == 4 || s == 8 || s == 12) { c->pshufd(va, va, utils::rol8(0xE4, s / 2)); } else if (utils::has_ssse3()) { c->palignr(va, va, 16 - s); } else { c->movdqa(v2, va); c->psrldq(va, 16 - s); c->pslldq(v2, s); c->por(va, v2); } c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ROTQMBYI(spu_opcode_t op) { const int s = (0 - op.i7) & 0x1f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psrldq(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SHLQBYI(spu_opcode_t op) { const int s = op.i7 & 0x1f; const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pslldq(va, s); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::NOP(spu_opcode_t) { } void spu_recompiler::CGT(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtd(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::XOR(spu_opcode_t op) { // xor const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CGTH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtw(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::EQV(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); if (utils::has_avx512()) { c->vpternlogd(vb, vb, SPU_OFF_128(gpr, op.ra), 0x99 /* xnorCB */); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); return; } c->pxor(vb, XmmConst(_mm_set1_epi32(0xffffffff))); c->pxor(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::CGTB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtb(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SUMB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& v1 = XmmAlloc(); const XmmLink& v2 = XmmAlloc(); c->movdqa(v2, XmmConst(_mm_set1_epi16(0xff))); c->movdqa(v1, va); c->psrlw(va, 8); c->pand(v1, v2); c->pand(v2, vb); c->psrlw(vb, 8); c->paddw(va, v1); c->paddw(vb, v2); c->movdqa(v2, XmmConst(_mm_set1_epi32(0xffff))); c->movdqa(v1, va); c->psrld(va, 16); c->pand(v1, v2); c->pandn(v2, vb); c->pslld(vb, 16); c->paddw(va, v1); c->paddw(vb, v2); c->por(va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::HGT(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_s32, 3)); c->cmp(*addr, SPU_OFF_32(gpr, op.rb, &v128::_s32, 3)); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->jg(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::CLZ(spu_opcode_t op) { if (utils::has_avx512()) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vt = XmmAlloc(); c->vplzcntd(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); return; } c->mov(qw0->r32(), 32 + 31); for (u32 i = 0; i < 4; i++) // unrolled loop { c->bsr(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, i)); c->cmovz(*addr, qw0->r32()); c->xor_(*addr, 31); c->mov(SPU_OFF_32(gpr, op.rt, &v128::_u32, i), *addr); } } void spu_recompiler::XSWD(spu_opcode_t op) { c->movsxd(*qw0, SPU_OFF_32(gpr, op.ra, &v128::_s32, 0)); c->movsxd(*qw1, SPU_OFF_32(gpr, op.ra, &v128::_s32, 2)); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_s64, 0), *qw0); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_s64, 1), *qw1); } void spu_recompiler::XSHW(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pslld(va, 16); c->psrad(va, 16); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CNTB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v1 = XmmAlloc(); const XmmLink& vm = XmmAlloc(); c->movdqa(vm, XmmConst(_mm_set1_epi8(0x55))); c->movdqa(v1, va); c->pand(va, vm); c->psrlq(v1, 1); c->pand(v1, vm); c->paddb(va, v1); c->movdqa(vm, XmmConst(_mm_set1_epi8(0x33))); c->movdqa(v1, va); c->pand(va, vm); c->psrlq(v1, 2); c->pand(v1, vm); c->paddb(va, v1); c->movdqa(vm, XmmConst(_mm_set1_epi8(0x0f))); c->movdqa(v1, va); c->pand(va, vm); c->psrlq(v1, 4); c->pand(v1, vm); c->paddb(va, v1); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::XSBH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psllw(va, 8); c->psraw(va, 8); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CLGT(spu_opcode_t op) { // compare if-greater-than const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vi = XmmAlloc(); c->movdqa(vi, XmmConst(_mm_set1_epi32(0x80000000))); c->pxor(va, vi); c->pxor(vi, SPU_OFF_128(gpr, op.rb)); c->pcmpgtd(va, vi); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ANDC(spu_opcode_t op) { // and not const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->pandn(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::FCGT(spu_opcode_t op) { const auto last_exp_bit = XmmConst(_mm_set1_epi32(0x00800000)); const auto all_exp_bits = XmmConst(_mm_set1_epi32(0x7f800000)); const XmmLink& tmp0 = XmmAlloc(); const XmmLink& tmp1 = XmmAlloc(); const XmmLink& tmp2 = XmmAlloc(); const XmmLink& tmp3 = XmmAlloc(); const XmmLink& tmpv = XmmAlloc(); c->pxor(tmp0, tmp0); c->pxor(tmp1, tmp1); c->cmpps(tmp0, SPU_OFF_128(gpr, op.ra), 3); //tmp0 is true if a is extended (nan/inf) c->cmpps(tmp1, SPU_OFF_128(gpr, op.rb), 3); //tmp1 is true if b is extended (nan/inf) //compute lower a and b c->movaps(tmp2, last_exp_bit); c->movaps(tmp3, last_exp_bit); c->pandn(tmp2, SPU_OFF_128(gpr, op.ra)); //tmp2 = lowered_a c->pandn(tmp3, SPU_OFF_128(gpr, op.rb)); //tmp3 = lowered_b //lower a if extended c->movaps(tmpv, tmp0); c->pand(tmpv, tmp2); c->pandn(tmp0, SPU_OFF_128(gpr, op.ra)); c->orps(tmp0, tmpv); //lower b if extended c->movaps(tmpv, tmp1); c->pand(tmpv, tmp3); c->pandn(tmp1, SPU_OFF_128(gpr, op.rb)); c->orps(tmp1, tmpv); //flush to 0 if denormalized c->pxor(tmpv, tmpv); c->movaps(tmp2, SPU_OFF_128(gpr, op.ra)); c->movaps(tmp3, SPU_OFF_128(gpr, op.rb)); c->andps(tmp2, all_exp_bits); c->andps(tmp3, all_exp_bits); c->cmpps(tmp2, tmpv, 0); c->cmpps(tmp3, tmpv, 0); c->pandn(tmp2, tmp0); c->pandn(tmp3, tmp1); c->cmpps(tmp3, tmp2, 1); c->movaps(SPU_OFF_128(gpr, op.rt), tmp3); } void spu_recompiler::DFCGT(spu_opcode_t op) { UNK(op); } void spu_recompiler::FA(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); c->addps(va, SPU_OFF_128(gpr, op.rb)); c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); c->subps(va, SPU_OFF_128(gpr, op.rb)); c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FM(spu_opcode_t op) { const auto sign_bits = XmmConst(_mm_set1_epi32(0x80000000)); const auto all_exp_bits = XmmConst(_mm_set1_epi32(0x7f800000)); const XmmLink& tmp0 = XmmAlloc(); const XmmLink& tmp1 = XmmAlloc(); const XmmLink& tmp2 = XmmAlloc(); const XmmLink& tmp3 = XmmAlloc(); const XmmLink& tmp4 = XmmGet(op.ra, XmmType::Float); const XmmLink& tmp5 = XmmGet(op.rb, XmmType::Float); //check denormals c->pxor(tmp0, tmp0); c->movaps(tmp1, all_exp_bits); c->movaps(tmp2, all_exp_bits); c->andps(tmp1, tmp4); c->andps(tmp2, tmp5); c->cmpps(tmp1, tmp0, 0); c->cmpps(tmp2, tmp0, 0); c->orps(tmp1, tmp2); //denormal operand mask //compute result with flushed denormal inputs c->movaps(tmp2, tmp4); c->mulps(tmp2, tmp5); //primary result c->movaps(tmp3, tmp2); c->andps(tmp3, all_exp_bits); c->cmpps(tmp3, tmp0, 0); //denom mask from result c->orps(tmp3, tmp1); c->andnps(tmp3, tmp2); //flushed result //compute results for the extended path c->andps(tmp2, all_exp_bits); c->cmpps(tmp2, all_exp_bits, 0); //extended mask c->movaps(tmp4, sign_bits); c->movaps(tmp5, sign_bits); c->movaps(tmp0, sign_bits); c->andps(tmp4, SPU_OFF_128(gpr, op.ra)); c->andps(tmp5, SPU_OFF_128(gpr, op.rb)); c->xorps(tmp4, tmp5); //sign mask c->pandn(tmp0, tmp2); c->orps(tmp4, tmp0); //add result sign back to original extended value c->movaps(tmp5, tmp1); //denormal mask (operands) c->andnps(tmp5, tmp4); //max_float with sign bit (nan/-nan) where not denormal or zero //select result c->movaps(tmp0, tmp2); c->andnps(tmp0, tmp3); c->andps(tmp2, tmp5); c->orps(tmp0, tmp2); c->movaps(SPU_OFF_128(gpr, op.rt), tmp0); } void spu_recompiler::CLGTH(spu_opcode_t op) { // compare if-greater-than const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vi = XmmAlloc(); c->movdqa(vi, XmmConst(_mm_set1_epi16(smin))); c->pxor(va, vi); c->pxor(vi, SPU_OFF_128(gpr, op.rb)); c->pcmpgtw(va, vi); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ORC(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); if (utils::has_avx512()) { c->vpternlogd(vb, vb, SPU_OFF_128(gpr, op.ra), 0xbb /* orC!B */); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); return; } c->pxor(vb, XmmConst(_mm_set1_epi32(0xffffffff))); c->por(vb, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::FCMGT(spu_opcode_t op) { // reverted less-than // since comparison is absoulte, a > b if a is extended and b is not extended // flush denormals to zero to make zero == zero work const auto all_exp_bits = XmmConst(_mm_set1_epi32(0x7f800000)); const auto remove_sign_bits = XmmConst(_mm_set1_epi32(0x7fffffff)); const XmmLink& tmp0 = XmmAlloc(); const XmmLink& tmp1 = XmmAlloc(); const XmmLink& tmp2 = XmmAlloc(); const XmmLink& tmp3 = XmmAlloc(); const XmmLink& tmpv = XmmAlloc(); c->pxor(tmp0, tmp0); c->pxor(tmp1, tmp1); c->cmpps(tmp0, SPU_OFF_128(gpr, op.ra), 3); //tmp0 is true if a is extended (nan/inf) c->cmpps(tmp1, SPU_OFF_128(gpr, op.rb), 3); //tmp1 is true if b is extended (nan/inf) //flush to 0 if denormalized c->pxor(tmpv, tmpv); c->movaps(tmp2, SPU_OFF_128(gpr, op.ra)); c->movaps(tmp3, SPU_OFF_128(gpr, op.rb)); c->andps(tmp2, all_exp_bits); c->andps(tmp3, all_exp_bits); c->cmpps(tmp2, tmpv, 0); c->cmpps(tmp3, tmpv, 0); c->pandn(tmp2, SPU_OFF_128(gpr, op.ra)); c->pandn(tmp3, SPU_OFF_128(gpr, op.rb)); //Set tmp1 to true where a is extended but b is not extended //This is a simplification since absolute values remove necessity of lowering c->xorps(tmp0, tmp1); //tmp0 is true when either a or b is extended c->pandn(tmp1, tmp0); //tmp1 is true if b is not extended and a is extended c->andps(tmp2, remove_sign_bits); c->andps(tmp3, remove_sign_bits); c->cmpps(tmp3, tmp2, 1); c->orps(tmp3, tmp1); //Force result to all true if a is extended but b is not c->movaps(SPU_OFF_128(gpr, op.rt), tmp3); } void spu_recompiler::DFCMGT(spu_opcode_t op) { UNK(op); } void spu_recompiler::DFA(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->addpd(va, SPU_OFF_128(gpr, op.rb)); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::DFS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->subpd(va, SPU_OFF_128(gpr, op.rb)); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::DFM(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->mulpd(va, SPU_OFF_128(gpr, op.rb)); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CLGTB(spu_opcode_t op) { // compare if-greater-than const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vi = XmmAlloc(); c->movdqa(vi, XmmConst(_mm_set1_epi8(smin))); c->pxor(va, vi); c->pxor(vi, SPU_OFF_128(gpr, op.rb)); c->pcmpgtb(va, vi); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::HLGT(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); c->cmp(*addr, SPU_OFF_32(gpr, op.rb, &v128::_u32, 3)); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->ja(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::DFMA(spu_opcode_t op) { const XmmLink& vr = XmmGet(op.rt, XmmType::Double); const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->mulpd(va, SPU_OFF_128(gpr, op.rb)); c->addpd(vr, va); c->movapd(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::DFMS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); const XmmLink& vt = XmmGet(op.rt, XmmType::Double); c->mulpd(va, SPU_OFF_128(gpr, op.rb)); c->subpd(va, vt); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::DFNMS(spu_opcode_t op) { const XmmLink& vr = XmmGet(op.rt, XmmType::Double); const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->mulpd(va, SPU_OFF_128(gpr, op.rb)); c->subpd(vr, va); c->movapd(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::DFNMA(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); const XmmLink& vt = XmmGet(op.rt, XmmType::Double); c->mulpd(va, SPU_OFF_128(gpr, op.rb)); c->addpd(va, vt); c->xorpd(va, XmmConst(_mm_set1_epi64x(0x8000000000000000))); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQ(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqd(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::MPYHHU(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& va2 = XmmAlloc(); c->movdqa(va2, va); c->pmulhuw(va, vb); c->pmullw(va2, vb); c->pand(va, XmmConst(_mm_set1_epi32(0xffff0000))); c->psrld(va2, 16); c->por(va, va2); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ADDX(spu_opcode_t op) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->pand(vt, XmmConst(_mm_set1_epi32(1))); c->paddd(vt, SPU_OFF_128(gpr, op.ra)); c->paddd(vt, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::SFX(spu_opcode_t op) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->pandn(vt, XmmConst(_mm_set1_epi32(1))); c->psubd(vb, SPU_OFF_128(gpr, op.ra)); c->psubd(vb, vt); c->movdqa(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::CGX(spu_opcode_t op) //nf { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& res = XmmAlloc(); const XmmLink& sign = XmmAlloc(); c->pslld(vt, 31); c->psrad(vt, 31); if (utils::has_avx()) { c->vpaddd(res, va, vb); } else { c->movdqa(res, va); c->paddd(res, vb); } c->movdqa(sign, XmmConst(_mm_set1_epi32(smin))); c->pxor(va, sign); c->pxor(res, sign); c->pcmpgtd(va, res); c->pxor(res, sign); c->pcmpeqd(res, vt); c->pand(res, vt); c->por(res, va); c->psrld(res, 31); c->movdqa(SPU_OFF_128(gpr, op.rt), res); } void spu_recompiler::BGX(spu_opcode_t op) //nf { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& temp = XmmAlloc(); const XmmLink& sign = XmmAlloc(); c->pslld(vt, 31); if (utils::has_avx()) { c->vpcmpeqd(temp, vb, va); } else { c->movdqa(temp, vb); c->pcmpeqd(temp, va); } c->pand(vt, temp); c->movdqa(sign, XmmConst(_mm_set1_epi32(smin))); c->pxor(va, sign); c->pxor(vb, sign); c->pcmpgtd(vb, va); c->por(vt, vb); c->psrld(vt, 31); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::MPYHHA(spu_opcode_t op) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->psrld(va, 16); c->psrld(vb, 16); c->pmaddwd(va, vb); c->paddd(vt, va); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::MPYHHAU(spu_opcode_t op) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& va2 = XmmAlloc(); c->movdqa(va2, va); c->pmulhuw(va, vb); c->pmullw(va2, vb); c->pand(va, XmmConst(_mm_set1_epi32(0xffff0000))); c->psrld(va2, 16); c->paddd(vt, va); c->paddd(vt, va2); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::FSCRRD(spu_opcode_t op) { // zero (hack) const XmmLink& v0 = XmmAlloc(); c->pxor(v0, v0); c->movdqa(SPU_OFF_128(gpr, op.rt), v0); } void spu_recompiler::FESD(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); c->shufps(va, va, 0x8d); // _f[0] = _f[1]; _f[1] = _f[3]; c->cvtps2pd(va, va); c->movapd(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FRDS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Double); c->cvtpd2ps(va, va); c->shufps(va, va, 0x72); // _f[1] = _f[0]; _f[3] = _f[1]; _f[0] = _f[2] = 0; c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FSCRWR(spu_opcode_t /*op*/) { // nop (not implemented) } void spu_recompiler::DFTSV(spu_opcode_t op) { UNK(op); } void spu_recompiler::FCEQ(spu_opcode_t op) { // compare equal const XmmLink& vb = XmmGet(op.rb, XmmType::Float); c->cmpps(vb, SPU_OFF_128(gpr, op.ra), 0); c->movaps(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::DFCEQ(spu_opcode_t op) { UNK(op); } void spu_recompiler::MPY(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vi = XmmAlloc(); c->movdqa(vi, XmmConst(_mm_set1_epi32(0xffff))); c->pand(va, vi); c->pand(vb, vi); c->pmaddwd(va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::MPYH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->psrld(va, 16); c->pmullw(va, vb); c->pslld(va, 16); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::MPYHH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->psrld(va, 16); c->psrld(vb, 16); c->pmaddwd(va, vb); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::MPYS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); c->pmulhw(va, vb); c->pslld(va, 16); c->psrad(va, 16); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQH(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqw(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FCMEQ(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Float); const XmmLink& vi = XmmAlloc(); c->movaps(vi, XmmConst(_mm_set1_epi32(0x7fffffff))); c->andps(vb, vi); // abs c->andps(vi, SPU_OFF_128(gpr, op.ra)); c->cmpps(vb, vi, 0); // == c->movaps(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::DFCMEQ(spu_opcode_t op) { UNK(op); } void spu_recompiler::MPYU(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& va2 = XmmAlloc(); c->movdqa(va2, va); c->pmulhuw(va, vb); c->pmullw(va2, vb); c->pslld(va, 16); c->pand(va2, XmmConst(_mm_set1_epi32(0xffff))); c->por(va, va2); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQB(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqb(va, SPU_OFF_128(gpr, op.rb)); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::FI(spu_opcode_t op) { // Floating Interpolate const XmmLink& vb = XmmGet(op.rb, XmmType::Float); c->movaps(SPU_OFF_128(gpr, op.rt), vb); } void spu_recompiler::HEQ(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_s32, 3)); c->cmp(*addr, SPU_OFF_32(gpr, op.rb, &v128::_s32, 3)); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->je(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::CFLTS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); const XmmLink& vi = XmmAlloc(); if (op.i8 != 173) c->mulps(va, XmmConst(_mm_set1_ps(std::exp2(static_cast(static_cast(173 - op.i8)))))); // scale c->movaps(vi, XmmConst(_mm_set1_ps(std::exp2(31.f)))); c->cmpps(vi, va, 2); c->cvttps2dq(va, va); // convert to ints with truncation c->pxor(va, vi); // fix result saturation (0x80000000 -> 0x7fffffff) c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CFLTU(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); const XmmLink& vs = XmmAlloc(); const XmmLink& vs2 = XmmAlloc(); const XmmLink& vs3 = XmmAlloc(); if (op.i8 != 173) c->mulps(va, XmmConst(_mm_set1_ps(std::exp2(static_cast(static_cast(173 - op.i8)))))); // scale if (utils::has_avx512()) { c->vcvttps2udq(vs, va); c->psrad(va, 31); c->pandn(va, vs); c->movdqa(SPU_OFF_128(gpr, op.rt), va); return; } c->movdqa(vs, va); c->psrad(va, 31); c->andnps(va, vs); c->movaps(vs, va); // copy scaled value c->movaps(vs2, va); c->movaps(vs3, XmmConst(_mm_set1_ps(std::exp2(31.f)))); c->subps(vs2, vs3); c->cmpps(vs3, vs, 2); c->andps(vs2, vs3); c->cvttps2dq(va, va); c->cmpps(vs, XmmConst(_mm_set1_ps(std::exp2(32.f))), 5); c->cvttps2dq(vs2, vs2); c->por(va, vs); c->por(va, vs2); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CSFLT(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->cvtdq2ps(va, va); // convert to floats if (op.i8 != 155) c->mulps(va, XmmConst(_mm_set1_ps(std::exp2(static_cast(static_cast(op.i8 - 155)))))); // scale c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CUFLT(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& v1 = XmmAlloc(); if (utils::has_avx512()) { c->vcvtudq2ps(va, va); } else { c->movdqa(v1, va); c->pand(va, XmmConst(_mm_set1_epi32(0x7fffffff))); c->cvtdq2ps(va, va); // convert to floats c->psrad(v1, 31); // generate mask from sign bit c->andps(v1, XmmConst(_mm_set1_ps(std::exp2(31.f)))); // generate correction component c->addps(va, v1); // add correction component } if (op.i8 != 155) c->mulps(va, XmmConst(_mm_set1_ps(std::exp2(static_cast(static_cast(op.i8 - 155)))))); // scale c->movaps(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::BRZ(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); if (target == m_pos + 4) { return; } asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_32(gpr, op.rt, &v128::_u32, 3), 0); c->je(branch_label); after.emplace_back([=, this]() { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); branch_fixed(target); }); } void spu_recompiler::STQA(spu_opcode_t op) { if (utils::has_ssse3()) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(asmjit::x86::oword_ptr(*ls, spu_ls_target(0, op.i16)), vt); } else { c->mov(*qw0, SPU_OFF_64(gpr, op.rt, &v128::_u64, 0)); c->mov(*qw1, SPU_OFF_64(gpr, op.rt, &v128::_u64, 1)); c->bswap(*qw0); c->bswap(*qw1); c->mov(asmjit::x86::qword_ptr(*ls, spu_ls_target(0, op.i16) + 0), *qw1); c->mov(asmjit::x86::qword_ptr(*ls, spu_ls_target(0, op.i16) + 8), *qw0); } } void spu_recompiler::BRNZ(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); if (target == m_pos + 4) { return; } asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_32(gpr, op.rt, &v128::_u32, 3), 0); c->jne(branch_label); after.emplace_back([=, this]() { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); branch_fixed(target); }); } void spu_recompiler::BRHZ(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); if (target == m_pos + 4) { return; } asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_16(gpr, op.rt, &v128::_u16, 6), 0); c->je(branch_label); after.emplace_back([=, this]() { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); branch_fixed(target); }); } void spu_recompiler::BRHNZ(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); if (target == m_pos + 4) { return; } asmjit::Label branch_label = c->newLabel(); c->cmp(SPU_OFF_16(gpr, op.rt, &v128::_u16, 6), 0); c->jne(branch_label); after.emplace_back([=, this]() { c->align(asmjit::AlignMode::kCode, 16); c->bind(branch_label); branch_fixed(target); }); } void spu_recompiler::STQR(spu_opcode_t op) { c->lea(addr->r64(), get_pc(spu_ls_target(m_pos, op.i16))); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(asmjit::x86::oword_ptr(*ls, addr->r64()), vt); } else { c->mov(*qw0, SPU_OFF_64(gpr, op.rt, &v128::_u64, 0)); c->mov(*qw1, SPU_OFF_64(gpr, op.rt, &v128::_u64, 1)); c->bswap(*qw0); c->bswap(*qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0), *qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8), *qw0); } } void spu_recompiler::BRA(spu_opcode_t op) { const u32 target = spu_branch_target(0, op.i16); branch_fixed(target, true); m_pos = -1; } void spu_recompiler::LQA(spu_opcode_t op) { if (utils::has_ssse3()) { const XmmLink& vt = XmmAlloc(); c->movdqa(vt, asmjit::x86::oword_ptr(*ls, spu_ls_target(0, op.i16))); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } else { c->mov(*qw0, asmjit::x86::qword_ptr(*ls, spu_ls_target(0, op.i16) + 0)); c->mov(*qw1, asmjit::x86::qword_ptr(*ls, spu_ls_target(0, op.i16) + 8)); c->bswap(*qw0); c->bswap(*qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 0), *qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 1), *qw0); } } void spu_recompiler::BRASL(spu_opcode_t op) { const u32 target = spu_branch_target(0, op.i16); const XmmLink& vr = XmmAlloc(); c->lea(addr->r64(), get_pc(m_pos + 4)); c->and_(*addr, 0x3fffc); c->movd(vr, *addr); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); branch_set_link(m_pos + 4); branch_fixed(target, true); m_pos = -1; } void spu_recompiler::BR(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); if (target != m_pos + 4) { branch_fixed(target); m_pos = -1; } } void spu_recompiler::FSMBI(spu_opcode_t op) { v128 data; for (u32 i = 0; i < 16; i++) data._u8[i] = op.i16 & (1u << i) ? 0xff : 0; const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(data)); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::BRSL(spu_opcode_t op) { const u32 target = spu_branch_target(m_pos, op.i16); const XmmLink& vr = XmmAlloc(); c->lea(addr->r64(), get_pc(m_pos + 4)); c->and_(*addr, 0x3fffc); c->movd(vr, *addr); c->pslldq(vr, 12); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); if (target != m_pos + 4) { branch_set_link(m_pos + 4); branch_fixed(target); m_pos = -1; } } void spu_recompiler::LQR(spu_opcode_t op) { c->lea(addr->r64(), get_pc(spu_ls_target(m_pos, op.i16))); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmAlloc(); c->movdqa(vt, asmjit::x86::oword_ptr(*ls, addr->r64())); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } else { c->mov(*qw0, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0)); c->mov(*qw1, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8)); c->bswap(*qw0); c->bswap(*qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 0), *qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 1), *qw0); } } void spu_recompiler::IL(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi32(op.si16))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::ILHU(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi32(op.i16 << 16))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::ILH(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi16(op.i16))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::IOHL(spu_opcode_t op) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->por(vt, XmmConst(_mm_set1_epi32(op.i16))); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } void spu_recompiler::ORI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); if (op.si10) c->por(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ORHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->por(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ORBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->por(va, XmmConst(_mm_set1_epi8(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::SFI(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi32(op.si10))); c->psubd(vr, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::SFHI(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi16(op.si10))); c->psubw(vr, SPU_OFF_128(gpr, op.ra)); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::ANDI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pand(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ANDHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pand(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::ANDBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pand(va, XmmConst(_mm_set1_epi8(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::AI(spu_opcode_t op) { // add const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->paddd(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::AHI(spu_opcode_t op) { // add const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->paddw(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::STQD(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.si10) c->add(*addr, op.si10 * 16); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmGet(op.rt, XmmType::Int); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(asmjit::x86::oword_ptr(*ls, addr->r64()), vt); } else { c->mov(*qw0, SPU_OFF_64(gpr, op.rt, &v128::_u64, 0)); c->mov(*qw1, SPU_OFF_64(gpr, op.rt, &v128::_u64, 1)); c->bswap(*qw0); c->bswap(*qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0), *qw1); c->mov(asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8), *qw0); } } void spu_recompiler::LQD(spu_opcode_t op) { c->mov(*addr, SPU_OFF_32(gpr, op.ra, &v128::_u32, 3)); if (op.si10) c->add(*addr, op.si10 * 16); c->and_(*addr, 0x3fff0); if (utils::has_ssse3()) { const XmmLink& vt = XmmAlloc(); c->movdqa(vt, asmjit::x86::oword_ptr(*ls, addr->r64())); c->pshufb(vt, XmmConst(_mm_set_epi32(0x00010203, 0x04050607, 0x08090a0b, 0x0c0d0e0f))); c->movdqa(SPU_OFF_128(gpr, op.rt), vt); } else { c->mov(*qw0, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 0)); c->mov(*qw1, asmjit::x86::qword_ptr(*ls, addr->r64(), 0, 8)); c->bswap(*qw0); c->bswap(*qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 0), *qw1); c->mov(SPU_OFF_64(gpr, op.rt, &v128::_u64, 1), *qw0); } } void spu_recompiler::XORI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::XORHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::XORBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, XmmConst(_mm_set1_epi8(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CGTI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtd(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CGTHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtw(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CGTBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpgtb(va, XmmConst(_mm_set1_epi8(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::HGTI(spu_opcode_t op) { c->cmp(SPU_OFF_32(gpr, op.ra, &v128::_s32, 3), +op.si10); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->jg(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::CLGTI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, XmmConst(_mm_set1_epi32(0x80000000))); c->pcmpgtd(va, XmmConst(_mm_set1_epi32(op.si10 - 0x80000000))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CLGTHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pxor(va, XmmConst(_mm_set1_epi16(smin))); c->pcmpgtw(va, XmmConst(_mm_set1_epi16(op.si10 - 0x8000))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CLGTBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->psubb(va, XmmConst(_mm_set1_epi8(smin))); c->pcmpgtb(va, XmmConst(_mm_set1_epi8(op.si10 - 0x80))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::HLGTI(spu_opcode_t op) { c->cmp(SPU_OFF_32(gpr, op.ra, &v128::_u32, 3), +op.si10); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->ja(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::MPYI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pmaddwd(va, XmmConst(_mm_set1_epi32(op.si10 & 0xffff))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::MPYUI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vi = XmmAlloc(); const XmmLink& va2 = XmmAlloc(); c->movdqa(va2, va); c->movdqa(vi, XmmConst(_mm_set1_epi32(op.si10 & 0xffff))); c->pmulhuw(va, vi); c->pmullw(va2, vi); c->pslld(va, 16); c->por(va, va2); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqd(va, XmmConst(_mm_set1_epi32(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQHI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqw(va, XmmConst(_mm_set1_epi16(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::CEQBI(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); c->pcmpeqb(va, XmmConst(_mm_set1_epi8(op.si10))); c->movdqa(SPU_OFF_128(gpr, op.rt), va); } void spu_recompiler::HEQI(spu_opcode_t op) { c->cmp(SPU_OFF_32(gpr, op.ra, &v128::_u32, 3), +op.si10); asmjit::Label label = c->newLabel(); asmjit::Label ret = c->newLabel(); c->je(label); after.emplace_back([=, this, pos = m_pos] { c->bind(label); c->lea(addr->r64(), get_pc(pos)); c->and_(*addr, 0x3fffc); c->mov(SPU_OFF_32(pc), *addr); c->mov(addr->r64(), reinterpret_cast(vm::base(0xffdead00))); c->mov(asmjit::x86::dword_ptr(addr->r64()), "HALT"_u32); c->jmp(ret); }); } void spu_recompiler::HBRA([[maybe_unused]] spu_opcode_t op) { } void spu_recompiler::HBRR([[maybe_unused]] spu_opcode_t op) { } void spu_recompiler::ILA(spu_opcode_t op) { const XmmLink& vr = XmmAlloc(); c->movdqa(vr, XmmConst(_mm_set1_epi32(op.i18))); c->movdqa(SPU_OFF_128(gpr, op.rt), vr); } void spu_recompiler::SELB(spu_opcode_t op) { const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vc = XmmGet(op.rc, XmmType::Int); if (utils::has_avx512()) { c->vpternlogd(vc, vb, SPU_OFF_128(gpr, op.ra), 0xca /* A?B:C */); c->movdqa(SPU_OFF_128(gpr, op.rt4), vc); return; } if (utils::has_xop()) { c->vpcmov(vc, vb, SPU_OFF_128(gpr, op.ra), vc); c->movdqa(SPU_OFF_128(gpr, op.rt4), vc); return; } c->pand(vb, vc); c->pandn(vc, SPU_OFF_128(gpr, op.ra)); c->por(vb, vc); c->movdqa(SPU_OFF_128(gpr, op.rt4), vb); } void spu_recompiler::SHUFB(spu_opcode_t op) { if (0 && utils::has_avx512()) { // Deactivated due to poor performance of mask merge ops. const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vc = XmmGet(op.rc, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& vm = XmmAlloc(); c->vpcmpub(asmjit::x86::k1, vc, XmmConst(_mm_set1_epi8(-0x40)), 5 /* GE */); c->vpxor(vm, vc, XmmConst(_mm_set1_epi8(0xf))); c->setExtraReg(asmjit::x86::k1); c->z().vpblendmb(vc, vc, XmmConst(_mm_set1_epi8(-1))); // {k1} c->vpcmpub(asmjit::x86::k2, vm, XmmConst(_mm_set1_epi8(-0x20)), 5 /* GE */); c->vptestmb(asmjit::x86::k1, vm, XmmConst(_mm_set1_epi8(0x10))); c->vpshufb(vt, va, vm); c->setExtraReg(asmjit::x86::k2); c->z().vpblendmb(va, va, XmmConst(_mm_set1_epi8(0x7f))); // {k2} c->setExtraReg(asmjit::x86::k1); c->vpshufb(vt, vb, vm); // {k1} c->vpternlogd(vt, va, vc, 0xf6 /* orAxorBC */); c->movdqa(SPU_OFF_128(gpr, op.rt4), vt); return; } if (!utils::has_ssse3()) { return fall(op); } const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vc = XmmGet(op.rc, XmmType::Int); const XmmLink& vt = XmmAlloc(); const XmmLink& vm = XmmAlloc(); const XmmLink& v5 = XmmAlloc(); c->movdqa(vm, XmmConst(_mm_set1_epi8(static_cast(0xc0)))); if (utils::has_avx()) { c->vpand(v5, vc, XmmConst(_mm_set1_epi8(static_cast(0xe0)))); c->vpxor(vc, vc, XmmConst(_mm_set1_epi8(0xf))); c->vpshufb(va, va, vc); c->vpslld(vt, vc, 3); c->vpcmpeqb(v5, v5, vm); c->vpshufb(vb, vb, vc); c->vpand(vc, vc, vm); c->vpblendvb(vb, va, vb, vt); c->vpcmpeqb(vt, vc, vm); c->vpavgb(vt, vt, v5); c->vpor(vt, vt, vb); } else { c->movdqa(v5, vc); c->pand(v5, XmmConst(_mm_set1_epi8(static_cast(0xe0)))); c->movdqa(vt, vc); c->pand(vt, vm); c->pxor(vc, XmmConst(_mm_set1_epi8(0xf))); c->pshufb(va, vc); c->pshufb(vb, vc); c->pslld(vc, 3); c->pcmpeqb(v5, vm); // If true, result should become 0xFF c->pcmpeqb(vt, vm); // If true, result should become either 0xFF or 0x80 c->pcmpeqb(vm, vm); c->pcmpgtb(vc, vm); c->pand(va, vc); c->pandn(vc, vb); c->por(vc, va); // Select result value from va or vb c->pavgb(vt, v5); // Generate result constant: AVG(0xff, 0x00) == 0x80 c->por(vt, vc); } c->movdqa(SPU_OFF_128(gpr, op.rt4), vt); } void spu_recompiler::MPYA(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Int); const XmmLink& vb = XmmGet(op.rb, XmmType::Int); const XmmLink& vi = XmmAlloc(); c->movdqa(vi, XmmConst(_mm_set1_epi32(0xffff))); c->pand(va, vi); c->pand(vb, vi); c->pmaddwd(va, vb); c->paddd(va, SPU_OFF_128(gpr, op.rc)); c->movdqa(SPU_OFF_128(gpr, op.rt4), va); } void spu_recompiler::FNMS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); const XmmLink& vb = XmmGet(op.rb, XmmType::Float); const XmmLink& mask = XmmAlloc(); const XmmLink& v1 = XmmAlloc(); const XmmLink& v2 = XmmAlloc(); c->movaps(mask, XmmConst(_mm_set1_epi32(0x7f800000))); c->movaps(v1, va); c->movaps(v2, vb); c->andps(va, mask); c->andps(vb, mask); c->cmpps(va, mask, 4); // va = ra == extended c->cmpps(vb, mask, 4); // vb = rb == extended c->andps(va, v1); // va = ra & ~ra_extended c->andps(vb, v2); // vb = rb & ~rb_extended c->mulps(va, vb); c->movaps(vb, SPU_OFF_128(gpr, op.rc)); c->subps(vb, va); c->movaps(SPU_OFF_128(gpr, op.rt4), vb); } void spu_recompiler::FMA(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); const XmmLink& vb = XmmGet(op.rb, XmmType::Float); const XmmLink& mask = XmmAlloc(); const XmmLink& v1 = XmmAlloc(); const XmmLink& v2 = XmmAlloc(); c->movaps(mask, XmmConst(_mm_set1_epi32(0x7f800000))); c->movaps(v1, va); c->movaps(v2, vb); c->andps(va, mask); c->andps(vb, mask); c->cmpps(va, mask, 4); // va = ra == extended c->cmpps(vb, mask, 4); // vb = rb == extended c->andps(va, v1); // va = ra & ~ra_extended c->andps(vb, v2); // vb = rb & ~rb_extended c->mulps(va, vb); c->addps(va, SPU_OFF_128(gpr, op.rc)); c->movaps(SPU_OFF_128(gpr, op.rt4), va); } void spu_recompiler::FMS(spu_opcode_t op) { const XmmLink& va = XmmGet(op.ra, XmmType::Float); const XmmLink& vb = XmmGet(op.rb, XmmType::Float); const XmmLink& mask = XmmAlloc(); const XmmLink& v1 = XmmAlloc(); const XmmLink& v2 = XmmAlloc(); c->movaps(mask, XmmConst(_mm_set1_epi32(0x7f800000))); c->movaps(v1, va); c->movaps(v2, vb); c->andps(va, mask); c->andps(vb, mask); c->cmpps(va, mask, 4); // va = ra == extended c->cmpps(vb, mask, 4); // vb = rb == extended c->andps(va, v1); // va = ra & ~ra_extended c->andps(vb, v2); // vb = rb & ~rb_extended c->mulps(va, vb); c->subps(va, SPU_OFF_128(gpr, op.rc)); c->movaps(SPU_OFF_128(gpr, op.rt4), va); }