/* * Copyright (c) 2020, Andreas Kling * Copyright (c) 2021, Leon Albrecht * * SPDX-License-Identifier: BSD-2-Clause */ #include "SoftFPU.h" #include "Emulator.h" #include "SoftCPU.h" #include "ValueWithShadow.h" #include #include #include #include #if defined(__GNUC__) && !defined(__clang__) # pragma GCC optimize("O3") #endif #define TODO_INSN() \ do { \ reportln("\n=={}== Unimplemented instruction: {}\n", getpid(), __FUNCTION__); \ m_emulator.dump_backtrace(); \ _exit(0); \ } while (0) template ALWAYS_INLINE void warn_if_uninitialized(T value_with_shadow, const char* message) { if (value_with_shadow.is_uninitialized()) [[unlikely]] { reportln("\033[31;1mWarning! Use of uninitialized value: {}\033[0m\n", message); UserspaceEmulator::Emulator::the().dump_backtrace(); } } namespace UserspaceEmulator { ALWAYS_INLINE void SoftFPU::warn_if_fpu_not_set_absolute(u8 index) const { if (!fpu_is_set(index)) [[unlikely]] { // FIXME: Are we supposed to set a flag here? // We might need to raise a stack underflow here reportln("\033[31;1mWarning! Read of uninitialized value on the FPU Stack ({} abs)\033[0m\n", index); m_emulator.dump_backtrace(); } } ALWAYS_INLINE void SoftFPU::warn_if_mmx_absolute(u8 index) const { if (m_reg_is_mmx[index]) [[unlikely]] { reportln("\033[31;1mWarning! Use of an MMX register as an FPU value ({} abs)\033[0m\n", index); m_emulator.dump_backtrace(); } } ALWAYS_INLINE void SoftFPU::warn_if_fpu_absolute(u8 index) const { if (!m_reg_is_mmx[index]) [[unlikely]] { reportln("\033[31;1mWarning! Use of an FPU value ({} abs) as an MMX register\033[0m\n", index); m_emulator.dump_backtrace(); } } ALWAYS_INLINE long double SoftFPU::fpu_get(u8 index) const { VERIFY(index < 8); warn_if_fpu_not_set_absolute(index); warn_if_mmx_absolute(index); u8 effective_index = (m_fpu_stack_top + index) % 8; return m_storage[effective_index].fp; } ALWAYS_INLINE void SoftFPU::fpu_set_absolute(u8 index, long double value) { VERIFY(index < 8); set_tag_from_value_absolute(index, value); m_storage[index].fp = value; m_reg_is_mmx[index] = false; } ALWAYS_INLINE void SoftFPU::fpu_set(u8 index, long double value) { VERIFY(index < 8); fpu_set_absolute((m_fpu_stack_top + index) % 8, value); } ALWAYS_INLINE MMX SoftFPU::mmx_get(u8 index) const { VERIFY(index < 8); warn_if_fpu_absolute(index); return m_storage[index].mmx; } ALWAYS_INLINE void SoftFPU::mmx_set(u8 index, MMX value) { m_storage[index].mmx = value; // The high bytes are set to 0b11... to make the floatingpoint value NaN. // This way we are technically able to find out if we are reading the wrong // type, but this is still difficult, so we use our own lookup for that // We set the alignment bytes to all 1's, too, just in case m_storage[index].__high = ~(decltype(m_storage[index].__high))0u; m_reg_is_mmx[index] = true; } ALWAYS_INLINE void SoftFPU::fpu_push(long double value) { if (fpu_is_set(7)) fpu_set_stack_overflow(); m_fpu_stack_top = (m_fpu_stack_top - 1u) % 8; fpu_set(0, value); } ALWAYS_INLINE long double SoftFPU::fpu_pop() { warn_if_mmx_absolute(m_fpu_stack_top); if (!fpu_is_set(0)) fpu_set_stack_underflow(); auto ret = fpu_get(0); fpu_set_tag(0, FPU_Tag::Empty); m_fpu_stack_top = (m_fpu_stack_top + 1u) % 8; return ret; } ALWAYS_INLINE void SoftFPU::fpu_set_exception(FPU_Exception ex) { switch (ex) { case FPU_Exception::StackFault: m_fpu_error_stackfault = 1; m_fpu_error_invalid = 1; // Implies InvalidOperation break; case FPU_Exception::InvalidOperation: m_fpu_error_invalid = 1; if (!m_fpu_mask_invalid) break; return; case FPU_Exception::DenormalizedOperand: m_fpu_error_denorm = 1; if (!m_fpu_mask_denorm) break; return; case FPU_Exception::ZeroDivide: m_fpu_error_zero_div = 1; if (!m_fpu_mask_zero_div) break; return; case FPU_Exception::Overflow: m_fpu_error_overflow = 1; if (!m_fpu_mask_overflow) break; return; case FPU_Exception::Underflow: m_fpu_error_underflow = 1; if (!m_fpu_mask_underflow) break; return; case FPU_Exception::Precision: m_fpu_error_precision = 1; if (!m_fpu_mask_precision) break; return; } // set exception bit m_fpu_error_summary = 1; // FIXME: set traceback // For that we need to get the currently executing instruction and // the previous eip // FIXME: Call FPU Exception handler reportln("Trying to call Exception handler from {}", fpu_exception_string(ex)); fpu_dump_env(); m_emulator.dump_backtrace(); TODO(); } template ALWAYS_INLINE T SoftFPU::fpu_round(long double value) const { // FIXME: may need to set indefinite values manually switch (fpu_get_round_mode()) { case RoundingMode::NEAREST: return static_cast(roundl(value)); case RoundingMode::DOWN: return static_cast(floorl(value)); case RoundingMode::UP: return static_cast(ceill(value)); case RoundingMode::TRUNK: return static_cast(truncl(value)); default: VERIFY_NOT_REACHED(); } } template ALWAYS_INLINE T SoftFPU::fpu_round_checked(long double value) { T result = fpu_round(value); if (auto rnd = value - result) { if (rnd > 0) set_c1(1); else set_c1(0); fpu_set_exception(FPU_Exception::Precision); } return result; } template ALWAYS_INLINE T SoftFPU::fpu_convert(long double value) const { // FIXME: actually round the right way return static_cast(value); } template ALWAYS_INLINE T SoftFPU::fpu_convert_checked(long double value) { T result = fpu_convert(value); if (auto rnd = value - result) { if (rnd > 0) set_c1(1); else set_c1(0); fpu_set_exception(FPU_Exception::Precision); } return result; } // Instructions // DATA TRANSFER void SoftFPU::FLD_RM32(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_push(fpu_get(insn.modrm().register_index())); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values fpu_push(bit_cast(new_f32.value())); } } void SoftFPU::FLD_RM64(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values fpu_push(bit_cast(new_f64.value())); } void SoftFPU::FLD_RM80(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); // long doubles can be up to 128 bits wide in memory for reasons (alignment) and only uses 80 bits of precision // GCC uses 12 bytes in 32 bit and 16 bytes in 64 bit mode // so in the 32 bit case we read a bit to much, but that shouldn't be an issue. // FIXME: Respect shadow values u128 new_f80 = insn.modrm().read128(m_cpu, insn).value(); fpu_push(*(long double*)new_f80.bytes().data()); } void SoftFPU::FST_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); float f32 = fpu_convert_checked(fpu_get(0)); if (fpu_is_set(0)) insn.modrm().write32(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(f32))); else insn.modrm().write32(m_cpu, insn, ValueWithShadow(bit_cast(f32), 0u)); } void SoftFPU::FST_RM64(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(0)); } else { double f64 = fpu_convert_checked(fpu_get(0)); if (fpu_is_set(0)) insn.modrm().write64(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(f64))); else insn.modrm().write64(m_cpu, insn, ValueWithShadow(bit_cast(f64), 0ULL)); } } void SoftFPU::FSTP_RM32(const X86::Instruction& insn) { FST_RM32(insn); fpu_pop(); } void SoftFPU::FSTP_RM64(const X86::Instruction& insn) { FST_RM64(insn); fpu_pop(); } void SoftFPU::FSTP_RM80(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(0)); fpu_pop(); } else { // FIXME: Respect more shadow values // long doubles can be up to 128 bits wide in memory for reasons (alignment) and only uses 80 bits of precision // gcc uses 12 byte in 32 bit and 16 byte in 64 bit mode // due to only 10 bytes being used, we just write these 10 into memory // We have to do .bytes().data() to get around static type analysis ValueWithShadow f80 { 0u, 0u }; u128 value {}; f80 = insn.modrm().read128(m_cpu, insn); *(long double*)value.bytes().data() = fpu_pop(); memcpy(f80.value().bytes().data(), &value, 10); // copy memset(f80.shadow().bytes().data(), 0x01, 10); // mark as initialized insn.modrm().write128(m_cpu, insn, f80); } } void SoftFPU::FILD_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = insn.modrm().read16(m_cpu, insn); warn_if_uninitialized(m16int, "int16 loaded as float"); fpu_push(static_cast(static_cast(m16int.value()))); } void SoftFPU::FILD_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = insn.modrm().read32(m_cpu, insn); warn_if_uninitialized(m32int, "int32 loaded as float"); fpu_push(static_cast(static_cast(m32int.value()))); } void SoftFPU::FILD_RM64(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m64int = insn.modrm().read64(m_cpu, insn); warn_if_uninitialized(m64int, "int64 loaded as float"); fpu_push(static_cast(static_cast(m64int.value()))); } void SoftFPU::FIST_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto f = fpu_get(0); set_c1(0); auto int16 = fpu_round_checked(f); // FIXME: Respect shadow values insn.modrm().write16(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(int16))); } void SoftFPU::FIST_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto f = fpu_get(0); set_c1(0); auto int32 = fpu_round_checked(f); // FIXME: Respect shadow values insn.modrm().write32(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(int32))); } void SoftFPU::FISTP_RM16(const X86::Instruction& insn) { FIST_RM16(insn); fpu_pop(); } void SoftFPU::FISTP_RM32(const X86::Instruction& insn) { FIST_RM32(insn); fpu_pop(); } void SoftFPU::FISTP_RM64(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto f = fpu_pop(); set_c1(0); auto i64 = fpu_round_checked(f); // FIXME: Respect shadow values insn.modrm().write64(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(i64))); } void SoftFPU::FISTTP_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); set_c1(0); i16 value = static_cast(fpu_pop()); // FIXME: Respect shadow values insn.modrm().write16(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(value))); } void SoftFPU::FISTTP_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); i32 value = static_cast(fpu_pop()); set_c1(0); // FIXME: Respect shadow values insn.modrm().write32(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(value))); } void SoftFPU::FISTTP_RM64(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); set_c1(0); i64 value = static_cast(fpu_pop()); // FIXME: Respect shadow values insn.modrm().write64(m_cpu, insn, shadow_wrap_as_initialized(bit_cast(value))); } void SoftFPU::FBLD_M80(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FBSTP_M80(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FXCH(const X86::Instruction& insn) { // FIXME: implicit argument `D9 C9` -> st[0] <-> st[1]? VERIFY(insn.modrm().is_register()); set_c1(0); auto tmp = fpu_get(0); fpu_set(0, fpu_get(insn.modrm().register_index())); fpu_set(insn.modrm().register_index(), tmp); } void SoftFPU::FCMOVE(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); if (m_cpu.zf()) fpu_set(0, fpu_get(insn.modrm().rm())); } void SoftFPU::FCMOVNE(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); if (!m_cpu.zf()) fpu_set(0, fpu_get((insn.modrm().reg_fpu()))); } void SoftFPU::FCMOVB(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); if (m_cpu.cf()) fpu_set(0, fpu_get(insn.modrm().rm())); } void SoftFPU::FCMOVNB(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_push((long double)m32int); } void SoftFPU::FCMOVBE(const X86::Instruction& insn) { if (m_cpu.cf() | m_cpu.zf()) fpu_set(0, fpu_get(insn.modrm().rm())); } void SoftFPU::FCMOVNBE(const X86::Instruction& insn) { if (!(m_cpu.cf() | m_cpu.zf())) fpu_set(0, fpu_get(insn.modrm().rm())); } void SoftFPU::FCMOVU(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); if (m_cpu.pf()) fpu_set(0, fpu_get((insn.modrm().reg_fpu()))); } void SoftFPU::FCMOVNU(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); if (m_cpu.pf()) fpu_set(0, fpu_get((insn.modrm().reg_fpu()))); } // BASIC ARITHMETIC void SoftFPU::FADD_RM32(const X86::Instruction& insn) { // XXX look at ::INC_foo for how mem/reg stuff is handled, and use that here too to make sure this is only called for mem32 ops if (insn.modrm().is_register()) { fpu_set(0, fpu_get(insn.modrm().register_index()) + fpu_get(0)); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); fpu_set(0, fpu_get(0) + f32); } } void SoftFPU::FADD_RM64(const X86::Instruction& insn) { // XXX look at ::INC_foo for how mem/reg stuff is handled, and use that here too to make sure this is only called for mem64 ops if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) + fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); fpu_set(0, fpu_get(0) + f64); } } void SoftFPU::FADDP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) + fpu_get(0)); fpu_pop(); } void SoftFPU::FIADD_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) + (long double)m32int); } void SoftFPU::FIADD_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) + (long double)m16int); } void SoftFPU::FSUB_RM32(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(0, fpu_get(0) - fpu_get(insn.modrm().register_index())); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); fpu_set(0, fpu_get(0) - f32); } } void SoftFPU::FSUB_RM64(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) - fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); fpu_set(0, fpu_get(0) - f64); } } void SoftFPU::FSUBP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) - fpu_get(0)); fpu_pop(); } void SoftFPU::FSUBR_RM32(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(0, fpu_get(insn.modrm().register_index()) - fpu_get(0)); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); fpu_set(0, f32 - fpu_get(0)); } } void SoftFPU::FSUBR_RM64(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) - fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); fpu_set(0, f64 - fpu_get(0)); } } void SoftFPU::FSUBRP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); fpu_set(insn.modrm().register_index(), fpu_get(0) - fpu_get(insn.modrm().register_index())); fpu_pop(); } void SoftFPU::FISUB_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) - (long double)m32int); } void SoftFPU::FISUB_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) - (long double)m16int); } void SoftFPU::FISUBR_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, (long double)m16int - fpu_get(0)); } void SoftFPU::FISUBR_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, (long double)m32int - fpu_get(0)); } void SoftFPU::FMUL_RM32(const X86::Instruction& insn) { // XXX look at ::INC_foo for how mem/reg stuff is handled, and use that here too to make sure this is only called for mem32 ops if (insn.modrm().is_register()) { fpu_set(0, fpu_get(0) * fpu_get(insn.modrm().register_index())); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); fpu_set(0, fpu_get(0) * f32); } } void SoftFPU::FMUL_RM64(const X86::Instruction& insn) { // XXX look at ::INC_foo for how mem/reg stuff is handled, and use that here too to make sure this is only called for mem64 ops if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) * fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); fpu_set(0, fpu_get(0) * f64); } } void SoftFPU::FMULP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) * fpu_get(0)); fpu_pop(); } void SoftFPU::FIMUL_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) * (long double)m32int); } void SoftFPU::FIMUL_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values fpu_set(0, fpu_get(0) * (long double)m16int); } void SoftFPU::FDIV_RM32(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(0, fpu_get(0) / fpu_get(insn.modrm().register_index())); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(0, fpu_get(0) / f32); } } void SoftFPU::FDIV_RM64(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) / fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(0, fpu_get(0) / f64); } } void SoftFPU::FDIVP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) / fpu_get(0)); fpu_pop(); } void SoftFPU::FDIVR_RM32(const X86::Instruction& insn) { if (insn.modrm().is_register()) { fpu_set(0, fpu_get(insn.modrm().register_index()) / fpu_get(0)); } else { auto new_f32 = insn.modrm().read32(m_cpu, insn); // FIXME: Respect shadow values auto f32 = bit_cast(new_f32.value()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(0, f32 / fpu_get(0)); } } void SoftFPU::FDIVR_RM64(const X86::Instruction& insn) { if (insn.modrm().is_register()) { // XXX this is FDIVR, Instruction decodes this weirdly //fpu_set(insn.modrm().register_index(), fpu_get(0) / fpu_get(insn.modrm().register_index())); fpu_set(insn.modrm().register_index(), fpu_get(insn.modrm().register_index()) / fpu_get(0)); } else { auto new_f64 = insn.modrm().read64(m_cpu, insn); // FIXME: Respect shadow values auto f64 = bit_cast(new_f64.value()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(0, f64 / fpu_get(0)); } } void SoftFPU::FDIVRP(const X86::Instruction& insn) { VERIFY(insn.modrm().is_register()); // FIXME: Raise IA on + infinity / +-infinity, +-0 / +-0, raise Z on finite / +-0 fpu_set(insn.modrm().register_index(), fpu_get(0) / fpu_get(insn.modrm().register_index())); fpu_pop(); } void SoftFPU::FIDIV_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values // FIXME: Raise IA on 0 / _=0, raise Z on finite / +-0 fpu_set(0, fpu_get(0) / (long double)m16int); } void SoftFPU::FIDIV_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values // FIXME: Raise IA on 0 / _=0, raise Z on finite / +-0 fpu_set(0, fpu_get(0) / (long double)m32int); } void SoftFPU::FIDIVR_RM16(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m16int = (i16)insn.modrm().read16(m_cpu, insn).value(); // FIXME: Respect shadow values // FIXME: Raise IA on 0 / _=0, raise Z on finite / +-0 fpu_set(0, (long double)m16int / fpu_get(0)); } void SoftFPU::FIDIVR_RM32(const X86::Instruction& insn) { VERIFY(!insn.modrm().is_register()); auto m32int = (i32)insn.modrm().read32(m_cpu, insn).value(); // FIXME: Respect shadow values // FIXME: Raise IA on 0 / _=0, raise Z on finite / +-0 fpu_set(0, (long double)m32int / fpu_get(0)); } void SoftFPU::FPREM(const X86::Instruction&) { // FIXME: There are some exponent shenanigans supposed to be here long double top = fpu_get(0); long double one = fpu_get(1); int Q = static_cast(truncl(top / one)); top = top - (one * Q); set_c2(0); set_c1(Q & 1); set_c3((Q >> 1) & 1); set_c0((Q >> 2) & 1); fpu_set(0, top); } void SoftFPU::FPREM1(const X86::Instruction&) { // FIXME: There are some exponent shenanigans supposed to be here long double top = fpu_get(0); long double one = fpu_get(1); int Q = static_cast(roundl(top / one)); top = top - (one * Q); set_c2(0); set_c1(Q & 1); set_c3((Q >> 1) & 1); set_c0((Q >> 2) & 1); fpu_set(0, top); } void SoftFPU::FABS(const X86::Instruction&) { set_c1(0); fpu_set(0, __builtin_fabsl(fpu_get(0))); } void SoftFPU::FCHS(const X86::Instruction&) { set_c1(0); fpu_set(0, -fpu_get(0)); } void SoftFPU::FRNDINT(const X86::Instruction&) { auto res = fpu_round(fpu_get(0)); if (auto rnd = (res - fpu_get(0))) { if (rnd > 0) set_c1(1); else set_c1(0); } fpu_set(0, res); } void SoftFPU::FSCALE(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded fpu_set(0, fpu_get(0) * powl(2, floorl(fpu_get(1)))); } void SoftFPU::FSQRT(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded fpu_set(0, sqrtl(fpu_get(0))); } void SoftFPU::FXTRACT(const X86::Instruction&) { TODO_INSN(); } // COMPARISON // FIXME: there may be an implicit argument, how is this conveyed by the insn void SoftFPU::FCOM_RM32(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FCOM_RM64(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FCOMP_RM32(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FCOMP_RM64(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FCOMPP(const X86::Instruction&) { if (fpu_isnan(0) || fpu_isnan(1)) { fpu_set_exception(FPU_Exception::InvalidOperation); if (m_fpu_mask_invalid) fpu_set_unordered(); } else { set_c2(0); set_c0(fpu_get(0) < fpu_get(1)); set_c3(fpu_get(0) == fpu_get(1)); } fpu_pop(); fpu_pop(); } void SoftFPU::FUCOM(const X86::Instruction&) { TODO_INSN(); } // Needs QNaN detection void SoftFPU::FUCOMP(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FUCOMPP(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FICOM_RM16(const X86::Instruction& insn) { // FIXME: Check for denormals VERIFY(insn.modrm().is_register()); auto val_shd = insn.modrm().read16(m_cpu, insn); warn_if_uninitialized(val_shd, "int16 compare to float"); auto val = static_cast(val_shd.value()); if (fpu_isnan(0)) { fpu_set_unordered(); } else { set_c0(fpu_get(0) < val); set_c2(0); set_c3(fpu_get(0) == val); } set_c1(0); } void SoftFPU::FICOM_RM32(const X86::Instruction& insn) { // FIXME: Check for denormals VERIFY(insn.modrm().is_register()); auto val_shd = insn.modrm().read32(m_cpu, insn); warn_if_uninitialized(val_shd, "int32 compare to float"); auto val = static_cast(val_shd.value()); if (fpu_isnan(0)) { fpu_set_unordered(); } else { set_c0(fpu_get(0) < val); set_c2(0); set_c3(fpu_get(0) == val); } set_c1(0); } void SoftFPU::FICOMP_RM16(const X86::Instruction& insn) { FICOM_RM16(insn); fpu_pop(); } void SoftFPU::FICOMP_RM32(const X86::Instruction& insn) { FICOM_RM32(insn); fpu_pop(); } void SoftFPU::FCOMI(const X86::Instruction& insn) { auto i = insn.modrm().rm(); // FIXME: QNaN / exception handling. set_c0(0); if (isnan(fpu_get(0)) || isnan(fpu_get(1))) { fpu_set_exception(FPU_Exception::InvalidOperation); m_cpu.set_zf(1); m_cpu.set_pf(1); m_cpu.set_cf(1); } if (!fpu_is_set(1)) fpu_set_exception(FPU_Exception::Underflow); m_cpu.set_zf(fpu_get(0) == fpu_get(i)); m_cpu.set_pf(false); m_cpu.set_cf(fpu_get(0) < fpu_get(i)); // FIXME: is this supposed to be here? // m_cpu.set_of(false); // FIXME: Taint should be based on ST(0) and ST(i) m_cpu.m_flags_tainted = false; } void SoftFPU::FCOMIP(const X86::Instruction& insn) { FCOMI(insn); fpu_pop(); } void SoftFPU::FUCOMI(const X86::Instruction& insn) { auto i = insn.modrm().rm(); // FIXME: Unordered comparison checks. // FIXME: QNaN / exception handling. set_c1(0); if (fpu_isnan(0) || fpu_isnan(i)) { m_cpu.set_zf(true); m_cpu.set_pf(true); m_cpu.set_cf(true); } else { m_cpu.set_zf(fpu_get(0) == fpu_get(i)); m_cpu.set_pf(false); m_cpu.set_cf(fpu_get(0) < fpu_get(i)); m_cpu.set_of(false); } // FIXME: Taint should be based on ST(0) and ST(i) m_cpu.m_flags_tainted = false; } void SoftFPU::FUCOMIP(const X86::Instruction& insn) { FUCOMI(insn); fpu_pop(); } void SoftFPU::FTST(const X86::Instruction&) { // FIXME: maybe check for denormal set_c1(0); if (fpu_isnan(0)) // raise #IA? fpu_set_unordered(); else { set_c0(fpu_get(0) < 0.); set_c2(0); set_c3(fpu_get(0) == 0.); } } void SoftFPU::FXAM(const X86::Instruction&) { if (m_reg_is_mmx[m_fpu_stack_top]) { // technically a subset of NaN/INF, with the Tag set to valid, // but we have our own helper for this set_c0(0); set_c2(0); set_c3(0); } else { switch (fpu_get_tag(0)) { case FPU_Tag::Valid: set_c0(0); set_c2(1); set_c3(0); break; case FPU_Tag::Zero: set_c0(1); set_c2(0); set_c3(0); break; case FPU_Tag::Special: if (isinf(fpu_get(0))) { set_c0(1); set_c2(1); set_c3(0); } else if (isnan(fpu_get(0))) { set_c0(1); set_c2(0); set_c3(0); } else { // denormalized set_c0(0); set_c2(1); set_c3(1); } break; case FPU_Tag::Empty: set_c0(1); set_c2(0); set_c3(1); break; default: VERIFY_NOT_REACHED(); } } set_c1(signbit(fpu_get(0))); } // TRANSCENDENTAL void SoftFPU::FSIN(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded // FIXME: Set C2 to 1 if ST(0) is outside range of -2^63 to +2^63; else set to 0 fpu_set(0, sinl(fpu_get(0))); } void SoftFPU::FCOS(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded // FIXME: Set C2 to 1 if ST(0) is outside range of -2^63 to +2^63; else set to 0 fpu_set(0, cosl(fpu_get(0))); } void SoftFPU::FSINCOS(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded // FIXME: Set C2 to 1 if ST(0) is outside range of -2^63 to +2^63; else set to 0s long double sin = sinl(fpu_get(0)); long double cos = cosl(fpu_get(0)); fpu_set(0, sin); fpu_push(cos); } void SoftFPU::FPTAN(const X86::Instruction&) { // FIXME: set C1 upon stack overflow or if result was rounded // FIXME: Set C2 to 1 if ST(0) is outside range of -2^63 to +2^63; else set to 0 fpu_set(0, tanl(fpu_get(0))); fpu_push(1.0f); } void SoftFPU::FPATAN(const X86::Instruction&) { // FIXME: set C1 on stack underflow, or on rounding // FIXME: Exceptions fpu_set(1, atan2l(fpu_get(1), fpu_get(0))); fpu_pop(); } void SoftFPU::F2XM1(const X86::Instruction&) { // FIXME: validate ST(0) is in range –1.0 to +1.0 auto val = fpu_get(0); // FIXME: Set C0, C2, C3 in FPU status word. fpu_set(0, powl(2, val) - 1.0l); } void SoftFPU::FYL2X(const X86::Instruction&) { // FIXME: raise precision and under/overflow // FIXME: detect denormal operands // FIXME: QNaN auto f0 = fpu_get(0); auto f1 = fpu_get(1); if (f0 < 0. || isnan(f0) || isnan(f1) || (isinf(f0) && f1 == 0.) || (f0 == 1. && isinf(f1))) fpu_set_exception(FPU_Exception::InvalidOperation); if (f0 == 0.) fpu_set_exception(FPU_Exception::ZeroDivide); fpu_set(1, f1 * log2l(f0)); fpu_pop(); } void SoftFPU::FYL2XP1(const X86::Instruction&) { // FIXME: raise #O #U #P #D // FIXME: QNaN auto f0 = fpu_get(0); auto f1 = fpu_get(1); if (isnan(f0) || isnan(f1) || (isinf(f1) && f0 == 0)) fpu_set_exception(FPU_Exception::InvalidOperation); fpu_set(1, (f1 * log2l(f0 + 1.0l))); fpu_pop(); } // LOAD CONSTANT void SoftFPU::FLD1(const X86::Instruction&) { fpu_push(1.0l); } void SoftFPU::FLDZ(const X86::Instruction&) { fpu_push(0.0l); } void SoftFPU::FLDPI(const X86::Instruction&) { fpu_push(M_PIl); } void SoftFPU::FLDL2E(const X86::Instruction&) { fpu_push(M_LOG2El); } void SoftFPU::FLDLN2(const X86::Instruction&) { fpu_push(M_LN2l); } void SoftFPU::FLDL2T(const X86::Instruction&) { fpu_push(log2l(10.0l)); } void SoftFPU::FLDLG2(const X86::Instruction&) { fpu_push(log10l(2.0l)); } // CONTROL void SoftFPU::FINCSTP(const X86::Instruction&) { m_fpu_stack_top = (m_fpu_stack_top + 1u) % 8u; set_c1(0); } void SoftFPU::FDECSTP(const X86::Instruction&) { m_fpu_stack_top = (m_fpu_stack_top - 1u) % 8u; set_c1(0); } void SoftFPU::FFREE(const X86::Instruction& insn) { fpu_set_tag(insn.modrm().reg_fpu(), FPU_Tag::Empty); } void SoftFPU::FFREEP(const X86::Instruction& insn) { FFREE(insn); fpu_pop(); } void SoftFPU::FNINIT(const X86::Instruction&) { m_fpu_cw = 0x037F; m_fpu_sw = 0; m_fpu_tw = 0xFFFF; m_fpu_ip = 0; m_fpu_cs = 0; m_fpu_dp = 0; m_fpu_ds = 0; m_fpu_iop = 0; }; void SoftFPU::FNCLEX(const X86::Instruction&) { m_fpu_error_invalid = 0; m_fpu_error_denorm = 0; m_fpu_error_zero_div = 0; m_fpu_error_overflow = 0; m_fpu_error_underflow = 0; m_fpu_error_precision = 0; m_fpu_error_stackfault = 0; m_fpu_busy = 0; } void SoftFPU::FNSTCW(const X86::Instruction& insn) { insn.modrm().write16(m_cpu, insn, shadow_wrap_as_initialized(m_fpu_cw)); } void SoftFPU::FLDCW(const X86::Instruction& insn) { m_fpu_cw = insn.modrm().read16(m_cpu, insn).value(); } void SoftFPU::FNSTENV(const X86::Instruction& insn) { // Assuming we are always in Protected mode // FIXME: 16-bit Format // 32-bit Format /* 31--------------16---------------0 * | | CW | 0 * +----------------+---------------+ * | | SW | 4 * +----------------+---------------+ * | | TW | 8 * +----------------+---------------+ * | FIP | 12 * +----+-----------+---------------+ * |0000|fpuOp[10:0]| FIP_sel | 16 * +----+-----------+---------------+ * | FDP | 20 * +----------------+---------------+ * | | FDP_ds | 24 * +----------------|---------------+ * */ auto address = insn.modrm().resolve(m_cpu, insn); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_cw)); address.set_offset(address.offset() + 4); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_sw)); address.set_offset(address.offset() + 4); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_tw)); address.set_offset(address.offset() + 4); m_cpu.write_memory32(address, shadow_wrap_as_initialized(m_fpu_ip)); address.set_offset(address.offset() + 4); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_cs)); address.set_offset(address.offset() + 2); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_iop & 0x3FFU)); address.set_offset(address.offset() + 2); m_cpu.write_memory32(address, shadow_wrap_as_initialized(m_fpu_dp)); address.set_offset(address.offset() + 4); m_cpu.write_memory16(address, shadow_wrap_as_initialized(m_fpu_ds)); } void SoftFPU::FLDENV(const X86::Instruction& insn) { // Assuming we are always in Protected mode // FIXME: 16-bit Format auto address = insn.modrm().resolve(m_cpu, insn); // FIXME: Shadow Values m_fpu_cw = m_cpu.read_memory16(address).value(); address.set_offset(address.offset() + 4); m_fpu_sw = m_cpu.read_memory16(address).value(); address.set_offset(address.offset() + 4); m_fpu_tw = m_cpu.read_memory16(address).value(); address.set_offset(address.offset() + 4); m_fpu_ip = m_cpu.read_memory32(address).value(); address.set_offset(address.offset() + 4); m_fpu_cs = m_cpu.read_memory16(address).value(); address.set_offset(address.offset() + 2); m_fpu_iop = m_cpu.read_memory16(address).value(); address.set_offset(address.offset() + 2); m_fpu_dp = m_cpu.read_memory32(address).value(); address.set_offset(address.offset() + 4); m_fpu_ds = m_cpu.read_memory16(address).value(); } void SoftFPU::FNSAVE(const X86::Instruction& insn) { FNSTENV(insn); auto address = insn.modrm().resolve(m_cpu, insn); address.set_offset(address.offset() + 28); // size of the ENV // write fpu-stack to memory u8 raw_data[80]; for (int i = 0; i < 8; ++i) { memcpy(raw_data + 10 * i, &m_storage[i], 10); } for (int i = 0; i < 5; ++i) { // FIXME: Shadow Value m_cpu.write_memory128(address, shadow_wrap_as_initialized(((u128*)raw_data)[i])); address.set_offset(address.offset() + 16); } FNINIT(insn); } void SoftFPU::FRSTOR(const X86::Instruction& insn) { FLDENV(insn); auto address = insn.modrm().resolve(m_cpu, insn); address.set_offset(address.offset() + 28); // size of the ENV // read fpu-stack from memory u8 raw_data[80]; for (int i = 0; i < 5; ++i) { // FIXME: Shadow Value ((u128*)raw_data)[i] = m_cpu.read_memory128(address).value(); address.set_offset(address.offset() + 16); } for (int i = 0; i < 8; ++i) { memcpy(&m_storage[i], raw_data + 10 * i, 10); } memset(m_reg_is_mmx, 0, sizeof(m_reg_is_mmx)); } void SoftFPU::FNSTSW(const X86::Instruction& insn) { insn.modrm().write16(m_cpu, insn, shadow_wrap_as_initialized(m_fpu_sw)); } void SoftFPU::FNSTSW_AX(const X86::Instruction&) { m_cpu.set_ax(shadow_wrap_as_initialized(m_fpu_sw)); } // FIXME: FWAIT void SoftFPU::FNOP(const X86::Instruction&) { } // DO NOTHING? void SoftFPU::FNENI(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FNDISI(const X86::Instruction&) { TODO_INSN(); } void SoftFPU::FNSETPM(const X86::Instruction&) { TODO_INSN(); } // MMX // helpers #define LOAD_MM_MM64M() \ MMX mm; \ MMX mm64m; \ if (insn.modrm().mod() == 0b11) { /* 0b11 signals a register */ \ mm64m = mmx_get(insn.modrm().rm()); \ } else { \ auto temp = insn.modrm().read64(m_cpu, insn); \ warn_if_uninitialized(temp, "Read of uninitialized Memory as Packed integer"); \ mm64m.raw = temp.value(); \ } \ mm = mmx_get(insn.modrm().reg()) #define MMX_intrinsic(intrinsic, res_type, actor_type) \ LOAD_MM_MM64M(); \ mm.res_type = __builtin_ia32_##intrinsic(mm.actor_type, mm64m.actor_type); \ mmx_set(insn.modrm().reg(), mm); \ mmx_common(); // ARITHMETIC void SoftFPU::PADDB_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v8 += mm64m.v8; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PADDW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 += mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PADDD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 += mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PADDSB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(paddsb, v8, v8); } void SoftFPU::PADDSW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(paddsw, v16, v16); } void SoftFPU::PADDUSB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(paddusb, v8, v8); } void SoftFPU::PADDUSW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(paddusw, v16, v16); } void SoftFPU::PSUBB_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v8 -= mm64m.v8; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSUBW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 -= mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSUBD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 -= mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSUBSB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(psubsb, v8, v8); } void SoftFPU::PSUBSW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(psubsw, v16, v16); } void SoftFPU::PSUBUSB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(psubusb, v8, v8); } void SoftFPU::PSUBUSW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(psubusw, v16, v16); } void SoftFPU::PMULHW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(pmulhw, v16, v16); } void SoftFPU::PMULLW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(pmullw, v16, v16); } void SoftFPU::PMADDWD_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(pmaddwd, v32, v16); } // COMPARISON void SoftFPU::PCMPEQB_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v8 = mm.v8 == mm64m.v8; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PCMPEQW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 = mm.v16 == mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PCMPEQD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 = mm.v32 == mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PCMPGTB_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v8 = mm.v8 > mm64m.v8; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PCMPGTW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 = mm.v16 > mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PCMPGTD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 = mm.v32 > mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } // CONVERSION void SoftFPU::PACKSSDW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(packssdw, v16, v32); } void SoftFPU::PACKSSWB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(packsswb, v8, v16); } void SoftFPU::PACKUSWB_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(packuswb, v8, v16); } // UNPACK void SoftFPU::PUNPCKHBW_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(punpckhbw, v8, v8); } void SoftFPU::PUNPCKHWD_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(punpckhwd, v16, v16); } void SoftFPU::PUNPCKHDQ_mm1_mm2m64(const X86::Instruction& insn) { MMX_intrinsic(punpckhdq, v32, v32); } void SoftFPU::PUNPCKLBW_mm1_mm2m32(const X86::Instruction& insn) { MMX_intrinsic(punpcklbw, v8, v8); } void SoftFPU::PUNPCKLWD_mm1_mm2m32(const X86::Instruction& insn) { MMX_intrinsic(punpcklwd, v16, v16); } void SoftFPU::PUNPCKLDQ_mm1_mm2m32(const X86::Instruction& insn) { MMX_intrinsic(punpckldq, v32, v32); } // LOGICAL void SoftFPU::PAND_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw &= mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PANDN_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw &= ~mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::POR_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw |= mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PXOR_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw ^= mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } // SHIFT void SoftFPU::PSLLW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 <<= mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSLLW_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v16 <<= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSLLD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 <<= mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSLLD_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v32 <<= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSLLQ_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw <<= mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSLLQ_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.raw <<= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRAW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16 >>= mm64m.v16; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRAW_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v16 >>= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRAD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32 >>= mm64m.v32; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRAD_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v32 >>= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLW_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v16u >>= mm64m.v16u; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLW_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v16u >>= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLD_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.v32u >>= mm64m.v32u; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLD_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.v32u >>= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLQ_mm1_mm2m64(const X86::Instruction& insn) { LOAD_MM_MM64M(); mm.raw >>= mm64m.raw; mmx_set(insn.modrm().reg(), mm); mmx_common(); } void SoftFPU::PSRLQ_mm1_imm8(const X86::Instruction& insn) { u8 imm = insn.imm8(); MMX mm = mmx_get(insn.modrm().reg()); mm.raw >>= imm; mmx_set(insn.modrm().reg(), mm); mmx_common(); } // DATA TRANSFER void SoftFPU::MOVD_mm1_rm32(const X86::Instruction& insn) { u8 mmx_index = insn.modrm().reg(); // FIXME:: Shadow Value // upper half is zeroed out mmx_set(mmx_index, { .raw = insn.modrm().read32(m_cpu, insn).value() }); mmx_common(); }; void SoftFPU::MOVD_rm32_mm2(const X86::Instruction& insn) { u8 mmx_index = insn.modrm().reg(); // FIXME:: Shadow Value insn.modrm().write32(m_cpu, insn, shadow_wrap_as_initialized(static_cast(mmx_get(mmx_index).raw))); mmx_common(); }; void SoftFPU::MOVQ_mm1_mm2m64(const X86::Instruction& insn) { // FIXME: Shadow Value if (insn.modrm().mod() == 0b11) { // instruction mmx_set(insn.modrm().reg(), mmx_get(insn.modrm().rm())); } else { mmx_set(insn.modrm().reg(), { .raw = insn.modrm().read64(m_cpu, insn).value() }); } mmx_common(); } void SoftFPU::MOVQ_mm1m64_mm2(const X86::Instruction& insn) { if (insn.modrm().mod() == 0b11) { // instruction mmx_set(insn.modrm().rm(), mmx_get(insn.modrm().reg())); } else { // FIXME: Shadow Value insn.modrm().write64(m_cpu, insn, shadow_wrap_as_initialized(mmx_get(insn.modrm().reg()).raw)); } mmx_common(); } void SoftFPU::MOVQ_mm1_rm64(const X86::Instruction&) { TODO_INSN(); }; // long mode void SoftFPU::MOVQ_rm64_mm2(const X86::Instruction&) { TODO_INSN(); }; // long mode // EMPTY MMX STATE void SoftFPU::EMMS(const X86::Instruction&) { // clear tagword m_fpu_tw = 0xFFFF; } }