pcsx2/common/emitter/internal.h

187 lines
5.8 KiB
C++

/* PCSX2 - PS2 Emulator for PCs
* Copyright (C) 2002-2010 PCSX2 Dev Team
*
* PCSX2 is free software: you can redistribute it and/or modify it under the terms
* of the GNU Lesser General Public License as published by the Free Software Found-
* ation, either version 3 of the License, or (at your option) any later version.
*
* PCSX2 is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
* PURPOSE. See the GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along with PCSX2.
* If not, see <http://www.gnu.org/licenses/>.
*/
#pragma once
#include "common/emitter/x86types.h"
#include "common/emitter/instructions.h"
namespace x86Emitter
{
#define OpWriteSSE(pre, op) xOpWrite0F(pre, op, to, from)
extern void SimdPrefix(u8 prefix, u16 opcode);
extern void EmitSibMagic(uint regfield, const void* address, int extraRIPOffset = 0);
extern void EmitSibMagic(uint regfield, const xIndirectVoid& info, int extraRIPOffset = 0);
extern void EmitSibMagic(uint reg1, const xRegisterBase& reg2, int = 0);
extern void EmitSibMagic(const xRegisterBase& reg1, const xRegisterBase& reg2, int = 0);
extern void EmitSibMagic(const xRegisterBase& reg1, const void* src, int extraRIPOffset = 0);
extern void EmitSibMagic(const xRegisterBase& reg1, const xIndirectVoid& sib, int extraRIPOffset = 0);
extern void EmitRex(uint regfield, const void* address);
extern void EmitRex(uint regfield, const xIndirectVoid& info);
extern void EmitRex(uint reg1, const xRegisterBase& reg2);
extern void EmitRex(const xRegisterBase& reg1, const xRegisterBase& reg2);
extern void EmitRex(const xRegisterBase& reg1, const void* src);
extern void EmitRex(const xRegisterBase& reg1, const xIndirectVoid& sib);
extern void _xMovRtoR(const xRegisterInt& to, const xRegisterInt& from);
template <typename T>
inline void xWrite(T val)
{
*(T*)x86Ptr = val;
x86Ptr += sizeof(T);
}
template <typename T1, typename T2>
__emitinline void xOpWrite(u8 prefix, u8 opcode, const T1& param1, const T2& param2, int extraRIPOffset = 0)
{
if (prefix != 0)
xWrite8(prefix);
EmitRex(param1, param2);
xWrite8(opcode);
EmitSibMagic(param1, param2, extraRIPOffset);
}
template <typename T1, typename T2>
__emitinline void xOpAccWrite(u8 prefix, u8 opcode, const T1& param1, const T2& param2)
{
if (prefix != 0)
xWrite8(prefix);
EmitRex(param1, param2);
xWrite8(opcode);
}
//////////////////////////////////////////////////////////////////////////////////////////
// emitter helpers for xmm instruction with prefixes, most of which are using
// the basic opcode format (items inside braces denote optional or conditional
// emission):
//
// [Prefix] / 0x0f / [OpcodePrefix] / Opcode / ModRM+[SibSB]
//
// Prefixes are typically 0x66, 0xf2, or 0xf3. OpcodePrefixes are either 0x38 or
// 0x3a [and other value will result in assertion failue].
//
template <typename T1, typename T2>
__emitinline void xOpWrite0F(u8 prefix, u16 opcode, const T1& param1, const T2& param2)
{
if (prefix != 0)
xWrite8(prefix);
EmitRex(param1, param2);
SimdPrefix(0, opcode);
EmitSibMagic(param1, param2);
}
template <typename T1, typename T2>
__emitinline void xOpWrite0F(u8 prefix, u16 opcode, const T1& param1, const T2& param2, u8 imm8)
{
if (prefix != 0)
xWrite8(prefix);
EmitRex(param1, param2);
SimdPrefix(0, opcode);
EmitSibMagic(param1, param2, 1);
xWrite8(imm8);
}
template <typename T1, typename T2>
__emitinline void xOpWrite0F(u16 opcode, const T1& param1, const T2& param2)
{
xOpWrite0F(0, opcode, param1, param2);
}
template <typename T1, typename T2>
__emitinline void xOpWrite0F(u16 opcode, const T1& param1, const T2& param2, u8 imm8)
{
xOpWrite0F(0, opcode, param1, param2, imm8);
}
// VEX 2 Bytes Prefix
template <typename T1, typename T2, typename T3>
__emitinline void xOpWriteC5(u8 prefix, u8 opcode, const T1& param1, const T2& param2, const T3& param3)
{
pxAssert(prefix == 0 || prefix == 0x66 || prefix == 0xF3 || prefix == 0xF2);
const xRegisterBase& reg = param1.IsReg() ? param1 : param2;
u8 nR = reg.IsExtended() ? 0x00 : 0x80;
u8 L;
// Needed for 256-bit movemask.
if constexpr (std::is_same_v<T3, xRegisterSSE>)
L = param3.IsWideSIMD() ? 4 : 0;
else
L = reg.IsWideSIMD() ? 4 : 0;
u8 nv = (param2.IsEmpty() ? 0xF : ((~param2.GetId() & 0xF))) << 3;
u8 p =
prefix == 0xF2 ? 3 :
prefix == 0xF3 ? 2 :
prefix == 0x66 ? 1 :
0;
xWrite8(0xC5);
xWrite8(nR | nv | L | p);
xWrite8(opcode);
EmitSibMagic(param1, param3);
}
// VEX 3 Bytes Prefix
template <typename T1, typename T2, typename T3>
__emitinline void xOpWriteC4(u8 prefix, u8 mb_prefix, u8 opcode, const T1& param1, const T2& param2, const T3& param3, int w = -1)
{
pxAssert(prefix == 0 || prefix == 0x66 || prefix == 0xF3 || prefix == 0xF2);
pxAssert(mb_prefix == 0x0F || mb_prefix == 0x38 || mb_prefix == 0x3A);
const xRegisterInt& reg = param1.IsReg() ? param1 : param2;
u8 nR = reg.IsExtended() ? 0x00 : 0x80;
u8 nB = param3.IsExtended() ? 0x00 : 0x20;
u8 nX = 0x40; // likely unused so hardwired to disabled
u8 L = reg.IsWideSIMD() ? 4 : 0;
u8 W = (w == -1) ? (reg.GetOperandSize() == 8 ? 0x80 : 0) : // autodetect the size
0x80 * w; // take directly the W value
u8 nv = (~param2.GetId() & 0xF) << 3;
u8 p =
prefix == 0xF2 ? 3 :
prefix == 0xF3 ? 2 :
prefix == 0x66 ? 1 :
0;
u8 m =
mb_prefix == 0x3A ? 3 :
mb_prefix == 0x38 ? 2 :
1;
xWrite8(0xC4);
xWrite8(nR | nX | nB | m);
xWrite8(W | nv | L | p);
xWrite8(opcode);
EmitSibMagic(param1, param3);
}
} // namespace x86Emitter