ppsspp/Common/ArmEmitter.cpp

650 lines
19 KiB
C++

// Copyright (C) 2003 Dolphin Project.
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, version 2.0.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License 2.0 for more details.
// A copy of the GPL 2.0 should have been included with the program.
// If not, see http://www.gnu.org/licenses/
// Official SVN repository and contact information can be found at
// http://code.google.com/p/dolphin-emu/
#include "Common.h"
#include "ArmEmitter.h"
#include "CPUDetect.h"
#include <assert.h>
#include <stdarg.h>
// For cache flushing on Symbian/Blackberry
#ifdef __SYMBIAN32__
#include <e32std.h>
#endif
#ifdef BLACKBERRY
#include <sys/mman.h>
#endif
namespace ArmGen
{
inline u32 RotR(u32 a, int amount) {
if (!amount) return a;
return (a >> amount) | (a << (32 - amount));
}
inline u32 RotL(u32 a, int amount) {
if (!amount) return a;
return (a << amount) | (a >> (32 - amount));
}
bool TryMakeOperand2(u32 imm, Operand2 &op2) {
// Just brute force it.
for (int i = 0; i < 16; i++) {
int mask = RotR(0xFF, i * 2);
if ((imm & mask) == imm) {
op2 = Operand2((u8)(RotL(imm, i * 2)), (u8)i);
return true;
}
}
return false;
}
bool TryMakeOperand2_AllowInverse(u32 imm, Operand2 &op2, bool *inverse)
{
if (!TryMakeOperand2(imm, op2)) {
*inverse = true;
return TryMakeOperand2(~imm, op2);
} else {
*inverse = false;
return true;
}
}
bool TryMakeOperand2_AllowNegation(s32 imm, Operand2 &op2, bool *negated)
{
if (!TryMakeOperand2(imm, op2)) {
*negated = true;
return TryMakeOperand2(-imm, op2);
} else {
*negated = false;
return true;
}
}
void ARMXEmitter::ARMABI_MOVI2R(ARMReg reg, u32 val)
{
Operand2 op2;
bool inverse;
if (TryMakeOperand2_AllowInverse(val, op2, &inverse)) {
if (!inverse)
MOV(reg, op2);
else
MVN(reg, op2);
} else {
if (cpu_info.bArmV7) {
// ARMv7 - can use MOVT/MOVW, best choice
MOVW(reg, val & 0xFFFF);
if(val & 0xFFFF0000)
MOVT(reg, val, true);
} else {
// ARMv6 - fallback sequence.
// TODO: Optimize further. Can for example choose negation etc.
// Literal pools is another way to do this but much more complicated
// so I can't really be bothered for an outdated CPU architecture like ARMv6.
bool first = true;
int shift = 16;
for (int i = 0; i < 4; i++) {
if (val & 0xFF) {
if (first) {
MOV(reg, Operand2((u8)val, (u8)(shift & 0xF)));
first = false;
} else {
ORR(reg, reg, Operand2((u8)val, (u8)(shift & 0xF)));
}
}
shift -= 4;
val >>= 8;
}
}
}
}
void ARMXEmitter::QuickCallFunction(ARMReg reg, void *func) {
ARMABI_MOVI2R(reg, (u32)(func));
BL(reg);
}
void ARMXEmitter::SetCodePtr(u8 *ptr)
{
code = ptr;
startcode = code;
}
const u8 *ARMXEmitter::GetCodePtr() const
{
return code;
}
u8 *ARMXEmitter::GetWritableCodePtr()
{
return code;
}
void ARMXEmitter::ReserveCodeSpace(u32 bytes)
{
for (u32 i = 0; i < bytes/4; i++)
Write32(0xE1200070); //bkpt 0
}
const u8 *ARMXEmitter::AlignCode16()
{
ReserveCodeSpace((-(s32)code) & 15);
return code;
}
const u8 *ARMXEmitter::AlignCodePage()
{
ReserveCodeSpace((-(s32)code) & 4095);
return code;
}
void ARMXEmitter::FlushIcache()
{
FlushIcacheSection(lastCacheFlushEnd, code);
lastCacheFlushEnd = code;
}
void ARMXEmitter::FlushIcacheSection(u8 *start, u8 *end)
{
#ifdef __SYMBIAN32__
User::IMB_Range( start, end);
#elif defined(BLACKBERRY)
msync(start, end - start, MS_SYNC | MS_INVALIDATE_ICACHE);
#else
#ifndef _WIN32
__builtin___clear_cache (start, end);
#endif
#endif
}
void ARMXEmitter::SetCC(CCFlags cond)
{
condition = cond << 28;
}
void ARMXEmitter::NOP(int count)
{
for (int i = 0; i < count; i++) {
Write32(condition | 0x01A00000);
}
}
void ARMXEmitter::SETEND(bool BE)
{
//SETEND is non-conditional
Write32( 0xF1010000 | (BE << 9));
}
void ARMXEmitter::BKPT(u16 arg)
{
Write32(condition | 0x01200070 | (arg << 4 & 0x000FFF00) | (arg & 0x0000000F));
}
void ARMXEmitter::YIELD()
{
Write32(condition | 0x0320F001);
}
FixupBranch ARMXEmitter::B()
{
FixupBranch branch;
branch.type = 0; // Zero for B
branch.ptr = code;
branch.condition = condition;
//We'll write NOP here for now.
Write32(condition | 0x01A00000);
return branch;
}
FixupBranch ARMXEmitter::BL()
{
FixupBranch branch;
branch.type = 1; // Zero for B
branch.ptr = code;
branch.condition = condition;
//We'll write NOP here for now.
Write32(condition | 0x01A00000);
return branch;
}
FixupBranch ARMXEmitter::B_CC(CCFlags Cond)
{
FixupBranch branch;
branch.type = 0; // Zero for B
branch.ptr = code;
branch.condition = Cond << 28;
//We'll write NOP here for now.
Write32(condition | 0x01A00000);
return branch;
}
void ARMXEmitter::B_CC(CCFlags Cond, const void *fnptr)
{
s32 distance = (s32)fnptr - (s32(code) + 8);
_assert_msg_(DYNA_REC, distance > -33554432
&& distance <= 33554432,
"B_CC out of range (%p calls %p)", code, fnptr);
Write32((Cond << 28) | 0x0A000000 | ((distance >> 2) & 0x00FFFFFF));
}
FixupBranch ARMXEmitter::BL_CC(CCFlags Cond)
{
FixupBranch branch;
branch.type = 1; // Zero for B
branch.ptr = code;
branch.condition = Cond << 28;
//We'll write NOP here for now.
Write32(condition | 0x01A00000);
return branch;
}
void ARMXEmitter::SetJumpTarget(FixupBranch const &branch)
{
s32 distance = (s32(code) - 8) - (s32)branch.ptr;
_assert_msg_(DYNA_REC, distance > -33554432
&& distance <= 33554432,
"SetJumpTarget out of range (%p calls %p)", code,
branch.ptr);
if(branch.type == 0) // B
*(u32*)branch.ptr = (u32)(branch.condition | (10 << 24) | ((distance >> 2) &
0x00FFFFFF));
else // BL
*(u32*)branch.ptr = (u32)(branch.condition | 0x0B000000 | ((distance >> 2)
& 0x00FFFFFF));
}
void ARMXEmitter::B (const void *fnptr)
{
s32 distance = (s32)fnptr - (s32(code) + 8);
_assert_msg_(DYNA_REC, distance > -33554432
&& distance <= 33554432,
"B out of range (%p calls %p)", code, fnptr);
Write32(condition | 0x0A000000 | ((distance >> 2) & 0x00FFFFFF));
}
void ARMXEmitter::B(ARMReg src)
{
Write32(condition | 0x12FFF10 | src);
}
void ARMXEmitter::BL(const void *fnptr)
{
s32 distance = (s32)fnptr - (s32(code) + 8);
_assert_msg_(DYNA_REC, distance > -33554432
&& distance <= 33554432,
"BL out of range (%p calls %p)", code, fnptr);
Write32(condition | 0x0B000000 | ((distance >> 2) & 0x00FFFFFF));
}
void ARMXEmitter::BL(ARMReg src)
{
Write32(condition | 0x12FFF30 | src);
}
void ARMXEmitter::PUSH(const int num, ...)
{
u16 RegList = 0;
u8 Reg;
int i;
va_list vl;
va_start(vl, num);
for (i=0;i<num;i++)
{
Reg = va_arg(vl, u32);
RegList |= (1 << Reg);
}
va_end(vl);
Write32(condition | (2349 << 16) | RegList);
}
void ARMXEmitter::POP(const int num, ...)
{
u16 RegList = 0;
u8 Reg;
int i;
va_list vl;
va_start(vl, num);
for (i=0;i<num;i++)
{
Reg = va_arg(vl, u32);
RegList |= (1 << Reg);
}
va_end(vl);
Write32(condition | (2237 << 16) | RegList);
}
void ARMXEmitter::WriteShiftedDataOp(u32 op, bool SetFlags, ARMReg dest, ARMReg src, Operand2 op2)
{
Write32(condition | (13 << 21) | (SetFlags << 20) | (dest << 12) | op2.Imm5() | (op << 4) | src);
}
void ARMXEmitter::WriteShiftedDataOp(u32 op, bool SetFlags, ARMReg dest, ARMReg src, ARMReg op2)
{
Write32(condition | (13 << 21) | (SetFlags << 20) | (dest << 12) | (op2 << 8) | (op << 4) | src);
}
// IMM, REG, IMMSREG, RSR
// -1 for invalid if the instruction doesn't support that
const s32 InstOps[][4] = {{16, 0, 0, 0}, // AND(s)
{17, 1, 1, 1}, // EOR(s)
{18, 2, 2, 2}, // SUB(s)
{19, 3, 3, 3}, // RSB(s)
{20, 4, 4, 4}, // ADD(s)
{21, 5, 5, 5}, // ADC(s)
{22, 6, 6, 6}, // SBC(s)
{23, 7, 7, 7}, // RSC(s)
{24, 8, 8, 8}, // TST
{25, 9, 9, 9}, // TEQ
{26, 10, 10, 10}, // CMP
{27, 11, 11, 11}, // CMN
{28, 12, 12, 12}, // ORR(s)
{29, 13, 13, 13}, // MOV(s)
{30, 14, 14, 14}, // BIC(s)
{31, 15, 15, 15}, // MVN(s)
{24, -1, -1, -1}, // MOVW
{26, -1, -1, -1}, // MOVT
};
const char *InstNames[] = { "AND",
"EOR",
"SUB",
"RSB",
"ADD",
"ADC",
"SBC",
"RSC",
"TST",
"TEQ",
"CMP",
"CMN",
"ORR",
"MOV",
"BIC",
"MVN"
};
void ARMXEmitter::AND (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(0, Rd, Rn, Rm); }
void ARMXEmitter::ANDS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(0, Rd, Rn, Rm, true); }
void ARMXEmitter::EOR (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(1, Rd, Rn, Rm); }
void ARMXEmitter::EORS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(1, Rd, Rn, Rm, true); }
void ARMXEmitter::SUB (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(2, Rd, Rn, Rm); }
void ARMXEmitter::SUBS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(2, Rd, Rn, Rm, true); }
void ARMXEmitter::RSB (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(3, Rd, Rn, Rm); }
void ARMXEmitter::RSBS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(3, Rd, Rn, Rm, true); }
void ARMXEmitter::ADD (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(4, Rd, Rn, Rm); }
void ARMXEmitter::ADDS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(4, Rd, Rn, Rm, true); }
void ARMXEmitter::ADC (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(5, Rd, Rn, Rm); }
void ARMXEmitter::ADCS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(5, Rd, Rn, Rm, true); }
void ARMXEmitter::SBC (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(6, Rd, Rn, Rm); }
void ARMXEmitter::SBCS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(6, Rd, Rn, Rm, true); }
void ARMXEmitter::RSC (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(7, Rd, Rn, Rm); }
void ARMXEmitter::RSCS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(7, Rd, Rn, Rm, true); }
void ARMXEmitter::TST ( ARMReg Rn, Operand2 Rm) { WriteInstruction(8, R0, Rn, Rm, true); }
void ARMXEmitter::TEQ ( ARMReg Rn, Operand2 Rm) { WriteInstruction(9, R0, Rn, Rm, true); }
void ARMXEmitter::CMP ( ARMReg Rn, Operand2 Rm) { WriteInstruction(10, R0, Rn, Rm, true); }
void ARMXEmitter::CMN ( ARMReg Rn, Operand2 Rm) { WriteInstruction(11, R0, Rn, Rm, true); }
void ARMXEmitter::ORR (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(12, Rd, Rn, Rm); }
void ARMXEmitter::ORRS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(12, Rd, Rn, Rm, true); }
void ARMXEmitter::MOV (ARMReg Rd, Operand2 Rm) { WriteInstruction(13, Rd, R0, Rm); }
void ARMXEmitter::MOVS(ARMReg Rd, Operand2 Rm) { WriteInstruction(13, Rd, R0, Rm, true); }
void ARMXEmitter::BIC (ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(14, Rd, Rn, Rm); }
void ARMXEmitter::BICS(ARMReg Rd, ARMReg Rn, Operand2 Rm) { WriteInstruction(14, Rd, Rn, Rm, true); }
void ARMXEmitter::MVN (ARMReg Rd, Operand2 Rm) { WriteInstruction(15, Rd, R0, Rm); }
void ARMXEmitter::MVNS(ARMReg Rd, Operand2 Rm) { WriteInstruction(15, Rd, R0, Rm, true); }
void ARMXEmitter::MOVW(ARMReg Rd, Operand2 Rm) { WriteInstruction(16, Rd, R0, Rm); }
void ARMXEmitter::MOVT(ARMReg Rd, Operand2 Rm, bool TopBits) { WriteInstruction(17, Rd, R0, TopBits ? Rm.Value >> 16 : Rm); }
void ARMXEmitter::WriteInstruction (u32 Op, ARMReg Rd, ARMReg Rn, Operand2 Rm, bool SetFlags) // This can get renamed later
{
u32 op = InstOps[Op][Rm.GetType()]; // Type always decided by last operand
u32 Data = Rm.GetData();
if (Rm.GetType() == TYPE_IMM)
{
switch (Op)
{
// MOV cases that support IMM16
case 16:
case 17:
Data = Rm.Imm16();
break;
default:
break;
}
}
if (op == (u32)-1)
_assert_msg_(DYNA_REC, false, "%s not yet support %d", InstNames[Op], Rm.GetType());
Write32(condition | (op << 21) | (SetFlags ? (1 << 20) : 0) | Rn << 16 | Rd << 12 | Data);
}
// Data Operations
void ARMXEmitter::WriteSignedMultiply(u32 Op, u32 Op2, u32 Op3, ARMReg dest, ARMReg r1, ARMReg r2)
{
Write32(condition | (0x7 << 24) | (Op << 20) | (dest << 16) | (Op2 << 12) | (r1 << 8) | (Op3 << 5) | (1 << 4) | r2);
}
void ARMXEmitter::UDIV(ARMReg dest, ARMReg dividend, ARMReg divisor)
{
if (!cpu_info.bIDIVa)
PanicAlert("Trying to use integer divide on hardware that doesn't support it. Bad programmer.");
WriteSignedMultiply(3, 0xF, 0, dest, divisor, dividend);
}
void ARMXEmitter::SDIV(ARMReg dest, ARMReg dividend, ARMReg divisor)
{
if (!cpu_info.bIDIVa)
PanicAlert("Trying to use integer divide on hardware that doesn't support it. Bad programmer.");
WriteSignedMultiply(1, 0xF, 0, dest, divisor, dividend);
}
void ARMXEmitter::LSL (ARMReg dest, ARMReg src, Operand2 op2) { WriteShiftedDataOp(0, false, dest, src, op2);}
void ARMXEmitter::LSLS(ARMReg dest, ARMReg src, Operand2 op2) { WriteShiftedDataOp(0, true, dest, src, op2);}
void ARMXEmitter::LSL (ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(1, false, dest, src, op2);}
void ARMXEmitter::LSLS(ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(1, true, dest, src, op2);}
void ARMXEmitter::MUL (ARMReg dest, ARMReg src, ARMReg op2)
{
Write32(condition | (dest << 16) | (src << 8) | (9 << 4) | op2);
}
void ARMXEmitter::MULS(ARMReg dest, ARMReg src, ARMReg op2)
{
Write32(condition | (1 << 20) | (dest << 16) | (src << 8) | (9 << 4) | op2);
}
void ARMXEmitter::SXTB (ARMReg dest, ARMReg op2)
{
Write32(condition | (0x6AF << 16) | (dest << 12) | (7 << 4) | op2);
}
void ARMXEmitter::SXTH (ARMReg dest, ARMReg op2, u8 rotation)
{
SXTAH(dest, (ARMReg)15, op2, rotation);
}
void ARMXEmitter::SXTAH(ARMReg dest, ARMReg src, ARMReg op2, u8 rotation)
{
// bits ten and 11 are the rotation amount, see 8.8.232 for more
// information
Write32(condition | (0x6B << 20) | (src << 16) | (dest << 12) | (rotation << 10) | (7 << 4) | op2);
}
void ARMXEmitter::REV (ARMReg dest, ARMReg src )
{
Write32(condition | (107 << 20) | (15 << 16) | (dest << 12) | (243 << 4) | src);
}
void ARMXEmitter::_MSR (bool write_nzcvq, bool write_g, Operand2 op2)
{
Write32(condition | (0x320F << 12) | (write_nzcvq << 19) | (write_g << 18) | op2.Imm12Mod());
}
void ARMXEmitter::_MSR (bool write_nzcvq, bool write_g, ARMReg src)
{
Write32(condition | (0x120F << 12) | (write_nzcvq << 19) | (write_g << 18) | src);
}
void ARMXEmitter::MRS (ARMReg dest)
{
Write32(condition | (16 << 20) | (15 << 16) | (dest << 12));
}
void ARMXEmitter::WriteStoreOp(u32 op, ARMReg dest, ARMReg src, Operand2 op2)
{
if (op2.GetData() == 0) // Don't index
Write32(condition | 0x00800000 | (op << 20) | (dest << 16) | (src << 12) | op2.Imm12());
else
Write32(condition | (op << 20) | (3 << 23) | (dest << 16) | (src << 12) | op2.Imm12());
}
void ARMXEmitter::STR (ARMReg dest, ARMReg src, Operand2 op) { WriteStoreOp(0x40, dest, src, op);}
void ARMXEmitter::STRB(ARMReg dest, ARMReg src, Operand2 op) { WriteStoreOp(0x44, dest, src, op);}
void ARMXEmitter::STR (ARMReg dest, ARMReg base, ARMReg offset, bool Index, bool Add)
{
Write32(condition | (0x60 << 20) | (Index << 24) | (Add << 23) | (dest << 16) | (base << 12) | offset);
}
void ARMXEmitter::LDREX(ARMReg dest, ARMReg base)
{
Write32(condition | (25 << 20) | (base << 16) | (dest << 12) | 0xF9F);
}
void ARMXEmitter::STREX(ARMReg dest, ARMReg base, ARMReg op)
{
_assert_msg_(DYNA_REC, (dest != base && dest != op), "STREX dest can't be other two registers");
Write32(condition | (24 << 20) | (base << 16) | (dest << 12) | (0xF9 << 4) | op);
}
void ARMXEmitter::DMB ()
{
Write32(0xF57FF05E);
}
void ARMXEmitter::LDR (ARMReg dest, ARMReg src, Operand2 op) { WriteStoreOp(0x41, src, dest, op);}
void ARMXEmitter::LDRB(ARMReg dest, ARMReg src, Operand2 op) { WriteStoreOp(0x45, src, dest, op);}
void ARMXEmitter::LDR (ARMReg dest, ARMReg base, ARMReg offset, bool Index, bool Add)
{
Write32(condition | (0x61 << 20) | (Index << 24) | (Add << 23) | (base << 16) | (dest << 12) | offset);
}
void ARMXEmitter::WriteRegStoreOp(u32 op, ARMReg dest, bool WriteBack, u16 RegList)
{
Write32(condition | (op << 20) | (WriteBack << 21) | (dest << 16) | RegList);
}
void ARMXEmitter::STMFD(ARMReg dest, bool WriteBack, const int Regnum, ...)
{
u16 RegList = 0;
u8 Reg;
int i;
va_list vl;
va_start(vl, Regnum);
for (i=0;i<Regnum;i++)
{
Reg = va_arg(vl, u32);
RegList |= (1 << Reg);
}
va_end(vl);
WriteRegStoreOp(0x90, dest, WriteBack, RegList);
}
void ARMXEmitter::LDMFD(ARMReg dest, bool WriteBack, const int Regnum, ...)
{
u16 RegList = 0;
u8 Reg;
int i;
va_list vl;
va_start(vl, Regnum);
for (i=0;i<Regnum;i++)
{
Reg = va_arg(vl, u32);
RegList |= (1 << Reg);
}
va_end(vl);
WriteRegStoreOp(0x89, dest, WriteBack, RegList);
}
// NEON and ASIMD
void ARMXEmitter::VLDR(ARMReg Dest, ARMReg Base, Operand2 op)
{
_assert_msg_(DYNA_REC, Dest >= S0 && Dest <= D31, "Passed Invalid dest register to VLDR");
_assert_msg_(DYNA_REC, Base <= R15, "Passed invalid Base register to VLDR");
bool single_reg = Dest < D0;
if (single_reg)
Dest = (ARMReg)(Dest - S0);
else
Dest = (ARMReg)(Dest - D0);
Write32(NO_COND | (13 << 24) | ((Dest & 0x10) << 18) | (1 << 20) | (Base << 16) \
| (5 << 9) | (!single_reg << 8) | op.Imm8());
}
void ARMXEmitter::VMOV(ARMReg Dest, ARMReg Src)
{
if (Dest > R15)
{
if (Src < S0)
{
if (Dest < D0)
{
// Moving to a Neon register FROM ARM Reg
Dest = (ARMReg)(Dest - S0);
Write32(NO_COND | (0xE0 << 20) | ((Dest & 0x1E) << 15) | (Src << 12) \
| (0xA << 8) | ((Dest & 0x1) << 7) | (1 << 4));
return;
}
else
{
// Move 64bit from Arm reg
_assert_msg_(DYNA_REC, false, "This VMOV doesn't support moving 64bit ARM to NEON");
}
}
}
else
{
if (Src > R15)
{
if (Src < D0)
{
// Moving to ARM Reg from Neon Register
Src = (ARMReg)(Src - S0);
Write32(NO_COND | (0xE1 << 20) | ((Src & 0x1E) << 15) | (Dest << 12) \
| (0xA << 8) | ((Src & 0x1) << 7) | (1 << 4));
return;
}
else
{
// Move 64bit To Arm reg
_assert_msg_(DYNA_REC, false, "This VMOV doesn't support moving 64bit ARM From NEON");
}
}
else
{
// Move Arm reg to Arm reg
_assert_msg_(DYNA_REC, false, "VMOV doesn't support moving ARM registers");
}
}
// Moving NEON registers
int SrcSize = Src < D0 ? 1 : Src < Q0 ? 2 : 4;
int DestSize = Dest < D0 ? 1 : Dest < Q0 ? 2 : 4;
bool Single = DestSize == 1;
_assert_msg_(DYNA_REC, SrcSize == DestSize, "VMOV doesn't support moving different register sizes");
if (Single)
{
Dest = (ARMReg)(Dest - S0);
Src = (ARMReg)(Src - S0);
Write32(NO_COND | (0x1D << 23) | ((Dest & 0x1) << 22) | (0x3 << 20) | ((Dest & 0x1E) << 11) \
| (0x5 << 9) | (1 << 6) | ((Src & 0x1) << 5) | ((Src & 0x1E) >> 1));
}
else
{
// Double and quad
bool Quad = DestSize == 4;
if (Quad)
{
// Gets encoded as a Double register
Dest = (ARMReg)((Dest - Q0) * 2);
Src = (ARMReg)((Src - Q0) * 2);
}
else
{
Dest = (ARMReg)(Dest - D0);
Src = (ARMReg)(Src - D0);
}
Write32((0xF2 << 24) | ((Dest & 0x10) << 18) | (1 << 21) | ((Src & 0xF) << 16) \
| ((Dest & 0xF) << 12) | (1 << 8) | ((Src & 0x10) << 3) | (Quad << 6) \
| ((Src & 0x10) << 1) | (1 << 4) | (Src & 0xF));
}
}
}