// 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 "base/logging.h" #include #include #include #include #include #include // For cache flushing on Symbian/iOS/Blackberry #ifdef __SYMBIAN32__ #include #endif #ifdef IOS #include #include #endif #ifdef BLACKBERRY #include #endif #include "MemoryUtil.h" #include "ArmEmitter.h" #include "CPUDetect.h" // Want it in release builds too #ifdef ANDROID #undef _dbg_assert_msg_ #define _dbg_assert_msg_ _assert_msg_ #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; } } Operand2 AssumeMakeOperand2(u32 imm) { Operand2 op2; bool result = TryMakeOperand2(imm, op2); _dbg_assert_msg_(JIT, result, "Could not make assumed Operand2."); if (!result) { // Make double sure that we get it logged. ERROR_LOG(JIT, "Could not make assumed Operand2."); } return op2; } bool ARMXEmitter::TrySetValue_TwoOp(ARMReg reg, u32 val) { int ops = 0; for (int i = 0; i < 16; i++) { if ((val >> (i*2)) & 0x3) { ops++; i+=3; } } if (ops > 2) return false; bool first = true; for (int i = 0; i < 16; i++, val >>=2) { if (val & 0x3) { first ? MOV(reg, Operand2((u8)val, (u8)((16-i) & 0xF))) : ORR(reg, reg, Operand2((u8)val, (u8)((16-i) & 0xF))); first = false; i+=3; val >>= 6; } } return true; } bool TryMakeFloatIMM8(u32 val, Operand2 &op2) { if ((val & 0x0007FFFF) == 0) { // VFP Encoding for Imms: <7> Not(<6>) Repeat(<6>,5) <5:0> Zeros(19) bool bit6 = (val & 0x40000000) == 0x40000000; bool canEncode = true; for (u32 mask = 0x20000000; mask >= 0x02000000; mask >>= 1) { if (((val & mask) == mask) == bit6) canEncode = false; } if (canEncode) { u32 imm8 = (val & 0x80000000) >> 24; // sign bit imm8 |= (!bit6 << 6); imm8 |= (val & 0x01F80000) >> 19; op2 = IMM(imm8); return true; } } return false; } void ARMXEmitter::MOVI2FR(ARMReg dest, float val, bool negate) { union {float f; u32 u;} conv; conv.f = negate ? -val : val; MOVI2R(dest, conv.u); } void ARMXEmitter::MOVI2F(ARMReg dest, float val, ARMReg tempReg, bool negate) { union {float f; u32 u;} conv; conv.f = negate ? -val : val; // Try moving directly first if mantisse is empty Operand2 op2; if (cpu_info.bVFPv3 && TryMakeFloatIMM8(conv.u, op2)) VMOV(dest, op2); else { MOVI2R(tempReg, conv.u); VMOV(dest, tempReg); } // Otherwise, possible to use a literal pool and VLDR directly (+- 1020) } void ARMXEmitter::MOVI2F_neon(ARMReg dest, float val, ARMReg tempReg, bool negate) { union {float f; u32 u;} conv; conv.f = negate ? -val : val; // Try moving directly first if mantisse is empty Operand2 op2; if (cpu_info.bVFPv3 && TryMakeFloatIMM8(conv.u, op2)) VMOV_neon(F_32, dest, conv.u); else { MOVI2R(tempReg, conv.u); VDUP(F_32, dest, tempReg); } // Otherwise, possible to use a literal pool and VLD1 directly (+- 1020) } void ARMXEmitter::ADDI2R(ARMReg rd, ARMReg rs, u32 val, ARMReg scratch) { if (!TryADDI2R(rd, rs, val)) { MOVI2R(scratch, val); ADD(rd, rs, scratch); } } bool ARMXEmitter::TryADDI2R(ARMReg rd, ARMReg rs, u32 val) { if (val == 0) { if (rd != rs) MOV(rd, rs); return true; } Operand2 op2; bool negated; if (TryMakeOperand2_AllowNegation(val, op2, &negated)) { if (!negated) ADD(rd, rs, op2); else SUB(rd, rs, op2); return true; } else { // Try 16-bit additions and subtractions - easy to test for. // Should also try other rotations... if ((val & 0xFFFF0000) == 0) { // Decompose into two additions. ADD(rd, rs, Operand2((u8)(val >> 8), 12)); // rotation right by 12*2 == rotation left by 8 ADD(rd, rd, Operand2((u8)(val), 0)); return true; } else if ((((u32)-(s32)val) & 0xFFFF0000) == 0) { val = (u32)-(s32)val; SUB(rd, rs, Operand2((u8)(val >> 8), 12)); SUB(rd, rd, Operand2((u8)(val), 0)); return true; } else { return false; } } } void ARMXEmitter::SUBI2R(ARMReg rd, ARMReg rs, u32 val, ARMReg scratch) { if (!TrySUBI2R(rd, rs, val)) { MOVI2R(scratch, val); SUB(rd, rs, scratch); } } bool ARMXEmitter::TrySUBI2R(ARMReg rd, ARMReg rs, u32 val) { // Just add a negative. return TryADDI2R(rd, rs, (u32)-(s32)val); } void ARMXEmitter::ANDI2R(ARMReg rd, ARMReg rs, u32 val, ARMReg scratch) { if (!TryANDI2R(rd, rs, val)) { MOVI2R(scratch, val); AND(rd, rs, scratch); } } bool ARMXEmitter::TryANDI2R(ARMReg rd, ARMReg rs, u32 val) { Operand2 op2; bool inverse; if (val == 0) { // Avoid the ALU, may improve pipeline. MOV(rd, 0); return true; } else if (TryMakeOperand2_AllowInverse(val, op2, &inverse)) { if (!inverse) { AND(rd, rs, op2); } else { BIC(rd, rs, op2); } return true; } else { #ifdef HAVE_ARMV7 // Check if we have a single pattern of sequential bits. int seq = -1; for (int i = 0; i < 32; ++i) { if (((val >> i) & 1) == 0) { if (seq == -1) { // The width is all bits previous to this, set to 1. seq = i; } } else if (seq != -1) { // Uh oh, more than one sequence. seq = -2; } } if (seq > 0) { UBFX(rd, rs, 0, seq); return true; } #endif int ops = 0; for (int i = 0; i < 32; i += 2) { u8 bits = RotR(val, i) & 0xFF; // If either low bit is not set, we need to use a BIC for them. if ((bits & 3) != 3) { ++ops; i += 8 - 2; } } // The worst case is 4 (e.g. 0x55555555.) #ifdef HAVE_ARMV7 if (ops > 3) { return false; } #endif bool first = true; for (int i = 0; i < 32; i += 2) { u8 bits = RotR(val, i) & 0xFF; if ((bits & 3) != 3) { u8 rotation = i == 0 ? 0 : 16 - i / 2; if (first) { BIC(rd, rs, Operand2(~bits, rotation)); first = false; } else { BIC(rd, rd, Operand2(~bits, rotation)); } // Well, we took care of these other bits while we were at it. i += 8 - 2; } } return true; } } void ARMXEmitter::CMPI2R(ARMReg rs, u32 val, ARMReg scratch) { if (!TryCMPI2R(rs, val)) { MOVI2R(scratch, val); CMP(rs, scratch); } } bool ARMXEmitter::TryCMPI2R(ARMReg rs, u32 val) { Operand2 op2; bool negated; if (TryMakeOperand2_AllowNegation(val, op2, &negated)) { if (!negated) CMP(rs, op2); else CMN(rs, op2); return true; } else { return false; } } void ARMXEmitter::TSTI2R(ARMReg rs, u32 val, ARMReg scratch) { if (!TryTSTI2R(rs, val)) { MOVI2R(scratch, val); TST(rs, scratch); } } bool ARMXEmitter::TryTSTI2R(ARMReg rs, u32 val) { Operand2 op2; if (TryMakeOperand2(val, op2)) { TST(rs, op2); return true; } else { return false; } } void ARMXEmitter::ORI2R(ARMReg rd, ARMReg rs, u32 val, ARMReg scratch) { if (!TryORI2R(rd, rs, val)) { MOVI2R(scratch, val); ORR(rd, rs, scratch); } } bool ARMXEmitter::TryORI2R(ARMReg rd, ARMReg rs, u32 val) { Operand2 op2; if (val == 0) { // Avoid the ALU, may improve pipeline. if (rd != rs) { MOV(rd, rs); } return true; } else if (TryMakeOperand2(val, op2)) { ORR(rd, rs, op2); return true; } else { int ops = 0; for (int i = 0; i < 32; i += 2) { u8 bits = RotR(val, i) & 0xFF; // If either low bit is set, we need to use a ORR for them. if ((bits & 3) != 0) { ++ops; i += 8 - 2; } } // The worst case is 4 (e.g. 0x55555555.) But MVN can make it 2. Not sure if better. bool inversed; if (TryMakeOperand2_AllowInverse(val, op2, &inversed) && ops >= 3) { return false; #ifdef HAVE_ARMV7 } else if (ops > 3) { return false; #endif } bool first = true; for (int i = 0; i < 32; i += 2) { u8 bits = RotR(val, i) & 0xFF; if ((bits & 3) != 0) { u8 rotation = i == 0 ? 0 : 16 - i / 2; if (first) { ORR(rd, rs, Operand2(bits, rotation)); first = false; } else { ORR(rd, rd, Operand2(bits, rotation)); } // Well, we took care of these other bits while we were at it. i += 8 - 2; } } return true; } } void ARMXEmitter::EORI2R(ARMReg rd, ARMReg rs, u32 val, ARMReg scratch) { if (!TryEORI2R(rd, rs, val)) { MOVI2R(scratch, val); EOR(rd, rs, scratch); } } bool ARMXEmitter::TryEORI2R(ARMReg rd, ARMReg rs, u32 val) { Operand2 op2; if (val == 0) { if (rd != rs) { MOV(rd, rs); } return true; } else if (TryMakeOperand2(val, op2)) { EOR(rd, rs, op2); return true; } else { return false; } } void ARMXEmitter::FlushLitPool() { for (LiteralPool& pool : currentLitPool) { // Search for duplicates for (LiteralPool& old_pool : currentLitPool) { if (old_pool.val == pool.val) pool.loc = old_pool.loc; } // Write the constant to Literal Pool if (!pool.loc) { pool.loc = (intptr_t)code; Write32(pool.val); } s32 offset = (s32)(pool.loc - (intptr_t)pool.ldr_address - 8); // Backpatch the LDR *(u32*)pool.ldr_address |= (offset >= 0) << 23 | abs(offset); } // TODO: Save a copy of previous pools in case they are still in range. currentLitPool.clear(); } void ARMXEmitter::AddNewLit(u32 val) { LiteralPool pool_item; pool_item.loc = 0; pool_item.val = val; pool_item.ldr_address = code; currentLitPool.push_back(pool_item); } void ARMXEmitter::MOVI2R(ARMReg reg, u32 val, bool optimize) { Operand2 op2; bool inverse; #ifdef HAVE_ARMV7 // Unused if (!optimize) { // For backpatching on ARMv7 MOVW(reg, val & 0xFFFF); MOVT(reg, val, true); return; } #endif if (TryMakeOperand2_AllowInverse(val, op2, &inverse)) { inverse ? MVN(reg, op2) : MOV(reg, op2); } else { #ifdef HAVE_ARMV7 // Use MOVW+MOVT for ARMv7+ MOVW(reg, val & 0xFFFF); if(val & 0xFFFF0000) MOVT(reg, val, true); #else if (!TrySetValue_TwoOp(reg,val)) { bool first = true; for (int i = 0; i < 32; i += 2) { u8 bits = RotR(val, i) & 0xFF; if ((bits & 3) != 0) { u8 rotation = i == 0 ? 0 : 16 - i / 2; if (first) { MOV(reg, Operand2(bits, rotation)); first = false; } else { ORR(reg, reg, Operand2(bits, rotation)); } // Well, we took care of these other bits while we were at it. i += 8 - 2; } } // Use literal pool for ARMv6. // Disabled for now as it is crashfing since Vertex Decoder JIT // AddNewLit(val); // LDR(reg, R_PC); // To be backpatched later } #endif } } static const char *armRegStrings[] = { "r0","r1","r2","r3", "r4","r5","r6","r7", "r8","r9","r10","r11", "r12","r13","r14","PC", "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "s12", "s13", "s14", "s15", "s16", "s17", "s18", "s19", "s20", "s21", "s22", "s23", "s24", "s25", "s26", "s27", "s28", "s29", "s30", "s31", "d0", "d1", "d2", "d3", "d4", "d5", "d6", "d7", "d8", "d9", "d10", "d11", "d12", "d13", "d14", "d15", "d16", "d17", "d18", "d19", "d20", "d21", "d22", "d23", "d24", "d25", "d26", "d27", "d28", "d29", "d30", "d31", "q0", "q1", "q2", "q3", "q4", "q5", "q6", "q7", "q8", "q9", "q10", "q11", "q12", "q13", "q14", "q15", }; const char *ARMRegAsString(ARMReg reg) { if ((unsigned int)reg >= sizeof(armRegStrings)/sizeof(armRegStrings[0])) return "(bad)"; return armRegStrings[(int)reg]; } void ARMXEmitter::QuickCallFunction(ARMReg reg, const void *func) { if (BLInRange(func)) { BL(func); } else { MOVP2R(reg, func); BL(reg); } } void ARMXEmitter::SetCodePtr(u8 *ptr) { code = ptr; startcode = code; lastCacheFlushEnd = ptr; } 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((-(intptr_t)code) & 15); return code; } const u8 *ARMXEmitter::AlignCodePage() { ReserveCodeSpace((-(intptr_t)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); #elif defined(IOS) // Header file says this is equivalent to: sys_icache_invalidate(start, end - start); sys_cache_control(kCacheFunctionPrepareForExecution, start, end - start); #elif !defined(_WIN32) #if defined(ARM) #ifdef __clang__ __clear_cache(start, end); #else __builtin___clear_cache(start, end); #endif #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) { ptrdiff_t distance = (intptr_t)fnptr - ((intptr_t)(code) + 8); _assert_msg_(JIT, distance > -0x2000000 && distance <= 0x2000000, "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) { ptrdiff_t distance = ((intptr_t)(code) - 8) - (intptr_t)branch.ptr; _assert_msg_(JIT, distance > -0x2000000 && distance <= 0x2000000, "SetJumpTarget out of range (%p calls %p)", code, branch.ptr); u32 instr = (u32)(branch.condition | ((distance >> 2) & 0x00FFFFFF)); instr |= branch.type == 0 ? /* B */ 0x0A000000 : /* BL */ 0x0B000000; *(u32*)branch.ptr = instr; } void ARMXEmitter::B (const void *fnptr) { ptrdiff_t distance = (intptr_t)fnptr - (intptr_t(code) + 8); _assert_msg_(JIT, distance > -0x2000000 && distance <= 0x2000000, "B out of range (%p calls %p)", code, fnptr); Write32(condition | 0x0A000000 | ((distance >> 2) & 0x00FFFFFF)); } void ARMXEmitter::B(ARMReg src) { Write32(condition | 0x012FFF10 | src); } bool ARMXEmitter::BLInRange(const void *fnptr) const { ptrdiff_t distance = (intptr_t)fnptr - (intptr_t(code) + 8); if (distance <= -0x2000000 || distance > 0x2000000) return false; else return true; } void ARMXEmitter::BL(const void *fnptr) { ptrdiff_t distance = (intptr_t)fnptr - (intptr_t(code) + 8); _assert_msg_(JIT, distance > -0x2000000 && distance <= 0x2000000, "BL out of range (%p calls %p)", code, fnptr); Write32(condition | 0x0B000000 | ((distance >> 2) & 0x00FFFFFF)); } void ARMXEmitter::BL(ARMReg src) { Write32(condition | 0x012FFF30 | 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> 16 : Rm); } void ARMXEmitter::WriteInstruction (u32 Op, ARMReg Rd, ARMReg Rn, Operand2 Rm, bool SetFlags) // This can get renamed later { s32 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 == -1) _assert_msg_(JIT, 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::LSR (ARMReg dest, ARMReg src, Operand2 op2) { _assert_msg_(JIT, op2.GetType() != TYPE_IMM || op2.Imm5() != 0, "LSR must have a non-zero shift (use LSL.)"); WriteShiftedDataOp(2, false, dest, src, op2); } void ARMXEmitter::LSRS(ARMReg dest, ARMReg src, Operand2 op2) { _assert_msg_(JIT, op2.GetType() != TYPE_IMM || op2.Imm5() != 0, "LSRS must have a non-zero shift (use LSLS.)"); WriteShiftedDataOp(2, true, dest, src, op2); } void ARMXEmitter::LSR (ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(3, false, dest, src, op2);} void ARMXEmitter::LSRS(ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(3, true, dest, src, op2);} void ARMXEmitter::ASR (ARMReg dest, ARMReg src, Operand2 op2) { _assert_msg_(JIT, op2.GetType() != TYPE_IMM || op2.Imm5() != 0, "ASR must have a non-zero shift (use LSL.)"); WriteShiftedDataOp(4, false, dest, src, op2); } void ARMXEmitter::ASRS(ARMReg dest, ARMReg src, Operand2 op2) { _assert_msg_(JIT, op2.GetType() != TYPE_IMM || op2.Imm5() != 0, "ASRS must have a non-zero shift (use LSLS.)"); WriteShiftedDataOp(4, true, dest, src, op2); } void ARMXEmitter::ASR (ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(5, false, dest, src, op2);} void ARMXEmitter::ASRS(ARMReg dest, ARMReg src, ARMReg op2) { WriteShiftedDataOp(5, 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::Write4OpMultiply(u32 op, ARMReg destLo, ARMReg destHi, ARMReg rm, ARMReg rn) { Write32(condition | (op << 20) | (destHi << 16) | (destLo << 12) | (rm << 8) | (9 << 4) | rn); } void ARMXEmitter::UMULL(ARMReg destLo, ARMReg destHi, ARMReg rm, ARMReg rn) { Write4OpMultiply(0x8, destLo, destHi, rn, rm); } void ARMXEmitter::SMULL(ARMReg destLo, ARMReg destHi, ARMReg rm, ARMReg rn) { Write4OpMultiply(0xC, destLo, destHi, rn, rm); } void ARMXEmitter::UMLAL(ARMReg destLo, ARMReg destHi, ARMReg rm, ARMReg rn) { Write4OpMultiply(0xA, destLo, destHi, rn, rm); } void ARMXEmitter::SMLAL(ARMReg destLo, ARMReg destHi, ARMReg rm, ARMReg rn) { Write4OpMultiply(0xE, destLo, destHi, rn, rm); } void ARMXEmitter::UBFX(ARMReg dest, ARMReg rn, u8 lsb, u8 width) { Write32(condition | (0x7E0 << 16) | ((width - 1) << 16) | (dest << 12) | (lsb << 7) | (5 << 4) | rn); } void ARMXEmitter::SBFX(ARMReg dest, ARMReg rn, u8 lsb, u8 width) { Write32(condition | (0x7A0 << 16) | ((width - 1) << 16) | (dest << 12) | (lsb << 7) | (5 << 4) | rn); } void ARMXEmitter::CLZ(ARMReg rd, ARMReg rm) { Write32(condition | (0x16F << 16) | (rd << 12) | (0xF1 << 4) | rm); } void ARMXEmitter::PLD(ARMReg rn, int offset, bool forWrite) { _dbg_assert_msg_(JIT, offset < 0x3ff && offset > -0x3ff, "PLD: Max 12 bits of offset allowed"); bool U = offset >= 0; if (offset < 0) offset = -offset; bool R = !forWrite; // Conditions not allowed Write32((0xF5 << 24) | (U << 23) | (R << 22) | (1 << 20) | ((int)rn << 16) | (0xF << 12) | offset); } void ARMXEmitter::BFI(ARMReg rd, ARMReg rn, u8 lsb, u8 width) { u32 msb = (lsb + width - 1); if (msb > 31) msb = 31; Write32(condition | (0x7C0 << 16) | (msb << 16) | (rd << 12) | (lsb << 7) | (1 << 4) | rn); } void ARMXEmitter::BFC(ARMReg rd, u8 lsb, u8 width) { u32 msb = (lsb + width - 1); if (msb > 31) msb = 31; Write32(condition | (0x7C0 << 16) | (msb << 16) | (rd << 12) | (lsb << 7) | (1 << 4) | 15); } 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::RBIT(ARMReg dest, ARMReg src) { Write32(condition | (0x6F << 20) | (0xF << 16) | (dest << 12) | (0xF3 << 4) | src); } void ARMXEmitter::REV (ARMReg dest, ARMReg src) { Write32(condition | (0x6BF << 16) | (dest << 12) | (0xF3 << 4) | src); } void ARMXEmitter::REV16(ARMReg dest, ARMReg src) { Write32(condition | (0x6BF << 16) | (dest << 12) | (0xFB << 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::LDREX(ARMReg dest, ARMReg base) { Write32(condition | (25 << 20) | (base << 16) | (dest << 12) | 0xF9F); } void ARMXEmitter::STREX(ARMReg result, ARMReg base, ARMReg op) { _assert_msg_(JIT, (result != base && result != op), "STREX dest can't be other two registers"); Write32(condition | (24 << 20) | (base << 16) | (result << 12) | (0xF9 << 4) | op); } void ARMXEmitter::DMB () { Write32(0xF57FF05E); } void ARMXEmitter::SVC(Operand2 op) { Write32(condition | (0x0F << 24) | op.Imm24()); } // IMM, REG, IMMSREG, RSR // -1 for invalid if the instruction doesn't support that const s32 LoadStoreOps[][4] = { {0x40, 0x60, 0x60, -1}, // STR {0x41, 0x61, 0x61, -1}, // LDR {0x44, 0x64, 0x64, -1}, // STRB {0x45, 0x65, 0x65, -1}, // LDRB // Special encodings { 0x4, 0x0, -1, -1}, // STRH { 0x5, 0x1, -1, -1}, // LDRH { 0x5, 0x1, -1, -1}, // LDRSB { 0x5, 0x1, -1, -1}, // LDRSH }; const char *LoadStoreNames[] = { "STR", "LDR", "STRB", "LDRB", "STRH", "LDRH", "LDRSB", "LDRSH", }; void ARMXEmitter::WriteStoreOp(u32 Op, ARMReg Rt, ARMReg Rn, Operand2 Rm, bool RegAdd) { s32 op = LoadStoreOps[Op][Rm.GetType()]; // Type always decided by last operand u32 Data; // Qualcomm chipsets get /really/ angry if you don't use index, even if the offset is zero. // Some of these encodings require Index at all times anyway. Doesn't really matter. // bool Index = op2 != 0 ? true : false; bool Index = true; bool Add = false; // Special Encoding (misc addressing mode) bool SpecialOp = false; bool Half = false; bool SignedLoad = false; if (op == -1) _assert_msg_(JIT, false, "%s does not support %d", LoadStoreNames[Op], Rm.GetType()); switch (Op) { case 4: // STRH SpecialOp = true; Half = true; SignedLoad = false; break; case 5: // LDRH SpecialOp = true; Half = true; SignedLoad = false; break; case 6: // LDRSB SpecialOp = true; Half = false; SignedLoad = true; break; case 7: // LDRSH SpecialOp = true; Half = true; SignedLoad = true; break; } switch (Rm.GetType()) { case TYPE_IMM: { s32 Temp = (s32)Rm.Value; Data = abs(Temp); // The offset is encoded differently on this one. if (SpecialOp) Data = ((Data & 0xF0) << 4) | (Data & 0xF); if (Temp >= 0) Add = true; } break; case TYPE_REG: Data = Rm.GetData(); Add = RegAdd; break; case TYPE_IMMSREG: if (!SpecialOp) { Data = Rm.GetData(); Add = RegAdd; break; } // Intentional fallthrough: TYPE_IMMSREG not supported for misc addressing. default: // RSR not supported for any of these // We already have the warning above BKPT(0x2); return; break; } if (SpecialOp) { // Add SpecialOp things Data = (0x9 << 4) | (SignedLoad << 6) | (Half << 5) | Data; } Write32(condition | (op << 20) | (Index << 24) | (Add << 23) | (Rn << 16) | (Rt << 12) | Data); } void ARMXEmitter::LDR (ARMReg dest, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(1, dest, base, op2, RegAdd);} void ARMXEmitter::LDRB(ARMReg dest, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(3, dest, base, op2, RegAdd);} void ARMXEmitter::LDRH(ARMReg dest, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(5, dest, base, op2, RegAdd);} void ARMXEmitter::LDRSB(ARMReg dest, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(6, dest, base, op2, RegAdd);} void ARMXEmitter::LDRSH(ARMReg dest, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(7, dest, base, op2, RegAdd);} void ARMXEmitter::STR (ARMReg result, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(0, result, base, op2, RegAdd);} void ARMXEmitter::STRH (ARMReg result, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(4, result, base, op2, RegAdd);} void ARMXEmitter::STRB (ARMReg result, ARMReg base, Operand2 op2, bool RegAdd) { WriteStoreOp(2, result, base, op2, RegAdd);} #define VA_TO_REGLIST(RegList, Regnum) \ { \ u8 Reg; \ va_list vl; \ va_start(vl, Regnum); \ for (int i = 0; i < Regnum; i++) \ { \ Reg = va_arg(vl, u32); \ RegList |= (1 << Reg); \ } \ va_end(vl); \ } void ARMXEmitter::WriteRegStoreOp(u32 op, ARMReg dest, bool WriteBack, u16 RegList) { Write32(condition | (op << 20) | (WriteBack << 21) | (dest << 16) | RegList); } void ARMXEmitter::WriteVRegStoreOp(u32 op, ARMReg Rn, bool Double, bool WriteBack, ARMReg Vd, u8 numregs) { _dbg_assert_msg_(JIT, !WriteBack || Rn != R_PC, "VLDM/VSTM cannot use WriteBack with PC (PC is deprecated anyway.)"); Write32(condition | (op << 20) | (WriteBack << 21) | (Rn << 16) | EncodeVd(Vd) | ((0xA | (int)Double) << 8) | (numregs << (int)Double)); } void ARMXEmitter::STMFD(ARMReg dest, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | 0x10 | 0, dest, WriteBack, RegList); } void ARMXEmitter::LDMFD(ARMReg dest, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | 0x08 | 1, dest, WriteBack, RegList); } void ARMXEmitter::STMIA(ARMReg dest, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | 0x08 | 0, dest, WriteBack, RegList); } void ARMXEmitter::LDMIA(ARMReg dest, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | 0x08 | 1, dest, WriteBack, RegList); } void ARMXEmitter::STM(ARMReg dest, bool Add, bool Before, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | (Before << 4) | (Add << 3) | 0, dest, WriteBack, RegList); } void ARMXEmitter::LDM(ARMReg dest, bool Add, bool Before, bool WriteBack, const int Regnum, ...) { u16 RegList = 0; VA_TO_REGLIST(RegList, Regnum); WriteRegStoreOp(0x80 | (Before << 4) | (Add << 3) | 1, dest, WriteBack, RegList); } void ARMXEmitter::STMBitmask(ARMReg dest, bool Add, bool Before, bool WriteBack, const u16 RegList) { WriteRegStoreOp(0x80 | (Before << 4) | (Add << 3) | 0, dest, WriteBack, RegList); } void ARMXEmitter::LDMBitmask(ARMReg dest, bool Add, bool Before, bool WriteBack, const u16 RegList) { WriteRegStoreOp(0x80 | (Before << 4) | (Add << 3) | 1, dest, WriteBack, RegList); } #undef VA_TO_REGLIST // NEON Specific void ARMXEmitter::VABD(IntegerSize Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _assert_msg_(JIT, Vd >= D0, "Pass invalid register to VABD(float)"); _assert_msg_(JIT, cpu_info.bNEON, "Can't use VABD(float) when CPU doesn't support it"); bool register_quad = Vd >= Q0; // Gets encoded as a double register Vd = SubBase(Vd); Vn = SubBase(Vn); Vm = SubBase(Vm); Write32((0xF3 << 24) | ((Vd & 0x10) << 18) | (Size << 20) | ((Vn & 0xF) << 16) \ | ((Vd & 0xF) << 12) | (0xD << 8) | ((Vn & 0x10) << 3) | (register_quad << 6) \ | ((Vm & 0x10) << 2) | (Vm & 0xF)); } void ARMXEmitter::VADD(IntegerSize Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _assert_msg_(JIT, Vd >= D0, "Pass invalid register to VADD(integer)"); _assert_msg_(JIT, cpu_info.bNEON, "Can't use VADD(integer) when CPU doesn't support it"); bool register_quad = Vd >= Q0; // Gets encoded as a double register Vd = SubBase(Vd); Vn = SubBase(Vn); Vm = SubBase(Vm); Write32((0xF2 << 24) | ((Vd & 0x10) << 18) | (Size << 20) | ((Vn & 0xF) << 16) \ | ((Vd & 0xF) << 12) | (0x8 << 8) | ((Vn & 0x10) << 3) | (register_quad << 6) \ | ((Vm & 0x10) << 1) | (Vm & 0xF)); } void ARMXEmitter::VSUB(IntegerSize Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _assert_msg_(JIT, Vd >= Q0, "Pass invalid register to VSUB(integer)"); _assert_msg_(JIT, cpu_info.bNEON, "Can't use VSUB(integer) when CPU doesn't support it"); // Gets encoded as a double register Vd = SubBase(Vd); Vn = SubBase(Vn); Vm = SubBase(Vm); Write32((0xF3 << 24) | ((Vd & 0x10) << 18) | (Size << 20) | ((Vn & 0xF) << 16) \ | ((Vd & 0xF) << 12) | (0x8 << 8) | ((Vn & 0x10) << 3) | (1 << 6) \ | ((Vm & 0x10) << 2) | (Vm & 0xF)); } extern const VFPEnc VFPOps[16][2] = { {{0xE0, 0xA0}, { -1, -1}}, // 0: VMLA {{0xE1, 0xA4}, { -1, -1}}, // 1: VNMLA {{0xE0, 0xA4}, { -1, -1}}, // 2: VMLS {{0xE1, 0xA0}, { -1, -1}}, // 3: VNMLS {{0xE3, 0xA0}, { -1, -1}}, // 4: VADD {{0xE3, 0xA4}, { -1, -1}}, // 5: VSUB {{0xE2, 0xA0}, { -1, -1}}, // 6: VMUL {{0xE2, 0xA4}, { -1, -1}}, // 7: VNMUL {{0xEB, 0xAC}, { -1 /* 0x3B */, -1 /* 0x70 */}}, // 8: VABS(Vn(0x0) used for encoding) {{0xE8, 0xA0}, { -1, -1}}, // 9: VDIV {{0xEB, 0xA4}, { -1 /* 0x3B */, -1 /* 0x78 */}}, // 10: VNEG(Vn(0x1) used for encoding) {{0xEB, 0xAC}, { -1, -1}}, // 11: VSQRT (Vn(0x1) used for encoding) {{0xEB, 0xA4}, { -1, -1}}, // 12: VCMP (Vn(0x4 | #0 ? 1 : 0) used for encoding) {{0xEB, 0xAC}, { -1, -1}}, // 13: VCMPE (Vn(0x4 | #0 ? 1 : 0) used for encoding) {{ -1, -1}, {0x3B, 0x30}}, // 14: VABSi }; const char *VFPOpNames[16] = { "VMLA", "VNMLA", "VMLS", "VNMLS", "VADD", "VSUB", "VMUL", "VNMUL", "VABS", "VDIV", "VNEG", "VSQRT", "VCMP", "VCMPE", "VABSi", }; u32 EncodeVd(ARMReg Vd) { bool quad_reg = Vd >= Q0; bool double_reg = Vd >= D0; ARMReg Reg = SubBase(Vd); if (quad_reg) return ((Reg & 0x10) << 18) | ((Reg & 0xF) << 12); else { if (double_reg) return ((Reg & 0x10) << 18) | ((Reg & 0xF) << 12); else return ((Reg & 0x1) << 22) | ((Reg & 0x1E) << 11); } } u32 EncodeVn(ARMReg Vn) { bool quad_reg = Vn >= Q0; bool double_reg = Vn >= D0; ARMReg Reg = SubBase(Vn); if (quad_reg) return ((Reg & 0xF) << 16) | ((Reg & 0x10) << 3); else { if (double_reg) return ((Reg & 0xF) << 16) | ((Reg & 0x10) << 3); else return ((Reg & 0x1E) << 15) | ((Reg & 0x1) << 7); } } u32 EncodeVm(ARMReg Vm) { bool quad_reg = Vm >= Q0; bool double_reg = Vm >= D0; ARMReg Reg = SubBase(Vm); if (quad_reg) return ((Reg & 0x10) << 1) | (Reg & 0xF); else { if (double_reg) return ((Reg & 0x10) << 1) | (Reg & 0xF); else return ((Reg & 0x1) << 5) | (Reg >> 1); } } u32 encodedSize(u32 value) { if (value & I_8) return 0; else if (value & I_16) return 1; else if ((value & I_32) || (value & F_32)) return 2; else if (value & I_64) return 3; else _dbg_assert_msg_(JIT, false, "Passed invalid size to integer NEON instruction"); return 0; } ARMReg SubBase(ARMReg Reg) { if (Reg >= S0) { if (Reg >= D0) { if (Reg >= Q0) return (ARMReg)((Reg - Q0) * 2); // Always gets encoded as a double register return (ARMReg)(Reg - D0); } return (ARMReg)(Reg - S0); } return Reg; } ARMReg DScalar(ARMReg dreg, int subScalar) { int dr = (int)(SubBase(dreg)) & 0xF; int scalar = ((subScalar << 4) | dr); ARMReg ret = (ARMReg)(D0 + scalar); // ILOG("Scalar: %i D0: %i AR: %i", scalar, (int)D0, (int)ret); return ret; } // Convert to a DScalar ARMReg QScalar(ARMReg qreg, int subScalar) { int dr = (int)(SubBase(qreg)) & 0xF; if (subScalar & 2) { dr++; } int scalar = (((subScalar & 1) << 4) | dr); ARMReg ret = (ARMReg)(D0 + scalar); return ret; } void ARMXEmitter::WriteVFPDataOp(u32 Op, ARMReg Vd, ARMReg Vn, ARMReg Vm) { bool quad_reg = Vd >= Q0; bool double_reg = Vd >= D0 && Vd < Q0; VFPEnc enc = VFPOps[Op][quad_reg]; if (enc.opc1 == -1 && enc.opc2 == -1) _assert_msg_(JIT, false, "%s does not support %s", VFPOpNames[Op], quad_reg ? "NEON" : "VFP"); u32 VdEnc = EncodeVd(Vd); u32 VnEnc = EncodeVn(Vn); u32 VmEnc = EncodeVm(Vm); u32 cond = quad_reg ? (0xF << 28) : condition; Write32(cond | (enc.opc1 << 20) | VnEnc | VdEnc | (enc.opc2 << 4) | (quad_reg << 6) | (double_reg << 8) | VmEnc); } void ARMXEmitter::VMLA(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(0, Vd, Vn, Vm); } void ARMXEmitter::VNMLA(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(1, Vd, Vn, Vm); } void ARMXEmitter::VMLS(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(2, Vd, Vn, Vm); } void ARMXEmitter::VNMLS(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(3, Vd, Vn, Vm); } void ARMXEmitter::VADD(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(4, Vd, Vn, Vm); } void ARMXEmitter::VSUB(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(5, Vd, Vn, Vm); } void ARMXEmitter::VMUL(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(6, Vd, Vn, Vm); } void ARMXEmitter::VNMUL(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(7, Vd, Vn, Vm); } void ARMXEmitter::VABS(ARMReg Vd, ARMReg Vm){ WriteVFPDataOp(8, Vd, D0, Vm); } void ARMXEmitter::VDIV(ARMReg Vd, ARMReg Vn, ARMReg Vm){ WriteVFPDataOp(9, Vd, Vn, Vm); } void ARMXEmitter::VNEG(ARMReg Vd, ARMReg Vm){ WriteVFPDataOp(10, Vd, D1, Vm); } void ARMXEmitter::VSQRT(ARMReg Vd, ARMReg Vm){ WriteVFPDataOp(11, Vd, D1, Vm); } void ARMXEmitter::VCMP(ARMReg Vd, ARMReg Vm){ WriteVFPDataOp(12, Vd, D4, Vm); } void ARMXEmitter::VCMPE(ARMReg Vd, ARMReg Vm){ WriteVFPDataOp(13, Vd, D4, Vm); } void ARMXEmitter::VCMP(ARMReg Vd){ WriteVFPDataOp(12, Vd, D5, D0); } void ARMXEmitter::VCMPE(ARMReg Vd){ WriteVFPDataOp(13, Vd, D5, D0); } void ARMXEmitter::VLDMIA(ARMReg ptr, bool WriteBack, ARMReg firstvreg, int numvregs) { WriteVRegStoreOp(0x80 | 0x40 | 0x8 | 1, ptr, firstvreg >= D0, WriteBack, firstvreg, numvregs); } void ARMXEmitter::VSTMIA(ARMReg ptr, bool WriteBack, ARMReg firstvreg, int numvregs) { WriteVRegStoreOp(0x80 | 0x40 | 0x8, ptr, firstvreg >= D0, WriteBack, firstvreg, numvregs); } void ARMXEmitter::VLDMDB(ARMReg ptr, bool WriteBack, ARMReg firstvreg, int numvregs) { _dbg_assert_msg_(JIT, WriteBack, "Writeback is required for VLDMDB"); WriteVRegStoreOp(0x80 | 0x040 | 0x10 | 1, ptr, firstvreg >= D0, WriteBack, firstvreg, numvregs); } void ARMXEmitter::VSTMDB(ARMReg ptr, bool WriteBack, ARMReg firstvreg, int numvregs) { _dbg_assert_msg_(JIT, WriteBack, "Writeback is required for VSTMDB"); WriteVRegStoreOp(0x80 | 0x040 | 0x10, ptr, firstvreg >= D0, WriteBack, firstvreg, numvregs); } void ARMXEmitter::VLDR(ARMReg Dest, ARMReg Base, s16 offset) { _assert_msg_(JIT, Dest >= S0 && Dest <= D31, "Passed Invalid dest register to VLDR"); _assert_msg_(JIT, Base <= R15, "Passed invalid Base register to VLDR"); bool Add = offset >= 0 ? true : false; u32 imm = abs(offset); _assert_msg_(JIT, (imm & 0xC03) == 0, "VLDR: Offset needs to be word aligned and small enough"); if (imm & 0xC03) ERROR_LOG(JIT, "VLDR: Bad offset %08x", imm); bool single_reg = Dest < D0; Dest = SubBase(Dest); if (single_reg) { Write32(condition | (0xD << 24) | (Add << 23) | ((Dest & 0x1) << 22) | (1 << 20) | (Base << 16) \ | ((Dest & 0x1E) << 11) | (10 << 8) | (imm >> 2)); } else { Write32(condition | (0xD << 24) | (Add << 23) | ((Dest & 0x10) << 18) | (1 << 20) | (Base << 16) \ | ((Dest & 0xF) << 12) | (11 << 8) | (imm >> 2)); } } void ARMXEmitter::VSTR(ARMReg Src, ARMReg Base, s16 offset) { _assert_msg_(JIT, Src >= S0 && Src <= D31, "Passed invalid src register to VSTR"); _assert_msg_(JIT, Base <= R15, "Passed invalid base register to VSTR"); bool Add = offset >= 0 ? true : false; u32 imm = abs(offset); _assert_msg_(JIT, (imm & 0xC03) == 0, "VSTR: Offset needs to be word aligned and small enough"); if (imm & 0xC03) ERROR_LOG(JIT, "VSTR: Bad offset %08x", imm); bool single_reg = Src < D0; Src = SubBase(Src); if (single_reg) { Write32(condition | (0xD << 24) | (Add << 23) | ((Src & 0x1) << 22) | (Base << 16) \ | ((Src & 0x1E) << 11) | (10 << 8) | (imm >> 2)); } else { Write32(condition | (0xD << 24) | (Add << 23) | ((Src & 0x10) << 18) | (Base << 16) \ | ((Src & 0xF) << 12) | (11 << 8) | (imm >> 2)); } } void ARMXEmitter::VMRS_APSR() { Write32(condition | 0x0EF10A10 | (15 << 12)); } void ARMXEmitter::VMRS(ARMReg Rt) { Write32(condition | (0xEF << 20) | (1 << 16) | (Rt << 12) | 0xA10); } void ARMXEmitter::VMSR(ARMReg Rt) { Write32(condition | (0xEE << 20) | (1 << 16) | (Rt << 12) | 0xA10); } void ARMXEmitter::VMOV(ARMReg Dest, Operand2 op2) { _assert_msg_(JIT, cpu_info.bVFPv3, "VMOV #imm requires VFPv3"); int sz = Dest >= D0 ? (1 << 8) : 0; Write32(condition | (0xEB << 20) | EncodeVd(Dest) | (5 << 9) | sz | op2.Imm8VFP()); } void ARMXEmitter::VMOV_neon(u32 Size, ARMReg Vd, u32 imm) { _assert_msg_(JIT, cpu_info.bNEON, "VMOV_neon #imm requires NEON"); _assert_msg_(JIT, Vd >= D0, "VMOV_neon #imm must target a double or quad"); bool register_quad = Vd >= Q0; int cmode = 0; int op = 0; Operand2 op2 = IMM(0); u32 imm8 = imm & 0xFF; imm8 = imm8 | (imm8 << 8) | (imm8 << 16) | (imm8 << 24); if (Size == I_8) { imm = imm8; } else if (Size == I_16) { imm &= 0xFFFF; imm = imm | (imm << 16); } if ((imm & 0x000000FF) == imm) { op = 0; cmode = 0 << 1; op2 = IMM(imm); } else if ((imm & 0x0000FF00) == imm) { op = 0; cmode = 1 << 1; op2 = IMM(imm >> 8); } else if ((imm & 0x00FF0000) == imm) { op = 0; cmode = 2 << 1; op2 = IMM(imm >> 16); } else if ((imm & 0xFF000000) == imm) { op = 0; cmode = 3 << 1; op2 = IMM(imm >> 24); } else if ((imm & 0x00FF00FF) == imm && (imm >> 16) == (imm & 0x00FF)) { op = 0; cmode = 4 << 1; op2 = IMM(imm & 0xFF); } else if ((imm & 0xFF00FF00) == imm && (imm >> 16) == (imm & 0xFF00)) { op = 0; cmode = 5 << 1; op2 = IMM(imm & 0xFF); } else if ((imm & 0x0000FFFF) == (imm | 0x000000FF)) { op = 0; cmode = (6 << 1) | 0; op2 = IMM(imm >> 8); } else if ((imm & 0x00FFFFFF) == (imm | 0x0000FFFF)) { op = 0; cmode = (6 << 1) | 1; op2 = IMM(imm >> 16); } else if (imm == imm8) { op = 0; cmode = (7 << 1) | 0; op2 = IMM(imm & 0xFF); } else if (TryMakeFloatIMM8(imm, op2)) { op = 0; cmode = (7 << 1) | 1; } else { // 64-bit constant form - technically we could take a u64. bool canEncode = true; u8 imm8 = 0; for (int i = 0, i8 = 0; i < 32; i += 8, ++i8) { u8 b = (imm >> i) & 0xFF; if (b == 0xFF) { imm8 |= 1 << i8; } else if (b != 0x00) { canEncode = false; } } if (canEncode) { // We don't want zeros in the second lane. op = 1; cmode = 7 << 1; op2 = IMM(imm8 | (imm8 << 4)); } else { _assert_msg_(JIT, false, "VMOV_neon #imm invalid constant value"); } } // No condition allowed. Write32((15 << 28) | (0x28 << 20) | EncodeVd(Vd) | (cmode << 8) | (register_quad << 6) | (op << 5) | (1 << 4) | op2.Imm8ASIMD()); } void ARMXEmitter::VMOV_neon(u32 Size, ARMReg Vd, ARMReg Rt, int lane) { _assert_msg_(JIT, cpu_info.bNEON, "VMOV_neon requires NEON"); int opc1 = 0; int opc2 = 0; switch (Size & ~(I_SIGNED | I_UNSIGNED)) { case I_8: opc1 = 2 | (lane >> 2); opc2 = lane & 3; break; case I_16: opc1 = lane >> 1; opc2 = 1 | ((lane & 1) << 1); break; case I_32: case F_32: opc1 = lane & 1; break; default: _assert_msg_(JIT, false, "VMOV_neon unsupported size"); } if (Vd < S0 && Rt >= D0 && Rt < Q0) { // Oh, reading to reg, our params are backwards. ARMReg Src = Rt; ARMReg Dest = Vd; _dbg_assert_msg_(JIT, (Size & (I_UNSIGNED | I_SIGNED | F_32)) != 0, "Must specify I_SIGNED or I_UNSIGNED in VMOV, unless F_32"); int U = (Size & I_UNSIGNED) ? (1 << 23) : 0; Write32(condition | (0xE1 << 20) | U | (opc1 << 21) | EncodeVn(Src) | (Dest << 12) | (0xB << 8) | (opc2 << 5) | (1 << 4)); } else if (Rt < S0 && Vd >= D0 && Vd < Q0) { ARMReg Src = Rt; ARMReg Dest = Vd; Write32(condition | (0xE0 << 20) | (opc1 << 21) | EncodeVn(Dest) | (Src << 12) | (0xB << 8) | (opc2 << 5) | (1 << 4)); } else _assert_msg_(JIT, false, "VMOV_neon unsupported arguments (Dx -> Rx or Rx -> Dx)"); } void ARMXEmitter::VMOV(ARMReg Vd, ARMReg Rt, ARMReg Rt2) { _assert_msg_(JIT, cpu_info.bVFP | cpu_info.bNEON, "VMOV_neon requires VFP or NEON"); if (Vd < S0 && Rt < S0 && Rt2 >= D0) { // Oh, reading to regs, our params are backwards. ARMReg Src = Rt2; ARMReg Dest1 = Vd; ARMReg Dest2 = Rt; Write32(condition | (0xC5 << 20) | (Dest2 << 16) | (Dest1 << 12) | (0xB << 8) | EncodeVm(Src) | (1 << 4)); } else if (Vd >= D0 && Rt < S0 && Rt2 < S0) { ARMReg Dest = Vd; ARMReg Src1 = Rt; ARMReg Src2 = Rt2; Write32(condition | (0xC4 << 20) | (Src2 << 16) | (Src1 << 12) | (0xB << 8) | EncodeVm(Dest) | (1 << 4)); } else _assert_msg_(JIT, false, "VMOV_neon requires either Dm, Rt, Rt2 or Rt, Rt2, Dm."); } void ARMXEmitter::VMOV(ARMReg Dest, ARMReg Src, bool high) { _assert_msg_(JIT, Src < S0, "This VMOV doesn't support SRC other than ARM Reg"); _assert_msg_(JIT, Dest >= D0, "This VMOV doesn't support DEST other than VFP"); Dest = SubBase(Dest); Write32(condition | (0xE << 24) | (high << 21) | ((Dest & 0xF) << 16) | (Src << 12) \ | (0xB << 8) | ((Dest & 0x10) << 3) | (1 << 4)); } void ARMXEmitter::VMOV(ARMReg Dest, ARMReg Src) { if (Dest == Src) { WARN_LOG(JIT, "VMOV %s, %s - same register", ARMRegAsString(Src), ARMRegAsString(Dest)); } if (Dest > R15) { if (Src < S0) { if (Dest < D0) { // Moving to a Neon register FROM ARM Reg Dest = (ARMReg)(Dest - S0); Write32(condition | (0xE0 << 20) | ((Dest & 0x1E) << 15) | (Src << 12) \ | (0xA << 8) | ((Dest & 0x1) << 7) | (1 << 4)); return; } else { // Move 64bit from Arm reg _assert_msg_(JIT, false, "This VMOV doesn't support moving 64bit ARM to NEON"); return; } } } else { if (Src > R15) { if (Src < D0) { // Moving to ARM Reg from Neon Register Src = (ARMReg)(Src - S0); Write32(condition | (0xE1 << 20) | ((Src & 0x1E) << 15) | (Dest << 12) \ | (0xA << 8) | ((Src & 0x1) << 7) | (1 << 4)); return; } else { // Move 64bit To Arm reg _assert_msg_(JIT, false, "This VMOV doesn't support moving 64bit ARM From NEON"); return; } } else { // Move Arm reg to Arm reg _assert_msg_(JIT, 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; bool Quad = DestSize == 4; _assert_msg_(JIT, SrcSize == DestSize, "VMOV doesn't support moving different register sizes"); if (SrcSize != DestSize) { ELOG("SrcSize: %i (%s) DestDize: %i (%s)", SrcSize, ARMRegAsString(Src), DestSize, ARMRegAsString(Dest)); } Dest = SubBase(Dest); Src = SubBase(Src); if (Single) { Write32(condition | (0x1D << 23) | ((Dest & 0x1) << 22) | (0x3 << 20) | ((Dest & 0x1E) << 11) \ | (0x5 << 9) | (1 << 6) | ((Src & 0x1) << 5) | ((Src & 0x1E) >> 1)); } else { // Double and quad if (Quad) { _assert_msg_(JIT, cpu_info.bNEON, "Trying to use quad registers when you don't support ASIMD."); // Gets encoded as a Double register Write32((0xF2 << 24) | ((Dest & 0x10) << 18) | (2 << 20) | ((Src & 0xF) << 16) \ | ((Dest & 0xF) << 12) | (1 << 8) | ((Src & 0x10) << 3) | (1 << 6) \ | ((Src & 0x10) << 1) | (1 << 4) | (Src & 0xF)); } else { Write32(condition | (0x1D << 23) | ((Dest & 0x10) << 18) | (0x3 << 20) | ((Dest & 0xF) << 12) \ | (0x2D << 6) | ((Src & 0x10) << 1) | (Src & 0xF)); } } } void ARMXEmitter::VCVT(ARMReg Dest, ARMReg Source, int flags) { bool single_reg = (Dest < D0) && (Source < D0); bool single_double = !single_reg && (Source < D0 || Dest < D0); bool single_to_double = Source < D0; int op = ((flags & TO_INT) ? (flags & ROUND_TO_ZERO) : (flags & IS_SIGNED)) ? 1 : 0; int op2 = ((flags & TO_INT) ? (flags & IS_SIGNED) : 0) ? 1 : 0; Dest = SubBase(Dest); Source = SubBase(Source); if (single_double) { // S32<->F64 if (flags & TO_INT) { if (single_to_double) { Write32(condition | (0x1D << 23) | ((Dest & 0x10) << 18) | (0x7 << 19) \ | ((Dest & 0xF) << 12) | (op << 7) | (0x2D << 6) | ((Source & 0x1) << 5) | (Source >> 1)); } else { Write32(condition | (0x1D << 23) | ((Dest & 0x1) << 22) | (0x7 << 19) | ((flags & TO_INT) << 18) | (op2 << 16) \ | ((Dest & 0x1E) << 11) | (op << 7) | (0x2D << 6) | ((Source & 0x10) << 1) | (Source & 0xF)); } } // F32<->F64 else { if (single_to_double) { Write32(condition | (0x1D << 23) | ((Dest & 0x10) << 18) | (0x3 << 20) | (0x7 << 16) \ | ((Dest & 0xF) << 12) | (0x2F << 6) | ((Source & 0x1) << 5) | (Source >> 1)); } else { Write32(condition | (0x1D << 23) | ((Dest & 0x1) << 22) | (0x3 << 20) | (0x7 << 16) \ | ((Dest & 0x1E) << 11) | (0x2B << 6) | ((Source & 0x10) << 1) | (Source & 0xF)); } } } else if (single_reg) { Write32(condition | (0x1D << 23) | ((Dest & 0x1) << 22) | (0x7 << 19) | ((flags & TO_INT) << 18) | (op2 << 16) \ | ((Dest & 0x1E) << 11) | (op << 7) | (0x29 << 6) | ((Source & 0x1) << 5) | (Source >> 1)); } else { Write32(condition | (0x1D << 23) | ((Dest & 0x10) << 18) | (0x7 << 19) | ((flags & TO_INT) << 18) | (op2 << 16) \ | ((Dest & 0xF) << 12) | (1 << 8) | (op << 7) | (0x29 << 6) | ((Source & 0x10) << 1) | (Source & 0xF)); } } void ARMXEmitter::VABA(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | EncodeVn(Vn) \ | (encodedSize(Size) << 20) | EncodeVd(Vd) | (0x71 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VABAL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= D0 && Vn < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (1 << 23) | EncodeVn(Vn) \ | (encodedSize(Size) << 20) | EncodeVd(Vd) | (0x50 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VABD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF3 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD << 8) | EncodeVm(Vm)); else Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | EncodeVn(Vn) \ | (encodedSize(Size) << 20) | EncodeVd(Vd) | (0x70 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VABDL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= D0 && Vn < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (1 << 23) | EncodeVn(Vn) \ | (encodedSize(Size) << 20) | EncodeVd(Vd) | (0x70 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VABS(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB1 << 16) | (encodedSize(Size) << 18) | EncodeVd(Vd) \ | ((Size & F_32 ? 1 : 0) << 10) | (0x30 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VACGE(ARMReg Vd, ARMReg Vn, ARMReg Vm) { // Only Float _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0xD1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VACGT(ARMReg Vd, ARMReg Vn, ARMReg Vm) { // Only Float _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0xD1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VACLE(ARMReg Vd, ARMReg Vn, ARMReg Vm) { VACGE(Vd, Vm, Vn); } void ARMXEmitter::VACLT(ARMReg Vd, ARMReg Vn, ARMReg Vm) { VACGT(Vd, Vn, Vm); } void ARMXEmitter::VADD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD << 8) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0x8 << 8) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VADDHN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) \ | EncodeVd(Vd) | (0x80 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VADDL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= D0 && Vn < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) \ | EncodeVd(Vd) | EncodeVm(Vm)); } void ARMXEmitter::VADDW(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) \ | EncodeVd(Vd) | (1 << 8) | EncodeVm(Vm)); } void ARMXEmitter::VAND(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Vd == Vn && Vn == Vm), "All operands the same for %s is a nop", __FUNCTION__); // _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VBIC(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (1 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VEOR(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s: %i", __FUNCTION__, Vd); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VBIF(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (3 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VBIT(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (2 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VBSL(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (1 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCEQ(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xE0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF3 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0x81 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCEQ(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 16) \ | EncodeVd(Vd) | ((Size & F_32 ? 1 : 0) << 10) | (0x10 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCGE(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xE0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0x31 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCGE(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 16) \ | EncodeVd(Vd) | ((Size & F_32 ? 1 : 0) << 10) | (0x8 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCGT(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF3 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | (0xE0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) \ | (0x30 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCGT(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) | (1 << 16) \ | EncodeVd(Vd) | ((Size & F_32 ? 1 : 0) << 10) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCLE(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { VCGE(Size, Vd, Vm, Vn); } void ARMXEmitter::VCLE(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) | (1 << 16) \ | EncodeVd(Vd) | ((Size & F_32 ? 1 : 0) << 10) | (3 << 7) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCLS(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) \ | EncodeVd(Vd) | (1 << 10) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCLT(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { VCGT(Size, Vd, Vm, Vn); } void ARMXEmitter::VCLT(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) | (1 << 16) \ | EncodeVd(Vd) | ((Size & F_32 ? 1 : 0) << 10) | (0x20 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCLZ(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) \ | EncodeVd(Vd) | (0x48 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VCNT(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, Size & I_8, "Can only use I_8 with %s", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xD << 20) | (encodedSize(Size) << 18) \ | EncodeVd(Vd) | (0x90 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VDUP(u32 Size, ARMReg Vd, ARMReg Vm, u8 index) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; u32 imm4 = 0; if (Size & I_8) imm4 = (index << 1) | 1; else if (Size & I_16) imm4 = (index << 2) | 2; else if (Size & (I_32 | F_32)) imm4 = (index << 3) | 4; Write32((0xF3 << 24) | (0xB << 20) | (imm4 << 16) \ | EncodeVd(Vd) | (0xC << 8) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VDUP(u32 Size, ARMReg Vd, ARMReg Rt) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Rt < S0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Vd = SubBase(Vd); u8 sizeEncoded = 0; if (Size & I_8) sizeEncoded = 2; else if (Size & I_16) sizeEncoded = 1; else if (Size & I_32) sizeEncoded = 0; Write32((0xEE << 24) | (0x8 << 20) | ((sizeEncoded & 2) << 21) | (register_quad << 21) \ | ((Vd & 0xF) << 16) | (Rt << 12) | (0xB1 << 4) | ((Vd & 0x10) << 3) | ((sizeEncoded & 1) << 5)); } void ARMXEmitter::VEXT(ARMReg Vd, ARMReg Vn, ARMReg Vm, u8 index) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (0xB << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (index & 0xF) \ | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VFMA(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Size == F_32, "Passed invalid size to FP-only NEON instruction"); _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bVFPv4, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xC1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VFMS(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Size == F_32, "Passed invalid size to FP-only NEON instruction"); _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bVFPv4, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | (0xC1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VHADD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (((Size & I_UNSIGNED) ? 1 : 0) << 23) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VHSUB(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (((Size & I_UNSIGNED) ? 1 : 0) << 23) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (1 << 9) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMAX(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xF0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (((Size & I_UNSIGNED) ? 1 : 0) << 23) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (0x60 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMIN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | (2 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0xF0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (((Size & I_UNSIGNED) ? 1 : 0) << 23) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (0x61 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMLA(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD1 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x90 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMLS(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD1 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (1 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x90 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMLAL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (0x80 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VMLSL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vn >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm < Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float.", __FUNCTION__); Write32((0xF2 << 24) | ((Size & I_UNSIGNED ? 1 : 0) << 24) | (encodedSize(Size) << 20) \ | EncodeVn(Vn) | EncodeVd(Vd) | (0xA0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VMUL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD1 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF2 << 24) | ((Size & I_POLYNOMIAL) ? (1 << 24) : 0) | (encodedSize(Size) << 20) | \ EncodeVn(Vn) | EncodeVd(Vd) | (0x91 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMULL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xC0 << 4) | ((Size & I_POLYNOMIAL) ? 1 << 9 : 0) | EncodeVm(Vm)); } void ARMXEmitter::VMLA_scalar(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; // No idea if the Non-Q case here works. Not really that interested. if (Size & F_32) Write32((0xF2 << 24) | (register_quad << 24) | (1 << 23) | (2 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x14 << 4) | EncodeVm(Vm)); else _dbg_assert_msg_(JIT, false, "VMLA_scalar only supports float atm"); //else // Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x90 << 4) | (1 << 6) | EncodeVm(Vm)); // Unsigned support missing } void ARMXEmitter::VMUL_scalar(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; int VmEnc = EncodeVm(Vm); // No idea if the Non-Q case here works. Not really that interested. if (Size & F_32) // Q flag Write32((0xF2 << 24) | (register_quad << 24) | (1 << 23) | (2 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x94 << 4) | VmEnc); else _dbg_assert_msg_(JIT, false, "VMUL_scalar only supports float atm"); // Write32((0xF2 << 24) | ((Size & I_POLYNOMIAL) ? (1 << 24) : 0) | (1 << 23) | (encodedSize(Size) << 20) | // EncodeVn(Vn) | EncodeVd(Vd) | (0x84 << 4) | (register_quad << 6) | EncodeVm(Vm)); // Unsigned support missing } void ARMXEmitter::VMVN(ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3B << 20) | \ EncodeVd(Vd) | (0xB << 7) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VNEG(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 16) | \ EncodeVd(Vd) | ((Size & F_32) ? 1 << 10 : 0) | (0xE << 6) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VORN(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (3 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VORR(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Vd == Vn && Vn == Vm), "All operands the same for %s is a nop", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (2 << 20) | EncodeVn(Vn) | EncodeVd(Vd) | (0x11 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VPADAL(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | EncodeVd(Vd) | \ (0x60 << 4) | ((Size & I_UNSIGNED) ? 1 << 7 : 0) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VPADD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); if (Size & F_32) Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xD0 << 4) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xB1 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VPADDL(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | EncodeVd(Vd) | \ (0x20 << 4) | (Size & I_UNSIGNED ? 1 << 7 : 0) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VPMAX(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); if (Size & F_32) Write32((0xF3 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xF0 << 4) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xA0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VPMIN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); if (Size & F_32) Write32((0xF3 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | (0xF0 << 4) | EncodeVm(Vm)); else Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xA1 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQABS(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | EncodeVd(Vd) | \ (0x70 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VQADD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VQDMLAL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x90 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQDMLSL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xB0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQDMULH(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xB0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQDMULL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xD0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQNEG(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | EncodeVd(Vd) | \ (0x78 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VQRDMULH(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF3 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xB0 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VQRSHL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x51 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VQSHL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x41 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VQSUB(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x21 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRADDHN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF3 << 24) | (1 << 23) | ((encodedSize(Size) - 1) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x40 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VRECPE(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (0xB << 16) | EncodeVd(Vd) | \ (0x40 << 4) | (Size & F_32 ? 1 << 8 : 0) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRECPS(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | EncodeVn(Vn) | EncodeVd(Vd) | (0xF1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRHADD(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x10 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRSHL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x50 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRSQRTE(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Vd = SubBase(Vd); Vm = SubBase(Vm); Write32((0xF3 << 24) | (0xB << 20) | ((Vd & 0x10) << 18) | (0xB << 16) | ((Vd & 0xF) << 12) | (9 << 7) | (Size & F_32 ? (1 << 8) : 0) | (register_quad << 6) | ((Vm & 0x10) << 1) | (Vm & 0xF)); } void ARMXEmitter::VRSQRTS(ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xF1 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VRSUBHN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); Write32((0xF3 << 24) | (1 << 23) | ((encodedSize(Size) - 1) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x60 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VSHL(u32 Size, ARMReg Vd, ARMReg Vm, ARMReg Vn) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x40 << 4) | (register_quad << 6) | EncodeVm(Vm)); } static int EncodeSizeShift(u32 Size, int amount, bool inverse, bool halve) { int sz = 0; switch (Size & 0xF) { case I_8: sz = 8; break; case I_16: sz = 16; break; case I_32: sz = 32; break; case I_64: sz = 64; break; } if (inverse && halve) { _dbg_assert_msg_(JIT, amount <= sz / 2, "Amount %d too large for narrowing shift (max %d)", amount, sz/2); return (sz / 2) + (sz / 2) - amount; } else if (inverse) { return sz + (sz - amount); } else { return sz + amount; } } void ARMXEmitter::EncodeShiftByImm(u32 Size, ARMReg Vd, ARMReg Vm, int shiftAmount, u8 opcode, bool register_quad, bool inverse, bool halve) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, !(Size & F_32), "%s doesn't support float", __FUNCTION__); int imm7 = EncodeSizeShift(Size, shiftAmount, inverse, halve); int L = (imm7 >> 6) & 1; int U = (Size & I_UNSIGNED) ? 1 : 0; u32 value = (0xF2 << 24) | (U << 24) | (1 << 23) | ((imm7 & 0x3f) << 16) | EncodeVd(Vd) | (opcode << 8) | (L << 7) | (register_quad << 6) | (1 << 4) | EncodeVm(Vm); Write32(value); } void ARMXEmitter::VSHL(u32 Size, ARMReg Vd, ARMReg Vm, int shiftAmount) { EncodeShiftByImm((Size & ~I_UNSIGNED), Vd, Vm, shiftAmount, 0x5, Vd >= Q0, false, false); } void ARMXEmitter::VSHLL(u32 Size, ARMReg Vd, ARMReg Vm, int shiftAmount) { if ((u32)shiftAmount == (8 * (Size & 0xF))) { // Entirely different encoding (A2) for size == shift! Bleh. int sz = 0; switch (Size & 0xF) { case I_8: sz = 0; break; case I_16: sz = 1; break; case I_32: sz = 2; break; case I_64: _dbg_assert_msg_(JIT, false, "Cannot VSHLL 64-bit elements"); } int imm6 = 0x32 | (sz << 2); u32 value = (0xF3 << 24) | (1 << 23) | (imm6 << 16) | EncodeVd(Vd) | (0x3 << 8) | EncodeVm(Vm); Write32(value); } else { EncodeShiftByImm((Size & ~I_UNSIGNED), Vd, Vm, shiftAmount, 0xA, false, false, false); } } void ARMXEmitter::VSHR(u32 Size, ARMReg Vd, ARMReg Vm, int shiftAmount) { EncodeShiftByImm(Size, Vd, Vm, shiftAmount, 0x0, Vd >= Q0, true, false); } void ARMXEmitter::VSHRN(u32 Size, ARMReg Vd, ARMReg Vm, int shiftAmount) { // Reduce Size by 1 to encode correctly. EncodeShiftByImm(Size, Vd, Vm, shiftAmount, 0x8, false, true, true); } void ARMXEmitter::VSUB(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; if (Size & F_32) Write32((0xF2 << 24) | (1 << 21) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0xD0 << 4) | (register_quad << 6) | EncodeVm(Vm)); else Write32((0xF3 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x80 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VSUBHN(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); Write32((0xF2 << 24) | (1 << 23) | ((encodedSize(Size) - 1) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x60 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VSUBL(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x20 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VSUBW(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); Write32((0xF2 << 24) | (Size & I_UNSIGNED ? 1 << 24 : 0) | (1 << 23) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x30 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VSWP(ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (1 << 17) | EncodeVd(Vd) | \ (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VTRN(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 17) | EncodeVd(Vd) | \ (1 << 7) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VTST(u32 Size, ARMReg Vd, ARMReg Vn, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF2 << 24) | (encodedSize(Size) << 20) | EncodeVn(Vn) | EncodeVd(Vd) | \ (0x81 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VUZP(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 17) | EncodeVd(Vd) | \ (0x10 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VZIP(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= D0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); bool register_quad = Vd >= Q0; Write32((0xF3 << 24) | (0xB << 20) | (encodedSize(Size) << 18) | (1 << 17) | EncodeVd(Vd) | \ (0x18 << 4) | (register_quad << 6) | EncodeVm(Vm)); } void ARMXEmitter::VMOVL(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vd >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vm >= D0 && Vm <= D31, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, (Size & (I_UNSIGNED | I_SIGNED)) != 0, "Must specify I_SIGNED or I_UNSIGNED in VMOVL"); bool unsign = (Size & I_UNSIGNED) != 0; int imm3 = 0; if (Size & I_8) imm3 = 1; if (Size & I_16) imm3 = 2; if (Size & I_32) imm3 = 4; Write32((0xF2 << 24) | (unsign << 24) | (1 << 23) | (imm3 << 19) | EncodeVd(Vd) | \ (0xA1 << 4) | EncodeVm(Vm)); } void ARMXEmitter::VMOVN(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vm >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vd >= D0 && Vd <= D31, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, (Size & I_8) == 0, "%s cannot narrow from I_8", __FUNCTION__); // For consistency with assembler syntax and VMOVL - encode one size down. int halfSize = encodedSize(Size) - 1; Write32((0xF3B << 20) | (halfSize << 18) | (1 << 17) | EncodeVd(Vd) | (1 << 9) | EncodeVm(Vm)); } void ARMXEmitter::VQMOVN(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vm >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vd >= D0 && Vd <= D31, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, (Size & (I_UNSIGNED | I_SIGNED)) != 0, "Must specify I_SIGNED or I_UNSIGNED in %s NEON", __FUNCTION__); _dbg_assert_msg_(JIT, (Size & I_8) == 0, "%s cannot narrow from I_8", __FUNCTION__); int halfSize = encodedSize(Size) - 1; int op = (1 << 7) | (Size & I_UNSIGNED ? 1 << 6 : 0); Write32((0xF3B << 20) | (halfSize << 18) | (1 << 17) | EncodeVd(Vd) | (1 << 9) | op | EncodeVm(Vm)); } void ARMXEmitter::VQMOVUN(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, Vm >= Q0, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, Vd >= D0 && Vd <= D31, "Pass invalid register to %s", __FUNCTION__); _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); _dbg_assert_msg_(JIT, (Size & I_8) == 0, "%s cannot narrow from I_8", __FUNCTION__); int halfSize = encodedSize(Size) - 1; int op = (1 << 6); Write32((0xF3B << 20) | (halfSize << 18) | (1 << 17) | EncodeVd(Vd) | (1 << 9) | op | EncodeVm(Vm)); } void ARMXEmitter::VCVT(u32 Size, ARMReg Vd, ARMReg Vm) { _dbg_assert_msg_(JIT, (Size & (I_UNSIGNED | I_SIGNED)) != 0, "Must specify I_SIGNED or I_UNSIGNED in VCVT NEON"); bool register_quad = Vd >= Q0; bool toInteger = (Size & I_32) != 0; bool isUnsigned = (Size & I_UNSIGNED) != 0; int op = (toInteger << 1) | (int)isUnsigned; Write32((0xF3 << 24) | (0xBB << 16) | EncodeVd(Vd) | (0x3 << 9) | (op << 7) | (register_quad << 6) | EncodeVm(Vm)); } static int RegCountToType(int nRegs, NEONAlignment align) { switch (nRegs) { case 1: _dbg_assert_msg_(JIT, !((int)align & 1), "align & 1 must be == 0"); return 7; case 2: _dbg_assert_msg_(JIT, !((int)align == 3), "align must be != 3"); return 10; case 3: _dbg_assert_msg_(JIT, !((int)align & 1), "align & 1 must be == 0"); return 6; case 4: return 2; default: _dbg_assert_msg_(JIT, false, "Invalid number of registers passed to vector load/store"); return 0; } } void ARMXEmitter::WriteVLDST1(bool load, u32 Size, ARMReg Vd, ARMReg Rn, int regCount, NEONAlignment align, ARMReg Rm) { u32 spacing = RegCountToType(regCount, align); // Only support loading to 1 reg // Gets encoded as a double register Vd = SubBase(Vd); Write32((0xF4 << 24) | ((Vd & 0x10) << 18) | (load << 21) | (Rn << 16) | ((Vd & 0xF) << 12) | (spacing << 8) | (encodedSize(Size) << 6) | (align << 4) | Rm); } void ARMXEmitter::VLD1(u32 Size, ARMReg Vd, ARMReg Rn, int regCount, NEONAlignment align, ARMReg Rm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); WriteVLDST1(true, Size, Vd, Rn, regCount, align, Rm); } void ARMXEmitter::VST1(u32 Size, ARMReg Vd, ARMReg Rn, int regCount, NEONAlignment align, ARMReg Rm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); WriteVLDST1(false, Size, Vd, Rn, regCount, align, Rm); } void ARMXEmitter::WriteVLDST1_lane(bool load, u32 Size, ARMReg Vd, ARMReg Rn, int lane, bool aligned, ARMReg Rm) { bool register_quad = Vd >= Q0; Vd = SubBase(Vd); // Support quad lanes by converting to D lanes if (register_quad && lane > 1) { Vd = (ARMReg)((int)Vd + 1); lane -= 2; } int encSize = encodedSize(Size); int index_align = 0; switch (encSize) { case 0: index_align = lane << 1; break; case 1: index_align = lane << 2; if (aligned) index_align |= 1; break; case 2: index_align = lane << 3; if (aligned) index_align |= 3; break; default: break; } Write32((0xF4 << 24) | (1 << 23) | ((Vd & 0x10) << 18) | (load << 21) | (Rn << 16) | ((Vd & 0xF) << 12) | (encSize << 10) | (index_align << 4) | Rm); } void ARMXEmitter::VLD1_lane(u32 Size, ARMReg Vd, ARMReg Rn, int lane, bool aligned, ARMReg Rm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); WriteVLDST1_lane(true, Size, Vd, Rn, lane, aligned, Rm); } void ARMXEmitter::VST1_lane(u32 Size, ARMReg Vd, ARMReg Rn, int lane, bool aligned, ARMReg Rm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); WriteVLDST1_lane(false, Size, Vd, Rn, lane, aligned, Rm); } void ARMXEmitter::VLD1_all_lanes(u32 Size, ARMReg Vd, ARMReg Rn, bool aligned, ARMReg Rm) { bool register_quad = Vd >= Q0; Vd = SubBase(Vd); int T = register_quad; // two D registers Write32((0xF4 << 24) | (1 << 23) | ((Vd & 0x10) << 18) | (1 << 21) | (Rn << 16) | ((Vd & 0xF) << 12) | (0xC << 8) | (encodedSize(Size) << 6) | (T << 5) | (aligned << 4) | Rm); } /* void ARMXEmitter::VLD2(u32 Size, ARMReg Vd, ARMReg Rn, int regCount, NEONAlignment align, ARMReg Rm) { u32 spacing = 0x8; // Single spaced registers // Gets encoded as a double register Vd = SubBase(Vd); Write32((0xF4 << 24) | ((Vd & 0x10) << 18) | (1 << 21) | (Rn << 16) | ((Vd & 0xF) << 12) | (spacing << 8) | (encodedSize(Size) << 6) | (align << 4) | Rm); } */ void ARMXEmitter::WriteVimm(ARMReg Vd, int cmode, u8 imm, int op) { bool register_quad = Vd >= Q0; Write32((0xF28 << 20) | ((imm >> 7) << 24) | (((imm >> 4) & 0x7) << 16) | (imm & 0xF) | EncodeVd(Vd) | (register_quad << 6) | (op << 5) | (1 << 4) | ((cmode & 0xF) << 8)); } void ARMXEmitter::VMOV_imm(u32 Size, ARMReg Vd, VIMMMode type, int imm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // Only let through the modes that apply. switch (type) { case VIMM___x___x: case VIMM__x___x_: case VIMM_x___x__: case VIMMx___x___: if (Size != I_32) goto error; WriteVimm(Vd, (int)type, imm, 0); break; case VIMM_x_x_x_x: case VIMMx_x_x_x_: if (Size != I_16) goto error; WriteVimm(Vd, (int)type, imm, 0); break; case VIMMxxxxxxxx: // replicate the byte if (Size != I_8) goto error; WriteVimm(Vd, (int)type, imm, 0); break; case VIMMbits2bytes: if (Size != I_64) goto error; WriteVimm(Vd, (int)type, imm, 1); break; default: goto error; } return; error: _dbg_assert_msg_(JIT, false, "Bad Size or type specified in %s: Size %i Type %i", __FUNCTION__, Size, type); } void ARMXEmitter::VMOV_immf(ARMReg Vd, float value) { // This only works with a select few values. I've hardcoded 1.0f. _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); u8 bits = 0; if (value == 0.0f) { VEOR(Vd, Vd, Vd); return; } // TODO: Do something more sophisticated here. if (value == 1.5f) { bits = 0x78; } else if (value == 1.0f) { bits = 0x70; } else if (value == -1.0f) { bits = 0xF0; } else { _dbg_assert_msg_(JIT, false, "%s: Invalid floating point immediate", __FUNCTION__); } WriteVimm(Vd, VIMMf000f000, bits, 0); } void ARMXEmitter::VORR_imm(u32 Size, ARMReg Vd, VIMMMode type, int imm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // Only let through the modes that apply. switch (type) { case VIMM___x___x: case VIMM__x___x_: case VIMM_x___x__: case VIMMx___x___: if (Size != I_32) goto error; WriteVimm(Vd, (int)type | 1, imm, 0); break; case VIMM_x_x_x_x: case VIMMx_x_x_x_: if (Size != I_16) goto error; WriteVimm(Vd, (int)type | 1, imm, 0); break; default: goto error; } return; error: _dbg_assert_msg_(JIT, false, "Bad Size or type specified in VORR_imm"); } void ARMXEmitter::VBIC_imm(u32 Size, ARMReg Vd, VIMMMode type, int imm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // Only let through the modes that apply. switch (type) { case VIMM___x___x: case VIMM__x___x_: case VIMM_x___x__: case VIMMx___x___: if (Size != I_32) goto error; WriteVimm(Vd, (int)type | 1, imm, 1); break; case VIMM_x_x_x_x: case VIMMx_x_x_x_: if (Size != I_16) goto error; WriteVimm(Vd, (int)type | 1, imm, 1); break; default: goto error; } return; error: _dbg_assert_msg_(JIT, false, "Bad Size or type specified in VBIC_imm"); } void ARMXEmitter::VMVN_imm(u32 Size, ARMReg Vd, VIMMMode type, int imm) { _dbg_assert_msg_(JIT, cpu_info.bNEON, "Can't use %s when CPU doesn't support it", __FUNCTION__); // Only let through the modes that apply. switch (type) { case VIMM___x___x: case VIMM__x___x_: case VIMM_x___x__: case VIMMx___x___: if (Size != I_32) goto error; WriteVimm(Vd, (int)type, imm, 1); break; case VIMM_x_x_x_x: case VIMMx_x_x_x_: if (Size != I_16) goto error; WriteVimm(Vd, (int)type, imm, 1); break; default: goto error; } return; error: _dbg_assert_msg_(JIT, false, "Bad Size or type specified in VMVN_imm"); } void ARMXEmitter::VREVX(u32 size, u32 Size, ARMReg Vd, ARMReg Vm) { bool register_quad = Vd >= Q0; Vd = SubBase(Vd); Vm = SubBase(Vm); Write32((0xF3 << 24) | (1 << 23) | ((Vd & 0x10) << 18) | (0x3 << 20) | (encodedSize(Size) << 18) | ((Vd & 0xF) << 12) | (size << 7) | (register_quad << 6) | ((Vm & 0x10) << 1) | (Vm & 0xF)); } void ARMXEmitter::VREV64(u32 Size, ARMReg Vd, ARMReg Vm) { VREVX(0, Size, Vd, Vm); } void ARMXEmitter::VREV32(u32 Size, ARMReg Vd, ARMReg Vm) { VREVX(1, Size, Vd, Vm); } void ARMXEmitter::VREV16(u32 Size, ARMReg Vd, ARMReg Vm) { VREVX(2, Size, Vd, Vm); } // See page A8-878 in ARMv7-A Architecture Reference Manual // Dest is a Q register, Src is a D register. void ARMXEmitter::VCVTF32F16(ARMReg Dest, ARMReg Src) { _assert_msg_(JIT, cpu_info.bVFPv4, "Can't use half-float conversions when you don't support VFPv4"); if (Dest < Q0 || Dest > Q15 || Src < D0 || Src > D15) { _assert_msg_(JIT, cpu_info.bNEON, "Bad inputs to VCVTF32F16"); // Invalid! } Dest = SubBase(Dest); Src = SubBase(Src); int op = 1; Write32((0xF3B6 << 16) | ((Dest & 0x10) << 18) | ((Dest & 0xF) << 12) | 0x600 | (op << 8) | ((Src & 0x10) << 1) | (Src & 0xF)); } // UNTESTED // Dest is a D register, Src is a Q register. void ARMXEmitter::VCVTF16F32(ARMReg Dest, ARMReg Src) { _assert_msg_(JIT, cpu_info.bVFPv4, "Can't use half-float conversions when you don't support VFPv4"); if (Dest < D0 || Dest > D15 || Src < Q0 || Src > Q15) { _assert_msg_(JIT, cpu_info.bNEON, "Bad inputs to VCVTF32F16"); // Invalid! } Dest = SubBase(Dest); Src = SubBase(Src); int op = 0; Write32((0xF3B6 << 16) | ((Dest & 0x10) << 18) | ((Dest & 0xF) << 12) | 0x600 | (op << 8) | ((Src & 0x10) << 1) | (Src & 0xF)); } // Always clear code space with breakpoints, so that if someone accidentally executes // uninitialized, it just breaks into the debugger. void ARMXCodeBlock::PoisonMemory() { // TODO: this isn't right for ARM! memset(region, 0xCC, region_size); ResetCodePtr(); } }