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//===- subzero/src/IceAssemblerARM32.cpp - Assembler for ARM32 --*- C++ -*-===//
//
// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
//
// Modified by the Subzero authors.
//
//===----------------------------------------------------------------------===//
//
// The Subzero Code Generator
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
///
/// \file
/// \brief Implements the Assembler class for ARM32.
///
//===----------------------------------------------------------------------===//
#include "IceAssemblerARM32.h"
#include "IceCfgNode.h"
#include "IceUtils.h"
namespace {
using namespace Ice;
using namespace Ice::ARM32;
using WordType = uint32_t;
static constexpr IValueT kWordSize = sizeof(WordType);
// The following define individual bits.
static constexpr IValueT B0 = 1;
static constexpr IValueT B1 = 1 << 1;
static constexpr IValueT B2 = 1 << 2;
static constexpr IValueT B3 = 1 << 3;
static constexpr IValueT B4 = 1 << 4;
static constexpr IValueT B5 = 1 << 5;
static constexpr IValueT B6 = 1 << 6;
static constexpr IValueT B7 = 1 << 7;
static constexpr IValueT B8 = 1 << 8;
static constexpr IValueT B9 = 1 << 9;
static constexpr IValueT B10 = 1 << 10;
static constexpr IValueT B11 = 1 << 11;
static constexpr IValueT B12 = 1 << 12;
static constexpr IValueT B13 = 1 << 13;
static constexpr IValueT B14 = 1 << 14;
static constexpr IValueT B15 = 1 << 15;
static constexpr IValueT B16 = 1 << 16;
static constexpr IValueT B17 = 1 << 17;
static constexpr IValueT B18 = 1 << 18;
static constexpr IValueT B19 = 1 << 19;
static constexpr IValueT B20 = 1 << 20;
static constexpr IValueT B21 = 1 << 21;
static constexpr IValueT B22 = 1 << 22;
static constexpr IValueT B23 = 1 << 23;
static constexpr IValueT B24 = 1 << 24;
static constexpr IValueT B25 = 1 << 25;
static constexpr IValueT B26 = 1 << 26;
static constexpr IValueT B27 = 1 << 27;
// Constants used for the decoding or encoding of the individual fields of
// instructions. Based on ARM section A5.1.
static constexpr IValueT L = 1 << 20; // load (or store)
static constexpr IValueT W = 1 << 21; // writeback base register
// (or leave unchanged)
static constexpr IValueT B = 1 << 22; // unsigned byte (or word)
static constexpr IValueT U = 1 << 23; // positive (or negative)
// offset/index
static constexpr IValueT P = 1 << 24; // offset/pre-indexed
// addressing (or
// post-indexed addressing)
static constexpr IValueT kConditionShift = 28;
static constexpr IValueT kLinkShift = 24;
static constexpr IValueT kOpcodeShift = 21;
static constexpr IValueT kRdShift = 12;
static constexpr IValueT kRmShift = 0;
static constexpr IValueT kRnShift = 16;
static constexpr IValueT kRsShift = 8;
static constexpr IValueT kSShift = 20;
static constexpr IValueT kTypeShift = 25;
// Immediate instruction fields encoding.
static constexpr IValueT kImmed8Bits = 8;
static constexpr IValueT kImmed8Shift = 0;
static constexpr IValueT kRotateBits = 4;
static constexpr IValueT kRotateShift = 8;
// Shift instruction register fields encodings.
static constexpr IValueT kShiftImmShift = 7;
static constexpr IValueT kShiftImmBits = 5;
static constexpr IValueT kShiftShift = 5;
static constexpr IValueT kImmed12Bits = 12;
static constexpr IValueT kImm12Shift = 0;
// Rotation instructions (uxtb etc.).
static constexpr IValueT kRotationShift = 10;
// MemEx instructions.
static constexpr IValueT kMemExOpcodeShift = 20;
// Div instruction register field encodings.
static constexpr IValueT kDivRdShift = 16;
static constexpr IValueT kDivRmShift = 8;
static constexpr IValueT kDivRnShift = 0;
// Type of instruction encoding (bits 25-27). See ARM section A5.1
static constexpr IValueT kInstTypeDataRegister = 0; // i.e. 000
static constexpr IValueT kInstTypeDataRegShift = 0; // i.e. 000
static constexpr IValueT kInstTypeDataImmediate = 1; // i.e. 001
static constexpr IValueT kInstTypeMemImmediate = 2; // i.e. 010
static constexpr IValueT kInstTypeRegisterShift = 3; // i.e. 011
// Limit on number of registers in a vpush/vpop.
static constexpr SizeT VpushVpopMaxConsecRegs = 16;
// Offset modifier to current PC for next instruction. The offset is off by 8
// due to the way the ARM CPUs read PC.
static constexpr IOffsetT kPCReadOffset = 8;
// Mask to pull out PC offset from branch (b) instruction.
static constexpr int kBranchOffsetBits = 24;
static constexpr IOffsetT kBranchOffsetMask = 0x00ffffff;
IValueT encodeBool(bool B) { return B ? 1 : 0; }
IValueT encodeRotation(ARM32::AssemblerARM32::RotationValue Value) {
return static_cast<IValueT>(Value);
}
IValueT encodeGPRRegister(RegARM32::GPRRegister Rn) {
return static_cast<IValueT>(Rn);
}
RegARM32::GPRRegister decodeGPRRegister(IValueT R) {
return static_cast<RegARM32::GPRRegister>(R);
}
IValueT encodeCondition(CondARM32::Cond Cond) {
return static_cast<IValueT>(Cond);
}
IValueT encodeShift(OperandARM32::ShiftKind Shift) {
// Follows encoding in ARM section A8.4.1 "Constant shifts".
switch (Shift) {
case OperandARM32::kNoShift:
case OperandARM32::LSL:
return 0; // 0b00
case OperandARM32::LSR:
return 1; // 0b01
case OperandARM32::ASR:
return 2; // 0b10
case OperandARM32::ROR:
case OperandARM32::RRX:
return 3; // 0b11
}
llvm::report_fatal_error("Unknown Shift value");
return 0;
}
// Returns the bits in the corresponding masked value.
IValueT mask(IValueT Value, IValueT Shift, IValueT Bits) {
return (Value >> Shift) & ((1 << Bits) - 1);
}
// Extract out a Bit in Value.
bool isBitSet(IValueT Bit, IValueT Value) { return (Value & Bit) == Bit; }
// Returns the GPR register at given Shift in Value.
RegARM32::GPRRegister getGPRReg(IValueT Shift, IValueT Value) {
return decodeGPRRegister((Value >> Shift) & 0xF);
}
IValueT getEncodedGPRegNum(const Variable *Var) {
assert(Var->hasReg());
const auto Reg = Var->getRegNum();
return llvm::isa<Variable64On32>(Var) ? RegARM32::getI64PairFirstGPRNum(Reg)
: RegARM32::getEncodedGPR(Reg);
}
IValueT getEncodedSRegNum(const Variable *Var) {
assert(Var->hasReg());
return RegARM32::getEncodedSReg(Var->getRegNum());
}
IValueT getEncodedDRegNum(const Variable *Var) {
return RegARM32::getEncodedDReg(Var->getRegNum());
}
IValueT getEncodedQRegNum(const Variable *Var) {
return RegARM32::getEncodedQReg(Var->getRegNum());
}
IValueT mapQRegToDReg(IValueT EncodedQReg) {
IValueT DReg = EncodedQReg << 1;
assert(DReg < RegARM32::getNumDRegs());
return DReg;
}
IValueT mapQRegToSReg(IValueT EncodedQReg) {
IValueT SReg = EncodedQReg << 2;
assert(SReg < RegARM32::getNumSRegs());
return SReg;
}
IValueT getYInRegXXXXY(IValueT RegXXXXY) { return RegXXXXY & 0x1; }
IValueT getXXXXInRegXXXXY(IValueT RegXXXXY) { return RegXXXXY >> 1; }
IValueT getYInRegYXXXX(IValueT RegYXXXX) { return RegYXXXX >> 4; }
IValueT getXXXXInRegYXXXX(IValueT RegYXXXX) { return RegYXXXX & 0x0f; }
// Figures out Op/Cmode values for given Value. Returns true if able to encode.
bool encodeAdvSIMDExpandImm(IValueT Value, Type ElmtTy, IValueT &Op,
IValueT &Cmode, IValueT &Imm8) {
// TODO(kschimpf): Handle other shifted 8-bit values.
constexpr IValueT Imm8Mask = 0xFF;
if ((Value & IValueT(~Imm8Mask)) != 0)
return false;
Imm8 = Value;
switch (ElmtTy) {
case IceType_i8:
Op = 0;
Cmode = 14; // 0b1110
return true;
case IceType_i16:
Op = 0;
Cmode = 8; // 0b1000
return true;
case IceType_i32:
Op = 0;
Cmode = 0; // 0b0000
return true;
default:
return false;
}
}
// Defines layouts of an operand representing a (register) memory address,
// possibly modified by an immediate value.
enum EncodedImmAddress {
// Address modified by a rotated immediate 8-bit value.
RotatedImm8Address,
// Alternate encoding for RotatedImm8Address, where the offset is divided by 4
// before encoding.
RotatedImm8Div4Address,
// Address modified by an immediate 12-bit value.
Imm12Address,
// Alternate encoding 3, for an address modified by a rotated immediate 8-bit
// value.
RotatedImm8Enc3Address,
// Encoding where no immediate offset is used.
NoImmOffsetAddress
};
// The way an operand is encoded into a sequence of bits in functions
// encodeOperand and encodeAddress below.
enum EncodedOperand {
// Unable to encode, value left undefined.
CantEncode = 0,
// Value is register found.
EncodedAsRegister,
// Value=rrrriiiiiiii where rrrr is the rotation, and iiiiiiii is the imm8
// value.
EncodedAsRotatedImm8,
// EncodedAsImmRegOffset is a memory operand that can take three forms, based
// on type EncodedImmAddress:
//
// ***** RotatedImm8Address *****
//
// Value=0000000pu0w0nnnn0000iiiiiiiiiiii where nnnn is the base register Rn,
// p=1 if pre-indexed addressing, u=1 if offset positive, w=1 if writeback to
// Rn should be used, and iiiiiiiiiiii defines the rotated Imm8 value.
//
// ***** RotatedImm8Div4Address *****
//
// Value=00000000pu0w0nnnn0000iiii0000jjjj where nnnn=Rn, iiiijjjj=Imm8, p=1
// if pre-indexed addressing, u=1 if offset positive, and w=1 if writeback to
// Rn.
//
// ***** Imm12Address *****
//
// Value=0000000pu0w0nnnn0000iiiiiiiiiiii where nnnn is the base register Rn,
// p=1 if pre-indexed addressing, u=1 if offset positive, w=1 if writeback to
// Rn should be used, and iiiiiiiiiiii defines the immediate 12-bit value.
//
// ***** NoImmOffsetAddress *****
//
// Value=000000001000nnnn0000000000000000 where nnnn=Rn.
EncodedAsImmRegOffset,
// Value=0000000pu0w00nnnnttttiiiiiss0mmmm where nnnn is the base register Rn,
// mmmm is the index register Rm, iiiii is the shift amount, ss is the shift
// kind, p=1 if pre-indexed addressing, u=1 if offset positive, and w=1 if
// writeback to Rn.
EncodedAsShiftRotateImm5,
// Value=000000000000000000000iiiii0000000 where iiii defines the Imm5 value
// to shift.
EncodedAsShiftImm5,
// Value=iiiiiss0mmmm where mmmm is the register to rotate, ss is the shift
// kind, and iiiii is the shift amount.
EncodedAsShiftedRegister,
// Value=ssss0tt1mmmm where mmmm=Rm, tt is an encoded ShiftKind, and ssss=Rms.
EncodedAsRegShiftReg,
// Value is 32bit integer constant.
EncodedAsConstI32
};
// Sets Encoding to a rotated Imm8 encoding of Value, if possible.
IValueT encodeRotatedImm8(IValueT RotateAmt, IValueT Immed8) {
assert(RotateAmt < (1 << kRotateBits));
assert(Immed8 < (1 << kImmed8Bits));
return (RotateAmt << kRotateShift) | (Immed8 << kImmed8Shift);
}
// Encodes iiiiitt0mmmm for data-processing (2nd) operands where iiiii=Imm5,
// tt=Shift, and mmmm=Rm.
IValueT encodeShiftRotateImm5(IValueT Rm, OperandARM32::ShiftKind Shift,
IOffsetT imm5) {
(void)kShiftImmBits;
assert(imm5 < (1 << kShiftImmBits));
return (imm5 << kShiftImmShift) | (encodeShift(Shift) << kShiftShift) | Rm;
}
// Encodes mmmmtt01ssss for data-processing operands where mmmm=Rm, ssss=Rs, and
// tt=Shift.
IValueT encodeShiftRotateReg(IValueT Rm, OperandARM32::ShiftKind Shift,
IValueT Rs) {
return (Rs << kRsShift) | (encodeShift(Shift) << kShiftShift) | B4 |
(Rm << kRmShift);
}
// Defines the set of registers expected in an operand.
enum RegSetWanted { WantGPRegs, WantSRegs, WantDRegs, WantQRegs };
EncodedOperand encodeOperand(const Operand *Opnd, IValueT &Value,
RegSetWanted WantedRegSet) {
Value = 0; // Make sure initialized.
if (const auto *Var = llvm::dyn_cast<Variable>(Opnd)) {
if (Var->hasReg()) {
switch (WantedRegSet) {
case WantGPRegs:
Value = getEncodedGPRegNum(Var);
break;
case WantSRegs:
Value = getEncodedSRegNum(Var);
break;
case WantDRegs:
Value = getEncodedDRegNum(Var);
break;
case WantQRegs:
Value = getEncodedQRegNum(Var);
break;
}
return EncodedAsRegister;
}
return CantEncode;
}
if (const auto *FlexImm = llvm::dyn_cast<OperandARM32FlexImm>(Opnd)) {
const IValueT Immed8 = FlexImm->getImm();
const IValueT Rotate = FlexImm->getRotateAmt();
if (!((Rotate < (1 << kRotateBits)) && (Immed8 < (1 << kImmed8Bits))))
return CantEncode;
Value = (Rotate << kRotateShift) | (Immed8 << kImmed8Shift);
return EncodedAsRotatedImm8;
}
if (const auto *Const = llvm::dyn_cast<ConstantInteger32>(Opnd)) {
Value = Const->getValue();
return EncodedAsConstI32;
}
if (const auto *FlexReg = llvm::dyn_cast<OperandARM32FlexReg>(Opnd)) {
Operand *Amt = FlexReg->getShiftAmt();
IValueT Rm;
if (encodeOperand(FlexReg->getReg(), Rm, WantGPRegs) != EncodedAsRegister)
return CantEncode;
if (const auto *Var = llvm::dyn_cast<Variable>(Amt)) {
IValueT Rs;
if (encodeOperand(Var, Rs, WantGPRegs) != EncodedAsRegister)
return CantEncode;
Value = encodeShiftRotateReg(Rm, FlexReg->getShiftOp(), Rs);
return EncodedAsRegShiftReg;
}
// If reached, the amount is a shifted amount by some 5-bit immediate.
uint32_t Imm5;
if (const auto *ShAmt = llvm::dyn_cast<OperandARM32ShAmtImm>(Amt)) {
Imm5 = ShAmt->getShAmtImm();
} else if (const auto *IntConst = llvm::dyn_cast<ConstantInteger32>(Amt)) {
int32_t Val = IntConst->getValue();
if (Val < 0)
return CantEncode;
Imm5 = static_cast<uint32_t>(Val);
} else
return CantEncode;
Value = encodeShiftRotateImm5(Rm, FlexReg->getShiftOp(), Imm5);
return EncodedAsShiftedRegister;
}
if (const auto *ShImm = llvm::dyn_cast<OperandARM32ShAmtImm>(Opnd)) {
const IValueT Immed5 = ShImm->getShAmtImm();
assert(Immed5 < (1 << kShiftImmBits));
Value = (Immed5 << kShiftImmShift);
return EncodedAsShiftImm5;
}
return CantEncode;
}
IValueT encodeImmRegOffset(IValueT Reg, IOffsetT Offset,
OperandARM32Mem::AddrMode Mode, IOffsetT MaxOffset,
IValueT OffsetShift) {
IValueT Value = Mode | (Reg << kRnShift);
if (Offset < 0) {
Offset = -Offset;
Value ^= U; // Flip U to adjust sign.
}
assert(Offset <= MaxOffset);
(void)MaxOffset;
return Value | (Offset >> OffsetShift);
}
// Encodes immediate register offset using encoding 3.
IValueT encodeImmRegOffsetEnc3(IValueT Rn, IOffsetT Imm8,
OperandARM32Mem::AddrMode Mode) {
IValueT Value = Mode | (Rn << kRnShift);
if (Imm8 < 0) {
Imm8 = -Imm8;
Value = (Value ^ U);
}
assert(Imm8 < (1 << 8));
Value = Value | B22 | ((Imm8 & 0xf0) << 4) | (Imm8 & 0x0f);
return Value;
}
IValueT encodeImmRegOffset(EncodedImmAddress ImmEncoding, IValueT Reg,
IOffsetT Offset, OperandARM32Mem::AddrMode Mode) {
switch (ImmEncoding) {
case RotatedImm8Address: {
constexpr IOffsetT MaxOffset = (1 << 8) - 1;
constexpr IValueT NoRightShift = 0;
return encodeImmRegOffset(Reg, Offset, Mode, MaxOffset, NoRightShift);
}
case RotatedImm8Div4Address: {
assert((Offset & 0x3) == 0);
constexpr IOffsetT MaxOffset = (1 << 8) - 1;
constexpr IValueT RightShift2 = 2;
return encodeImmRegOffset(Reg, Offset, Mode, MaxOffset, RightShift2);
}
case Imm12Address: {
constexpr IOffsetT MaxOffset = (1 << 12) - 1;
constexpr IValueT NoRightShift = 0;
return encodeImmRegOffset(Reg, Offset, Mode, MaxOffset, NoRightShift);
}
case RotatedImm8Enc3Address:
return encodeImmRegOffsetEnc3(Reg, Offset, Mode);
case NoImmOffsetAddress: {
assert(Offset == 0);
assert(Mode == OperandARM32Mem::Offset);
return Reg << kRnShift;
}
}
llvm_unreachable("(silence g++ warning)");
}
// Encodes memory address Opnd, and encodes that information into Value, based
// on how ARM represents the address. Returns how the value was encoded.
EncodedOperand encodeAddress(const Operand *Opnd, IValueT &Value,
const AssemblerARM32::TargetInfo &TInfo,
EncodedImmAddress ImmEncoding) {
Value = 0; // Make sure initialized.
if (const auto *Var = llvm::dyn_cast<Variable>(Opnd)) {
// Should be a stack variable, with an offset.
if (Var->hasReg())
return CantEncode;
IOffsetT Offset = Var->getStackOffset();
if (!Utils::IsAbsoluteUint(12, Offset))
return CantEncode;
const auto BaseRegNum =
Var->hasReg() ? Var->getBaseRegNum() : TInfo.FrameOrStackReg;
Value = encodeImmRegOffset(ImmEncoding, BaseRegNum, Offset,
OperandARM32Mem::Offset);
return EncodedAsImmRegOffset;
}
if (const auto *Mem = llvm::dyn_cast<OperandARM32Mem>(Opnd)) {
Variable *Var = Mem->getBase();
if (!Var->hasReg())
return CantEncode;
IValueT Rn = getEncodedGPRegNum(Var);
if (Mem->isRegReg()) {
const Variable *Index = Mem->getIndex();
if (Var == nullptr)
return CantEncode;
Value = (Rn << kRnShift) | Mem->getAddrMode() |
encodeShiftRotateImm5(getEncodedGPRegNum(Index),
Mem->getShiftOp(), Mem->getShiftAmt());
return EncodedAsShiftRotateImm5;
}
// Encoded as immediate register offset.
ConstantInteger32 *Offset = Mem->getOffset();
Value = encodeImmRegOffset(ImmEncoding, Rn, Offset->getValue(),
Mem->getAddrMode());
return EncodedAsImmRegOffset;
}
return CantEncode;
}
// Checks that Offset can fit in imm24 constant of branch (b) instruction.
void assertCanEncodeBranchOffset(IOffsetT Offset) {
(void)Offset;
(void)kBranchOffsetBits;
assert(Utils::IsAligned(Offset, 4) &&
Utils::IsInt(kBranchOffsetBits, Offset >> 2));
}
IValueT encodeBranchOffset(IOffsetT Offset, IValueT Inst) {
// Adjust offset to the way ARM CPUs read PC.
Offset -= kPCReadOffset;
assertCanEncodeBranchOffset(Offset);
// Properly preserve only the bits supported in the instruction.
Offset >>= 2;
Offset &= kBranchOffsetMask;
return (Inst & ~kBranchOffsetMask) | Offset;
}
IValueT encodeRegister(const Operand *OpReg, RegSetWanted WantedRegSet,
const char *RegName, const char *InstName) {
IValueT Reg = 0;
if (encodeOperand(OpReg, Reg, WantedRegSet) != EncodedAsRegister)
llvm::report_fatal_error(std::string(InstName) + ": Can't find register " +
RegName);
return Reg;
}
IValueT encodeGPRegister(const Operand *OpReg, const char *RegName,
const char *InstName) {
return encodeRegister(OpReg, WantGPRegs, RegName, InstName);
}
IValueT encodeSRegister(const Operand *OpReg, const char *RegName,
const char *InstName) {
return encodeRegister(OpReg, WantSRegs, RegName, InstName);
}
IValueT encodeDRegister(const Operand *OpReg, const char *RegName,
const char *InstName) {
return encodeRegister(OpReg, WantDRegs, RegName, InstName);
}
IValueT encodeQRegister(const Operand *OpReg, const char *RegName,
const char *InstName) {
return encodeRegister(OpReg, WantQRegs, RegName, InstName);
}
void verifyPOrNotW(IValueT Address, const char *InstName) {
if (BuildDefs::minimal())
return;
if (!isBitSet(P, Address) && isBitSet(W, Address))
llvm::report_fatal_error(std::string(InstName) +
": P=0 when W=1 not allowed");
}
void verifyRegsNotEq(IValueT Reg1, const char *Reg1Name, IValueT Reg2,
const char *Reg2Name, const char *InstName) {
if (BuildDefs::minimal())
return;
if (Reg1 == Reg2)
llvm::report_fatal_error(std::string(InstName) + ": " + Reg1Name + "=" +
Reg2Name + " not allowed");
}
void verifyRegNotPc(IValueT Reg, const char *RegName, const char *InstName) {
verifyRegsNotEq(Reg, RegName, RegARM32::Encoded_Reg_pc, "pc", InstName);
}
void verifyAddrRegNotPc(IValueT RegShift, IValueT Address, const char *RegName,
const char *InstName) {
if (BuildDefs::minimal())
return;
if (getGPRReg(RegShift, Address) == RegARM32::Encoded_Reg_pc)
llvm::report_fatal_error(std::string(InstName) + ": " + RegName +
"=pc not allowed");
}
void verifyRegNotPcWhenSetFlags(IValueT Reg, bool SetFlags,
const char *InstName) {
if (BuildDefs::minimal())
return;
if (SetFlags && (Reg == RegARM32::Encoded_Reg_pc))
llvm::report_fatal_error(std::string(InstName) + ": " +
RegARM32::getRegName(RegARM32::Reg_pc) +
"=pc not allowed when CC=1");
}
enum SIMDShiftType { ST_Vshl, ST_Vshr };
IValueT encodeSIMDShiftImm6(SIMDShiftType Shift, Type ElmtTy,
const IValueT Imm) {
assert(Imm > 0);
const SizeT MaxShift = getScalarIntBitWidth(ElmtTy);
assert(Imm < 2 * MaxShift);
assert(ElmtTy == IceType_i8 || ElmtTy == IceType_i16 ||
ElmtTy == IceType_i32);
const IValueT VshlImm = Imm - MaxShift;
const IValueT VshrImm = 2 * MaxShift - Imm;
return ((Shift == ST_Vshl) ? VshlImm : VshrImm) & (2 * MaxShift - 1);
}
IValueT encodeSIMDShiftImm6(SIMDShiftType Shift, Type ElmtTy,
const ConstantInteger32 *Imm6) {
const IValueT Imm = Imm6->getValue();
return encodeSIMDShiftImm6(Shift, ElmtTy, Imm);
}
} // end of anonymous namespace
namespace Ice {
namespace ARM32 {
size_t MoveRelocatableFixup::emit(GlobalContext *Ctx,
const Assembler &Asm) const {
if (!BuildDefs::dump())
return InstARM32::InstSize;
Ostream &Str = Ctx->getStrEmit();
IValueT Inst = Asm.load<IValueT>(position());
const bool IsMovw = kind() == llvm::ELF::R_ARM_MOVW_ABS_NC ||
kind() == llvm::ELF::R_ARM_MOVW_PREL_NC;
const auto Symbol = symbol().toString();
const bool NeedsPCRelSuffix =
(Asm.fixupIsPCRel(kind()) || Symbol == GlobalOffsetTable);
Str << "\t"
"mov"
<< (IsMovw ? "w" : "t") << "\t"
<< RegARM32::getRegName(RegNumT::fixme((Inst >> kRdShift) & 0xF))
<< ", #:" << (IsMovw ? "lower" : "upper") << "16:" << Symbol
<< (NeedsPCRelSuffix ? " - ." : "")
<< "\t@ .word "
// TODO(jpp): This is broken, it also needs to add a magic constant.
<< llvm::format_hex_no_prefix(Inst, 8) << "\n";
return InstARM32::InstSize;
}
IValueT AssemblerARM32::encodeElmtType(Type ElmtTy) {
switch (ElmtTy) {
case IceType_i8:
return 0;
case IceType_i16:
return 1;
case IceType_i32:
case IceType_f32:
return 2;
case IceType_i64:
return 3;
default:
llvm::report_fatal_error("SIMD op: Don't understand element type " +
typeStdString(ElmtTy));
}
}
// This fixup points to an ARM32 instruction with the following format:
void MoveRelocatableFixup::emitOffset(Assembler *Asm) const {
// cccc00110T00iiiiddddiiiiiiiiiiii where cccc=Cond, dddd=Rd,
// iiiiiiiiiiiiiiii = Imm16, and T=1 for movt.
const IValueT Inst = Asm->load<IValueT>(position());
constexpr IValueT Imm16Mask = 0x000F0FFF;
const IValueT Imm16 = offset() & 0xffff;
Asm->store(position(),
(Inst & ~Imm16Mask) | ((Imm16 >> 12) << 16) | (Imm16 & 0xfff));
}
MoveRelocatableFixup *AssemblerARM32::createMoveFixup(bool IsMovW,
const Constant *Value) {
MoveRelocatableFixup *F =
new (allocate<MoveRelocatableFixup>()) MoveRelocatableFixup();
F->set_kind(IsMovW ? llvm::ELF::R_ARM_MOVW_ABS_NC
: llvm::ELF::R_ARM_MOVT_ABS);
F->set_value(Value);
Buffer.installFixup(F);
return F;
}
size_t BlRelocatableFixup::emit(GlobalContext *Ctx,
const Assembler &Asm) const {
if (!BuildDefs::dump())
return InstARM32::InstSize;
Ostream &Str = Ctx->getStrEmit();
IValueT Inst = Asm.load<IValueT>(position());
Str << "\t"
"bl\t"
<< symbol() << "\t@ .word " << llvm::format_hex_no_prefix(Inst, 8)
<< "\n";
return InstARM32::InstSize;
}
void BlRelocatableFixup::emitOffset(Assembler *Asm) const {
// cccc101liiiiiiiiiiiiiiiiiiiiiiii where cccc=Cond, l=Link, and
// iiiiiiiiiiiiiiiiiiiiiiii=
// EncodedBranchOffset(cccc101l000000000000000000000000, Offset);
const IValueT Inst = Asm->load<IValueT>(position());
constexpr IValueT OffsetMask = 0x00FFFFFF;
Asm->store(position(), encodeBranchOffset(offset(), Inst & ~OffsetMask));
}
void AssemblerARM32::padWithNop(intptr_t Padding) {
constexpr intptr_t InstWidth = sizeof(IValueT);
assert(Padding % InstWidth == 0 &&
"Padding not multiple of instruction size");
for (intptr_t i = 0; i < Padding; i += InstWidth)
nop();
}
BlRelocatableFixup *
AssemblerARM32::createBlFixup(const ConstantRelocatable *BlTarget) {
BlRelocatableFixup *F =
new (allocate<BlRelocatableFixup>()) BlRelocatableFixup();
F->set_kind(llvm::ELF::R_ARM_CALL);
F->set_value(BlTarget);
Buffer.installFixup(F);
return F;
}
void AssemblerARM32::bindCfgNodeLabel(const CfgNode *Node) {
if (BuildDefs::dump() && !getFlags().getDisableHybridAssembly()) {
// Generate label name so that branches can find it.
constexpr SizeT InstSize = 0;
emitTextInst(Node->getAsmName() + ":", InstSize);
}
SizeT NodeNumber = Node->getIndex();
assert(!getPreliminary());
Label *L = getOrCreateCfgNodeLabel(NodeNumber);
this->bind(L);
}
Label *AssemblerARM32::getOrCreateLabel(SizeT Number, LabelVector &Labels) {
Label *L = nullptr;
if (Number == Labels.size()) {
L = new (this->allocate<Label>()) Label();
Labels.push_back(L);
return L;
}
if (Number > Labels.size()) {
Labels.resize(Number + 1);
}
L = Labels[Number];
if (!L) {
L = new (this->allocate<Label>()) Label();
Labels[Number] = L;
}
return L;
}
// Pull out offset from branch Inst.
IOffsetT AssemblerARM32::decodeBranchOffset(IValueT Inst) {
// Sign-extend, left-shift by 2, and adjust to the way ARM CPUs read PC.
const IOffsetT Offset = (Inst & kBranchOffsetMask) << 8;
return (Offset >> 6) + kPCReadOffset;
}
void AssemblerARM32::bind(Label *L) {
IOffsetT BoundPc = Buffer.size();
assert(!L->isBound()); // Labels can only be bound once.
while (L->isLinked()) {
IOffsetT Position = L->getLinkPosition();
IOffsetT Dest = BoundPc - Position;
IValueT Inst = Buffer.load<IValueT>(Position);
Buffer.store<IValueT>(Position, encodeBranchOffset(Dest, Inst));
L->setPosition(decodeBranchOffset(Inst));
}
L->bindTo(BoundPc);
}
void AssemblerARM32::emitTextInst(const std::string &Text, SizeT InstSize) {
AssemblerFixup *F = createTextFixup(Text, InstSize);
emitFixup(F);
for (SizeT I = 0; I < InstSize; ++I) {
AssemblerBuffer::EnsureCapacity ensured(&Buffer);
Buffer.emit<char>(0);
}
}
void AssemblerARM32::emitType01(CondARM32::Cond Cond, IValueT InstType,
IValueT Opcode, bool SetFlags, IValueT Rn,
IValueT Rd, IValueT Imm12,
EmitChecks RuleChecks, const char *InstName) {
switch (RuleChecks) {
case NoChecks:
break;
case RdIsPcAndSetFlags:
verifyRegNotPcWhenSetFlags(Rd, SetFlags, InstName);
break;
}
assert(Rd < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) |
(InstType << kTypeShift) | (Opcode << kOpcodeShift) |
(encodeBool(SetFlags) << kSShift) |
(Rn << kRnShift) | (Rd << kRdShift) | Imm12;
emitInst(Encoding);
}
void AssemblerARM32::emitType01(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
EmitChecks RuleChecks, const char *InstName) {
IValueT Rd = encodeGPRegister(OpRd, "Rd", InstName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", InstName);
emitType01(Cond, Opcode, Rd, Rn, OpSrc1, SetFlags, RuleChecks, InstName);
}
void AssemblerARM32::emitType01(CondARM32::Cond Cond, IValueT Opcode,
IValueT Rd, IValueT Rn, const Operand *OpSrc1,
bool SetFlags, EmitChecks RuleChecks,
const char *InstName) {
IValueT Src1Value;
// TODO(kschimpf) Other possible decodings of data operations.
switch (encodeOperand(OpSrc1, Src1Value, WantGPRegs)) {
default:
llvm::report_fatal_error(std::string(InstName) +
": Can't encode instruction");
return;
case EncodedAsRegister: {
// XXX (register)
// xxx{s}<c> <Rd>, <Rn>, <Rm>{, <shiff>}
//
// cccc000xxxxsnnnnddddiiiiitt0mmmm where cccc=Cond, xxxx=Opcode, dddd=Rd,
// nnnn=Rn, mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
constexpr IValueT Imm5 = 0;
Src1Value = encodeShiftRotateImm5(Src1Value, OperandARM32::kNoShift, Imm5);
emitType01(Cond, kInstTypeDataRegister, Opcode, SetFlags, Rn, Rd, Src1Value,
RuleChecks, InstName);
return;
}
case EncodedAsShiftedRegister: {
// Form is defined in case EncodedAsRegister. (i.e. XXX (register)).
emitType01(Cond, kInstTypeDataRegister, Opcode, SetFlags, Rn, Rd, Src1Value,
RuleChecks, InstName);
return;
}
case EncodedAsConstI32: {
// See if we can convert this to an XXX (immediate).
IValueT RotateAmt;
IValueT Imm8;
if (!OperandARM32FlexImm::canHoldImm(Src1Value, &RotateAmt, &Imm8))
llvm::report_fatal_error(std::string(InstName) +
": Immediate rotated constant not valid");
Src1Value = encodeRotatedImm8(RotateAmt, Imm8);
// Intentionally fall to next case!
}
case EncodedAsRotatedImm8: {
// XXX (Immediate)
// xxx{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc001xxxxsnnnnddddiiiiiiiiiiii where cccc=Cond, xxxx=Opcode, dddd=Rd,
// nnnn=Rn, s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
emitType01(Cond, kInstTypeDataImmediate, Opcode, SetFlags, Rn, Rd,
Src1Value, RuleChecks, InstName);
return;
}
case EncodedAsRegShiftReg: {
// XXX (register-shifted reg)
// xxx{s}<c> <Rd>, <Rn>, <Rm>, <type> <Rs>
//
// cccc000xxxxfnnnnddddssss0tt1mmmm where cccc=Cond, xxxx=Opcode, dddd=Rd,
// nnnn=Rn, ssss=Rs, f=SetFlags, tt is encoding of type, and
// Src1Value=ssss01tt1mmmm.
emitType01(Cond, kInstTypeDataRegShift, Opcode, SetFlags, Rn, Rd, Src1Value,
RuleChecks, InstName);
return;
}
}
}
void AssemblerARM32::emitType05(CondARM32::Cond Cond, IOffsetT Offset,
bool Link) {
// cccc101liiiiiiiiiiiiiiiiiiiiiiii where cccc=Cond, l=Link, and
// iiiiiiiiiiiiiiiiiiiiiiii=
// EncodedBranchOffset(cccc101l000000000000000000000000, Offset);
assert(CondARM32::isDefined(Cond));
IValueT Encoding = static_cast<int32_t>(Cond) << kConditionShift |
5 << kTypeShift | (Link ? 1 : 0) << kLinkShift;
Encoding = encodeBranchOffset(Offset, Encoding);
emitInst(Encoding);
}
void AssemblerARM32::emitBranch(Label *L, CondARM32::Cond Cond, bool Link) {
// TODO(kschimpf): Handle far jumps.
if (L->isBound()) {
const int32_t Dest = L->getPosition() - Buffer.size();
emitType05(Cond, Dest, Link);
return;
}
const IOffsetT Position = Buffer.size();
// Use the offset field of the branch instruction for linking the sites.
emitType05(Cond, L->getEncodedPosition(), Link);
L->linkTo(*this, Position);
}
void AssemblerARM32::emitCompareOp(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpRn, const Operand *OpSrc1,
const char *InstName) {
// XXX (register)
// XXX<c> <Rn>, <Rm>{, <shift>}
//
// ccccyyyxxxx1nnnn0000iiiiitt0mmmm where cccc=Cond, nnnn=Rn, mmmm=Rm, iiiii
// defines shift constant, tt=ShiftKind, yyy=kInstTypeDataRegister, and
// xxxx=Opcode.
//
// XXX (immediate)
// XXX<c> <Rn>, #<RotatedImm8>
//
// ccccyyyxxxx1nnnn0000iiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// yyy=kInstTypeDataImmdiate, xxxx=Opcode, and iiiiiiiiiiii=Src1Value
// defining RotatedImm8.
constexpr bool SetFlags = true;
constexpr IValueT Rd = RegARM32::Encoded_Reg_r0;
IValueT Rn = encodeGPRegister(OpRn, "Rn", InstName);
emitType01(Cond, Opcode, Rd, Rn, OpSrc1, SetFlags, NoChecks, InstName);
}
void AssemblerARM32::emitMemOp(CondARM32::Cond Cond, IValueT InstType,
bool IsLoad, bool IsByte, IValueT Rt,
IValueT Address) {
assert(Rt < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) |
(InstType << kTypeShift) | (IsLoad ? L : 0) |
(IsByte ? B : 0) | (Rt << kRdShift) | Address;
emitInst(Encoding);
}
void AssemblerARM32::emitMemOp(CondARM32::Cond Cond, bool IsLoad, bool IsByte,
IValueT Rt, const Operand *OpAddress,
const TargetInfo &TInfo, const char *InstName) {
IValueT Address;
switch (encodeAddress(OpAddress, Address, TInfo, Imm12Address)) {
default:
llvm::report_fatal_error(std::string(InstName) +
": Memory address not understood");
case EncodedAsImmRegOffset: {
// XXX{B} (immediate):
// xxx{b}<c> <Rt>, [<Rn>{, #+/-<imm12>}] ; p=1, w=0
// xxx{b}<c> <Rt>, [<Rn>], #+/-<imm12> ; p=1, w=1
// xxx{b}<c> <Rt>, [<Rn>, #+/-<imm12>]! ; p=0, w=1
//
// cccc010pubwlnnnnttttiiiiiiiiiiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiiiiiii=imm12, b=IsByte, pu0w<<21 is a BlockAddr, l=IsLoad, and
// pu0w0nnnn0000iiiiiiiiiiii=Address.
RegARM32::GPRRegister Rn = getGPRReg(kRnShift, Address);
// Check if conditions of rules violated.
verifyRegNotPc(Rn, "Rn", InstName);
verifyPOrNotW(Address, InstName);
if (!IsByte && (Rn == RegARM32::Encoded_Reg_sp) && !isBitSet(P, Address) &&
isBitSet(U, Address) && !isBitSet(W, Address) &&
(mask(Address, kImm12Shift, kImmed12Bits) == 0x8 /* 000000000100 */))
llvm::report_fatal_error(std::string(InstName) +
": Use push/pop instead");
emitMemOp(Cond, kInstTypeMemImmediate, IsLoad, IsByte, Rt, Address);
return;
}
case EncodedAsShiftRotateImm5: {
// XXX{B} (register)
// xxx{b}<c> <Rt>, [<Rn>, +/-<Rm>{, <shift>}]{!}
// xxx{b}<c> <Rt>, [<Rn>], +/-<Rm>{, <shift>}
//
// cccc011pubwlnnnnttttiiiiiss0mmmm where cccc=Cond, tttt=Rt,
// b=IsByte, U=1 if +, pu0b is a BlockAddr, l=IsLoad, and
// pu0w0nnnn0000iiiiiss0mmmm=Address.
RegARM32::GPRRegister Rn = getGPRReg(kRnShift, Address);
RegARM32::GPRRegister Rm = getGPRReg(kRmShift, Address);
// Check if conditions of rules violated.
verifyPOrNotW(Address, InstName);
verifyRegNotPc(Rm, "Rm", InstName);
if (IsByte)
verifyRegNotPc(Rt, "Rt", InstName);
if (isBitSet(W, Address)) {
verifyRegNotPc(Rn, "Rn", InstName);
verifyRegsNotEq(Rn, "Rn", Rt, "Rt", InstName);
}
emitMemOp(Cond, kInstTypeRegisterShift, IsLoad, IsByte, Rt, Address);
return;
}
}
}
void AssemblerARM32::emitMemOpEnc3(CondARM32::Cond Cond, IValueT Opcode,
IValueT Rt, const Operand *OpAddress,
const TargetInfo &TInfo,
const char *InstName) {
IValueT Address;
switch (encodeAddress(OpAddress, Address, TInfo, RotatedImm8Enc3Address)) {
default:
llvm::report_fatal_error(std::string(InstName) +
": Memory address not understood");
case EncodedAsImmRegOffset: {
// XXXH (immediate)
// xxxh<c> <Rt>, [<Rn>{, #+-<Imm8>}]
// xxxh<c> <Rt>, [<Rn>, #+/-<Imm8>]
// xxxh<c> <Rt>, [<Rn>, #+/-<Imm8>]!
//
// cccc000pu0wxnnnnttttiiiiyyyyjjjj where cccc=Cond, nnnn=Rn, tttt=Rt,
// iiiijjjj=Imm8, pu0w<<21 is a BlockAddr, x000000000000yyyy0000=Opcode,
// and pu0w0nnnn0000iiii0000jjjj=Address.
assert(Rt < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
verifyPOrNotW(Address, InstName);
verifyRegNotPc(Rt, "Rt", InstName);
if (isBitSet(W, Address))
verifyRegsNotEq(getGPRReg(kRnShift, Address), "Rn", Rt, "Rt", InstName);
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) |
Opcode | (Rt << kRdShift) | Address;
emitInst(Encoding);
return;
}
case EncodedAsShiftRotateImm5: {
// XXXH (register)
// xxxh<c> <Rt>, [<Rn>, +/-<Rm>]{!}
// xxxh<c> <Rt>, [<Rn>], +/-<Rm>
//
// cccc000pu0wxnnnntttt00001011mmmm where cccc=Cond, tttt=Rt, nnnn=Rn,
// mmmm=Rm, pu0w<<21 is a BlockAddr, x000000000000yyyy0000=Opcode, and
// pu0w0nnnn000000000000mmmm=Address.
assert(Rt < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
verifyPOrNotW(Address, InstName);
verifyRegNotPc(Rt, "Rt", InstName);
verifyAddrRegNotPc(kRmShift, Address, "Rm", InstName);
const RegARM32::GPRRegister Rn = getGPRReg(kRnShift, Address);
if (isBitSet(W, Address)) {
verifyRegNotPc(Rn, "Rn", InstName);
verifyRegsNotEq(Rn, "Rn", Rt, "Rt", InstName);
}
if (mask(Address, kShiftImmShift, 5) != 0)
// For encoding 3, no shift is allowed.
llvm::report_fatal_error(std::string(InstName) +
": Shift constant not allowed");
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) |
Opcode | (Rt << kRdShift) | Address;
emitInst(Encoding);
return;
}
}
}
void AssemblerARM32::emitDivOp(CondARM32::Cond Cond, IValueT Opcode, IValueT Rd,
IValueT Rn, IValueT Rm) {
assert(Rd < RegARM32::getNumGPRegs());
assert(Rn < RegARM32::getNumGPRegs());
assert(Rm < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
const IValueT Encoding = Opcode | (encodeCondition(Cond) << kConditionShift) |
(Rn << kDivRnShift) | (Rd << kDivRdShift) | B26 |
B25 | B24 | B20 | B15 | B14 | B13 | B12 | B4 |
(Rm << kDivRmShift);
emitInst(Encoding);
}
void AssemblerARM32::emitInsertExtractInt(CondARM32::Cond Cond,
const Operand *OpQn, uint32_t Index,
const Operand *OpRt, bool IsExtract,
const char *InstName) {
const IValueT Rt = encodeGPRegister(OpRt, "Rt", InstName);
IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", InstName));
assert(Rt != RegARM32::Encoded_Reg_pc);
assert(Rt != RegARM32::Encoded_Reg_sp);
assert(CondARM32::isDefined(Cond));
const uint32_t BitSize = typeWidthInBytes(OpRt->getType()) * CHAR_BIT;
IValueT Opcode1 = 0;
IValueT Opcode2 = 0;
switch (BitSize) {
default:
llvm::report_fatal_error(std::string(InstName) +
": Unable to process type " +
typeStdString(OpRt->getType()));
case 8:
assert(Index < 16);
Dn = Dn | mask(Index, 3, 1);
Opcode1 = B1 | mask(Index, 2, 1);
Opcode2 = mask(Index, 0, 2);
break;
case 16:
assert(Index < 8);
Dn = Dn | mask(Index, 2, 1);
Opcode1 = mask(Index, 1, 1);
Opcode2 = (mask(Index, 0, 1) << 1) | B0;
break;
case 32:
assert(Index < 4);
Dn = Dn | mask(Index, 1, 1);
Opcode1 = mask(Index, 0, 1);
break;
}
const IValueT Encoding = B27 | B26 | B25 | B11 | B9 | B8 | B4 |
(encodeCondition(Cond) << kConditionShift) |
(Opcode1 << 21) |
(getXXXXInRegYXXXX(Dn) << kRnShift) | (Rt << 12) |
(encodeBool(IsExtract) << 20) |
(getYInRegYXXXX(Dn) << 7) | (Opcode2 << 5);
emitInst(Encoding);
}
void AssemblerARM32::emitMoveSS(CondARM32::Cond Cond, IValueT Sd, IValueT Sm) {
// VMOV (register) - ARM section A8.8.340, encoding A2:
// vmov<c>.f32 <Sd>, <Sm>
//
// cccc11101D110000dddd101001M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr IValueT VmovssOpcode = B23 | B21 | B20 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VmovssOpcode, Sd, S0, Sm);
}
void AssemblerARM32::emitMulOp(CondARM32::Cond Cond, IValueT Opcode, IValueT Rd,
IValueT Rn, IValueT Rm, IValueT Rs,
bool SetFlags) {
assert(Rd < RegARM32::getNumGPRegs());
assert(Rn < RegARM32::getNumGPRegs());
assert(Rm < RegARM32::getNumGPRegs());
assert(Rs < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
IValueT Encoding = Opcode | (encodeCondition(Cond) << kConditionShift) |
(encodeBool(SetFlags) << kSShift) | (Rn << kRnShift) |
(Rd << kRdShift) | (Rs << kRsShift) | B7 | B4 |
(Rm << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::emitMultiMemOp(CondARM32::Cond Cond,
BlockAddressMode AddressMode, bool IsLoad,
IValueT BaseReg, IValueT Registers) {
assert(CondARM32::isDefined(Cond));
assert(BaseReg < RegARM32::getNumGPRegs());
assert(Registers < (1 << RegARM32::getNumGPRegs()));
IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | B27 |
AddressMode | (IsLoad ? L : 0) | (BaseReg << kRnShift) |
Registers;
emitInst(Encoding);
}
void AssemblerARM32::emitSignExtend(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpRd, const Operand *OpSrc0,
const char *InstName) {
IValueT Rd = encodeGPRegister(OpRd, "Rd", InstName);
IValueT Rm = encodeGPRegister(OpSrc0, "Rm", InstName);
// Note: For the moment, we assume no rotation is specified.
RotationValue Rotation = kRotateNone;
constexpr IValueT Rn = RegARM32::Encoded_Reg_pc;
const Type Ty = OpSrc0->getType();
switch (Ty) {
default:
llvm::report_fatal_error(std::string(InstName) + ": Type " +
typeString(Ty) + " not allowed");
break;
case IceType_i1:
case IceType_i8: {
// SXTB/UXTB - Arm sections A8.8.233 and A8.8.274, encoding A1:
// sxtb<c> <Rd>, <Rm>{, <rotate>}
// uxtb<c> <Rd>, <Rm>{, <rotate>}
//
// ccccxxxxxxxx1111ddddrr000111mmmm where cccc=Cond, xxxxxxxx<<20=Opcode,
// dddd=Rd, mmmm=Rm, and rr defined (RotationValue) rotate.
break;
}
case IceType_i16: {
// SXTH/UXTH - ARM sections A8.8.235 and A8.8.276, encoding A1:
// uxth<c> <Rd>< <Rm>{, <rotate>}
//
// cccc01101111nnnnddddrr000111mmmm where cccc=Cond, dddd=Rd, mmmm=Rm, and
// rr defined (RotationValue) rotate.
Opcode |= B20;
break;
}
}
assert(CondARM32::isDefined(Cond));
IValueT Rot = encodeRotation(Rotation);
if (!Utils::IsUint(2, Rot))
llvm::report_fatal_error(std::string(InstName) +
": Illegal rotation value");
IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | Opcode |
(Rn << kRnShift) | (Rd << kRdShift) |
(Rot << kRotationShift) | B6 | B5 | B4 | (Rm << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::emitSIMDBase(IValueT Opcode, IValueT Dd, IValueT Dn,
IValueT Dm, bool UseQRegs, bool IsFloatTy) {
const IValueT Encoding =
Opcode | B25 | (encodeCondition(CondARM32::kNone) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (getXXXXInRegYXXXX(Dn) << 16) |
(getXXXXInRegYXXXX(Dd) << 12) | (IsFloatTy ? B10 : 0) |
(getYInRegYXXXX(Dn) << 7) | (encodeBool(UseQRegs) << 6) |
(getYInRegYXXXX(Dm) << 5) | getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::emitSIMD(IValueT Opcode, Type ElmtTy, IValueT Dd,
IValueT Dn, IValueT Dm, bool UseQRegs) {
constexpr IValueT ElmtShift = 20;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
emitSIMDBase(Opcode | (ElmtSize << ElmtShift), Dd, Dn, Dm, UseQRegs,
isFloatingType(ElmtTy));
}
void AssemblerARM32::emitSIMDqqqBase(IValueT Opcode, const Operand *OpQd,
const Operand *OpQn, const Operand *OpQm,
bool IsFloatTy, const char *OpcodeName) {
const IValueT Qd = encodeQRegister(OpQd, "Qd", OpcodeName);
const IValueT Qn = encodeQRegister(OpQn, "Qn", OpcodeName);
const IValueT Qm = encodeQRegister(OpQm, "Qm", OpcodeName);
constexpr bool UseQRegs = true;
emitSIMDBase(Opcode, mapQRegToDReg(Qd), mapQRegToDReg(Qn), mapQRegToDReg(Qm),
UseQRegs, IsFloatTy);
}
void AssemblerARM32::emitSIMDqqq(IValueT Opcode, Type ElmtTy,
const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm, const char *OpcodeName) {
constexpr IValueT ElmtShift = 20;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
emitSIMDqqqBase(Opcode | (ElmtSize << ElmtShift), OpQd, OpQn, OpQm,
isFloatingType(ElmtTy), OpcodeName);
}
void AssemblerARM32::emitSIMDShiftqqc(IValueT Opcode, const Operand *OpQd,
const Operand *OpQm, const IValueT Imm6,
const char *OpcodeName) {
const IValueT Qd = encodeQRegister(OpQd, "Qd", OpcodeName);
const IValueT Qn = 0;
const IValueT Qm = encodeQRegister(OpQm, "Qm", OpcodeName);
constexpr bool UseQRegs = true;
constexpr bool IsFloatTy = false;
constexpr IValueT ElmtShift = 16;
emitSIMDBase(Opcode | (Imm6 << ElmtShift), mapQRegToDReg(Qd),
mapQRegToDReg(Qn), mapQRegToDReg(Qm), UseQRegs, IsFloatTy);
}
void AssemblerARM32::emitSIMDCvtqq(IValueT Opcode, const Operand *OpQd,
const Operand *OpQm,
const char *OpcodeName) {
const IValueT SIMDOpcode =
B24 | B23 | B21 | B20 | B19 | B17 | B16 | B10 | B9 | Opcode;
constexpr bool UseQRegs = true;
constexpr bool IsFloatTy = false;
const IValueT Qd = encodeQRegister(OpQd, "Qd", OpcodeName);
constexpr IValueT Qn = 0;
const IValueT Qm = encodeQRegister(OpQm, "Qm", OpcodeName);
emitSIMDBase(SIMDOpcode, mapQRegToDReg(Qd), mapQRegToDReg(Qn),
mapQRegToDReg(Qm), UseQRegs, IsFloatTy);
}
void AssemblerARM32::emitVFPddd(CondARM32::Cond Cond, IValueT Opcode,
IValueT Dd, IValueT Dn, IValueT Dm) {
assert(Dd < RegARM32::getNumDRegs());
assert(Dn < RegARM32::getNumDRegs());
assert(Dm < RegARM32::getNumDRegs());
assert(CondARM32::isDefined(Cond));
constexpr IValueT VFPOpcode = B27 | B26 | B25 | B11 | B9 | B8;
const IValueT Encoding =
Opcode | VFPOpcode | (encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (getXXXXInRegYXXXX(Dn) << 16) |
(getXXXXInRegYXXXX(Dd) << 12) | (getYInRegYXXXX(Dn) << 7) |
(getYInRegYXXXX(Dm) << 5) | getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::emitVFPddd(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, const char *InstName) {
IValueT Dd = encodeDRegister(OpDd, "Dd", InstName);
IValueT Dn = encodeDRegister(OpDn, "Dn", InstName);
IValueT Dm = encodeDRegister(OpDm, "Dm", InstName);
emitVFPddd(Cond, Opcode, Dd, Dn, Dm);
}
void AssemblerARM32::emitVFPsss(CondARM32::Cond Cond, IValueT Opcode,
IValueT Sd, IValueT Sn, IValueT Sm) {
assert(Sd < RegARM32::getNumSRegs());
assert(Sn < RegARM32::getNumSRegs());
assert(Sm < RegARM32::getNumSRegs());
assert(CondARM32::isDefined(Cond));
constexpr IValueT VFPOpcode = B27 | B26 | B25 | B11 | B9;
const IValueT Encoding =
Opcode | VFPOpcode | (encodeCondition(Cond) << kConditionShift) |
(getYInRegXXXXY(Sd) << 22) | (getXXXXInRegXXXXY(Sn) << 16) |
(getXXXXInRegXXXXY(Sd) << 12) | (getYInRegXXXXY(Sn) << 7) |
(getYInRegXXXXY(Sm) << 5) | getXXXXInRegXXXXY(Sm);
emitInst(Encoding);
}
void AssemblerARM32::emitVFPsss(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, const char *InstName) {
const IValueT Sd = encodeSRegister(OpSd, "Sd", InstName);
const IValueT Sn = encodeSRegister(OpSn, "Sn", InstName);
const IValueT Sm = encodeSRegister(OpSm, "Sm", InstName);
emitVFPsss(Cond, Opcode, Sd, Sn, Sm);
}
void AssemblerARM32::adc(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// ADC (register) - ARM section 18.8.2, encoding A1:
// adc{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
//
// cccc0000101snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// ADC (Immediate) - ARM section A8.8.1, encoding A1:
// adc{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0010101snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *AdcName = "adc";
constexpr IValueT AdcOpcode = B2 | B0; // 0101
emitType01(Cond, AdcOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
AdcName);
}
void AssemblerARM32::add(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// ADD (register) - ARM section A8.8.7, encoding A1:
// add{s}<c> <Rd>, <Rn>, <Rm>{, <shiff>}
// ADD (Sp plus register) - ARM section A8.8.11, encoding A1:
// add{s}<c> sp, <Rn>, <Rm>{, <shiff>}
//
// cccc0000100snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// ADD (Immediate) - ARM section A8.8.5, encoding A1:
// add{s}<c> <Rd>, <Rn>, #<RotatedImm8>
// ADD (SP plus immediate) - ARM section A8.8.9, encoding A1.
// add{s}<c> <Rd>, sp, #<RotatedImm8>
//
// cccc0010100snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *AddName = "add";
constexpr IValueT Add = B2; // 0100
emitType01(Cond, Add, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
AddName);
}
void AssemblerARM32::and_(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// AND (register) - ARM section A8.8.14, encoding A1:
// and{s}<c> <Rd>, <Rn>{, <shift>}
//
// cccc0000000snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// AND (Immediate) - ARM section A8.8.13, encoding A1:
// and{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0010100snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *AndName = "and";
constexpr IValueT And = 0; // 0000
emitType01(Cond, And, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
AndName);
}
void AssemblerARM32::b(Label *L, CondARM32::Cond Cond) {
emitBranch(L, Cond, false);
}
void AssemblerARM32::bkpt(uint16_t Imm16) {
// BKPT - ARM section A*.8.24 - encoding A1:
// bkpt #<Imm16>
//
// cccc00010010iiiiiiiiiiii0111iiii where cccc=AL and iiiiiiiiiiiiiiii=Imm16
const IValueT Encoding = (CondARM32::AL << kConditionShift) | B24 | B21 |
((Imm16 >> 4) << 8) | B6 | B5 | B4 | (Imm16 & 0xf);
emitInst(Encoding);
}
void AssemblerARM32::bic(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// BIC (register) - ARM section A8.8.22, encoding A1:
// bic{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
//
// cccc0001110snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// BIC (immediate) - ARM section A8.8.21, encoding A1:
// bic{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0011110snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rn, nnnn=Rn,
// s=SetFlags, and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *BicName = "bic";
constexpr IValueT BicOpcode = B3 | B2 | B1; // i.e. 1110
emitType01(Cond, BicOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
BicName);
}
void AssemblerARM32::bl(const ConstantRelocatable *Target) {
// BL (immediate) - ARM section A8.8.25, encoding A1:
// bl<c> <label>
//
// cccc1011iiiiiiiiiiiiiiiiiiiiiiii where cccc=Cond (not currently allowed)
// and iiiiiiiiiiiiiiiiiiiiiiii is the (encoded) Target to branch to.
emitFixup(createBlFixup(Target));
constexpr CondARM32::Cond Cond = CondARM32::AL;
constexpr IValueT Immed = 0;
constexpr bool Link = true;
emitType05(Cond, Immed, Link);
}
void AssemblerARM32::blx(const Operand *Target) {
// BLX (register) - ARM section A8.8.26, encoding A1:
// blx<c> <Rm>
//
// cccc000100101111111111110011mmmm where cccc=Cond (not currently allowed)
// and mmmm=Rm.
constexpr const char *BlxName = "Blx";
IValueT Rm = encodeGPRegister(Target, "Rm", BlxName);
verifyRegNotPc(Rm, "Rm", BlxName);
constexpr CondARM32::Cond Cond = CondARM32::AL;
int32_t Encoding = (encodeCondition(Cond) << kConditionShift) | B24 | B21 |
(0xfff << 8) | B5 | B4 | (Rm << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::bx(RegARM32::GPRRegister Rm, CondARM32::Cond Cond) {
// BX - ARM section A8.8.27, encoding A1:
// bx<c> <Rm>
//
// cccc000100101111111111110001mmmm where mmmm=rm and cccc=Cond.
assert(CondARM32::isDefined(Cond));
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | B24 |
B21 | (0xfff << 8) | B4 |
(encodeGPRRegister(Rm) << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::clz(const Operand *OpRd, const Operand *OpSrc,
CondARM32::Cond Cond) {
// CLZ - ARM section A8.8.33, encoding A1:
// clz<c> <Rd> <Rm>
//
// cccc000101101111dddd11110001mmmm where cccc=Cond, dddd=Rd, and mmmm=Rm.
constexpr const char *ClzName = "clz";
constexpr const char *RdName = "Rd";
constexpr const char *RmName = "Rm";
IValueT Rd = encodeGPRegister(OpRd, RdName, ClzName);
assert(Rd < RegARM32::getNumGPRegs());
verifyRegNotPc(Rd, RdName, ClzName);
IValueT Rm = encodeGPRegister(OpSrc, RmName, ClzName);
assert(Rm < RegARM32::getNumGPRegs());
verifyRegNotPc(Rm, RmName, ClzName);
assert(CondARM32::isDefined(Cond));
constexpr IValueT PredefinedBits =
B24 | B22 | B21 | (0xF << 16) | (0xf << 8) | B4;
const IValueT Encoding = PredefinedBits | (Cond << kConditionShift) |
(Rd << kRdShift) | (Rm << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::cmn(const Operand *OpRn, const Operand *OpSrc1,
CondARM32::Cond Cond) {
// CMN (immediate) - ARM section A8.8.34, encoding A1:
// cmn<c> <Rn>, #<RotatedImm8>
//
// cccc00110111nnnn0000iiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
//
// CMN (register) - ARM section A8.8.35, encodeing A1:
// cmn<c> <Rn>, <Rm>{, <shift>}
//
// cccc00010111nnnn0000iiiiitt0mmmm where cccc=Cond, nnnn=Rn, mmmm=Rm,
// iiiii=Shift, and tt=ShiftKind.
constexpr const char *CmnName = "cmn";
constexpr IValueT CmnOpcode = B3 | B1 | B0; // ie. 1011
emitCompareOp(Cond, CmnOpcode, OpRn, OpSrc1, CmnName);
}
void AssemblerARM32::cmp(const Operand *OpRn, const Operand *OpSrc1,
CondARM32::Cond Cond) {
// CMP (register) - ARM section A8.8.38, encoding A1:
// cmp<c> <Rn>, <Rm>{, <shift>}
//
// cccc00010101nnnn0000iiiiitt0mmmm where cccc=Cond, nnnn=Rn, mmmm=Rm,
// iiiii=Shift, and tt=ShiftKind.
//
// CMP (immediate) - ARM section A8.8.37
// cmp<c: <Rn>, #<RotatedImm8>
//
// cccc00110101nnnn0000iiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *CmpName = "cmp";
constexpr IValueT CmpOpcode = B3 | B1; // ie. 1010
emitCompareOp(Cond, CmpOpcode, OpRn, OpSrc1, CmpName);
}
void AssemblerARM32::dmb(IValueT Option) {
// DMB - ARM section A8.8.43, encoding A1:
// dmb <option>
//
// 1111010101111111111100000101xxxx where xxxx=Option.
assert(Utils::IsUint(4, Option) && "Bad dmb option");
const IValueT Encoding =
(encodeCondition(CondARM32::kNone) << kConditionShift) | B26 | B24 | B22 |
B21 | B20 | B19 | B18 | B17 | B16 | B15 | B14 | B13 | B12 | B6 | B4 |
Option;
emitInst(Encoding);
}
void AssemblerARM32::eor(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// EOR (register) - ARM section A*.8.47, encoding A1:
// eor{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
//
// cccc0000001snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// EOR (Immediate) - ARM section A8.*.46, encoding A1:
// eor{s}<c> <Rd>, <Rn>, #RotatedImm8
//
// cccc0010001snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *EorName = "eor";
constexpr IValueT EorOpcode = B0; // 0001
emitType01(Cond, EorOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
EorName);
}
void AssemblerARM32::ldr(const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
constexpr const char *LdrName = "ldr";
constexpr bool IsLoad = true;
IValueT Rt = encodeGPRegister(OpRt, "Rt", LdrName);
const Type Ty = OpRt->getType();
switch (Ty) {
case IceType_i64:
// LDRD is not implemented because target lowering handles i64 and double by
// using two (32-bit) load instructions. Note: Intentionally drop to default
// case.
llvm::report_fatal_error(std::string("ldr : Type ") + typeString(Ty) +
" not implemented");
default:
llvm::report_fatal_error(std::string("ldr : Type ") + typeString(Ty) +
" not allowed");
case IceType_i1:
case IceType_i8: {
// LDRB (immediate) - ARM section A8.8.68, encoding A1:
// ldrb<c> <Rt>, [<Rn>{, #+/-<imm12>}] ; p=1, w=0
// ldrb<c> <Rt>, [<Rn>], #+/-<imm12> ; p=1, w=1
// ldrb<c> <Rt>, [<Rn>, #+/-<imm12>]! ; p=0, w=1
//
// cccc010pu1w1nnnnttttiiiiiiiiiiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiiiiiii=imm12, u=1 if +, pu0w is a BlockAddr, and
// pu0w0nnnn0000iiiiiiiiiiii=Address.
//
// LDRB (register) - ARM section A8.8.66, encoding A1:
// ldrb<c> <Rt>, [<Rn>, +/-<Rm>{, <shift>}]{!}
// ldrb<c> <Rt>, [<Rn>], +/-<Rm>{, <shift>}
//
// cccc011pu1w1nnnnttttiiiiiss0mmmm where cccc=Cond, tttt=Rt, U=1 if +, pu0b
// is a BlockAddr, and pu0w0nnnn0000iiiiiss0mmmm=Address.
constexpr bool IsByte = true;
emitMemOp(Cond, IsLoad, IsByte, Rt, OpAddress, TInfo, LdrName);
return;
}
case IceType_i16: {
// LDRH (immediate) - ARM section A8.8.80, encoding A1:
// ldrh<c> <Rt>, [<Rn>{, #+/-<Imm8>}]
// ldrh<c> <Rt>, [<Rn>], #+/-<Imm8>
// ldrh<c> <Rt>, [<Rn>, #+/-<Imm8>]!
//
// cccc000pu1w1nnnnttttiiii1011iiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiii=Imm8, u=1 if +, pu0w is a BlockAddr, and
// pu0w0nnnn0000iiiiiiiiiiii=Address.
constexpr const char *Ldrh = "ldrh";
emitMemOpEnc3(Cond, L | B7 | B5 | B4, Rt, OpAddress, TInfo, Ldrh);
return;
}
case IceType_i32: {
// LDR (immediate) - ARM section A8.8.63, encoding A1:
// ldr<c> <Rt>, [<Rn>{, #+/-<imm12>}] ; p=1, w=0
// ldr<c> <Rt>, [<Rn>], #+/-<imm12> ; p=1, w=1
// ldr<c> <Rt>, [<Rn>, #+/-<imm12>]! ; p=0, w=1
//
// cccc010pu0w1nnnnttttiiiiiiiiiiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiiiiiii=imm12, u=1 if +, pu0w is a BlockAddr, and
//
// LDR (register) - ARM section A8.8.70, encoding A1:
// ldrb<c> <Rt>, [<Rn>, +/-<Rm>{, <shift>}]{!}
// ldrb<c> <Rt>, [<Rn>], +-<Rm>{, <shift>}
//
// cccc011pu0w1nnnnttttiiiiiss0mmmm where cccc=Cond, tttt=Rt, U=1 if +, pu0b
// is a BlockAddr, and pu0w0nnnn0000iiiiiss0mmmm=Address.
constexpr bool IsByte = false;
emitMemOp(Cond, IsLoad, IsByte, Rt, OpAddress, TInfo, LdrName);
return;
}
}
}
void AssemblerARM32::emitMemExOp(CondARM32::Cond Cond, Type Ty, bool IsLoad,
const Operand *OpRd, IValueT Rt,
const Operand *OpAddress,
const TargetInfo &TInfo,
const char *InstName) {
IValueT Rd = encodeGPRegister(OpRd, "Rd", InstName);
IValueT MemExOpcode = IsLoad ? B0 : 0;
switch (Ty) {
default:
llvm::report_fatal_error(std::string(InstName) + ": Type " +
typeString(Ty) + " not allowed");
case IceType_i1:
case IceType_i8:
MemExOpcode |= B2;
break;
case IceType_i16:
MemExOpcode |= B2 | B1;
break;
case IceType_i32:
break;
case IceType_i64:
MemExOpcode |= B1;
}
IValueT AddressRn;
if (encodeAddress(OpAddress, AddressRn, TInfo, NoImmOffsetAddress) !=
EncodedAsImmRegOffset)
llvm::report_fatal_error(std::string(InstName) +
": Can't extract Rn from address");
assert(Utils::IsAbsoluteUint(3, MemExOpcode));
assert(Rd < RegARM32::getNumGPRegs());
assert(Rt < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
IValueT Encoding = (Cond << kConditionShift) | B24 | B23 | B11 | B10 | B9 |
B8 | B7 | B4 | (MemExOpcode << kMemExOpcodeShift) |
AddressRn | (Rd << kRdShift) | (Rt << kRmShift);
emitInst(Encoding);
return;
}
void AssemblerARM32::ldrex(const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// LDREXB - ARM section A8.8.76, encoding A1:
// ldrexb<c> <Rt>, [<Rn>]
//
// cccc00011101nnnntttt111110011111 where cccc=Cond, tttt=Rt, and nnnn=Rn.
//
// LDREXH - ARM section A8.8.78, encoding A1:
// ldrexh<c> <Rt>, [<Rn>]
//
// cccc00011111nnnntttt111110011111 where cccc=Cond, tttt=Rt, and nnnn=Rn.
//
// LDREX - ARM section A8.8.75, encoding A1:
// ldrex<c> <Rt>, [<Rn>]
//
// cccc00011001nnnntttt111110011111 where cccc=Cond, tttt=Rt, and nnnn=Rn.
//
// LDREXD - ARM section A8.
// ldrexd<c> <Rt>, [<Rn>]
//
// cccc00011001nnnntttt111110011111 where cccc=Cond, tttt=Rt, and nnnn=Rn.
constexpr const char *LdrexName = "ldrex";
const Type Ty = OpRt->getType();
constexpr bool IsLoad = true;
constexpr IValueT Rm = RegARM32::Encoded_Reg_pc;
emitMemExOp(Cond, Ty, IsLoad, OpRt, Rm, OpAddress, TInfo, LdrexName);
}
void AssemblerARM32::emitShift(const CondARM32::Cond Cond,
const OperandARM32::ShiftKind Shift,
const Operand *OpRd, const Operand *OpRm,
const Operand *OpSrc1, const bool SetFlags,
const char *InstName) {
constexpr IValueT ShiftOpcode = B3 | B2 | B0; // 1101
IValueT Rd = encodeGPRegister(OpRd, "Rd", InstName);
IValueT Rm = encodeGPRegister(OpRm, "Rm", InstName);
IValueT Value;
switch (encodeOperand(OpSrc1, Value, WantGPRegs)) {
default:
llvm::report_fatal_error(std::string(InstName) +
": Last operand not understood");
case EncodedAsShiftImm5: {
// XXX (immediate)
// xxx{s}<c> <Rd>, <Rm>, #imm5
//
// cccc0001101s0000ddddiiiii000mmmm where cccc=Cond, s=SetFlags, dddd=Rd,
// iiiii=imm5, and mmmm=Rm.
constexpr IValueT Rn = 0; // Rn field is not used.
Value = Value | (Rm << kRmShift) | (Shift << kShiftShift);
emitType01(Cond, kInstTypeDataRegShift, ShiftOpcode, SetFlags, Rn, Rd,
Value, RdIsPcAndSetFlags, InstName);
return;
}
case EncodedAsRegister: {
// XXX (register)
// xxx{S}<c> <Rd>, <Rm>, <Rs>
//
// cccc0001101s0000ddddssss0001mmmm where cccc=Cond, s=SetFlags, dddd=Rd,
// mmmm=Rm, and ssss=Rs.
constexpr IValueT Rn = 0; // Rn field is not used.
IValueT Rs = encodeGPRegister(OpSrc1, "Rs", InstName);
verifyRegNotPc(Rd, "Rd", InstName);
verifyRegNotPc(Rm, "Rm", InstName);
verifyRegNotPc(Rs, "Rs", InstName);
emitType01(Cond, kInstTypeDataRegShift, ShiftOpcode, SetFlags, Rn, Rd,
encodeShiftRotateReg(Rm, Shift, Rs), NoChecks, InstName);
return;
}
}
}
void AssemblerARM32::asr(const Operand *OpRd, const Operand *OpRm,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
constexpr const char *AsrName = "asr";
emitShift(Cond, OperandARM32::ASR, OpRd, OpRm, OpSrc1, SetFlags, AsrName);
}
void AssemblerARM32::lsl(const Operand *OpRd, const Operand *OpRm,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
constexpr const char *LslName = "lsl";
emitShift(Cond, OperandARM32::LSL, OpRd, OpRm, OpSrc1, SetFlags, LslName);
}
void AssemblerARM32::lsr(const Operand *OpRd, const Operand *OpRm,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
constexpr const char *LsrName = "lsr";
emitShift(Cond, OperandARM32::LSR, OpRd, OpRm, OpSrc1, SetFlags, LsrName);
}
void AssemblerARM32::mov(const Operand *OpRd, const Operand *OpSrc,
CondARM32::Cond Cond) {
// MOV (register) - ARM section A8.8.104, encoding A1:
// mov{S}<c> <Rd>, <Rn>
//
// cccc0001101s0000dddd00000000mmmm where cccc=Cond, s=SetFlags, dddd=Rd,
// and nnnn=Rn.
//
// MOV (immediate) - ARM section A8.8.102, encoding A1:
// mov{S}<c> <Rd>, #<RotatedImm8>
//
// cccc0011101s0000ddddiiiiiiiiiiii where cccc=Cond, s=SetFlags, dddd=Rd,
// and iiiiiiiiiiii=RotatedImm8=Src. Note: We don't use movs in this
// assembler.
constexpr const char *MovName = "mov";
IValueT Rd = encodeGPRegister(OpRd, "Rd", MovName);
constexpr bool SetFlags = false;
constexpr IValueT Rn = 0;
constexpr IValueT MovOpcode = B3 | B2 | B0; // 1101.
emitType01(Cond, MovOpcode, Rd, Rn, OpSrc, SetFlags, RdIsPcAndSetFlags,
MovName);
}
void AssemblerARM32::emitMovwt(CondARM32::Cond Cond, bool IsMovW,
const Operand *OpRd, const Operand *OpSrc,
const char *MovName) {
IValueT Opcode = B25 | B24 | (IsMovW ? 0 : B22);
IValueT Rd = encodeGPRegister(OpRd, "Rd", MovName);
IValueT Imm16;
if (const auto *Src = llvm::dyn_cast<ConstantRelocatable>(OpSrc)) {
emitFixup(createMoveFixup(IsMovW, Src));
// Use 0 for the lower 16 bits of the relocatable, and add a fixup to
// install the correct bits.
Imm16 = 0;
} else if (encodeOperand(OpSrc, Imm16, WantGPRegs) != EncodedAsConstI32) {
llvm::report_fatal_error(std::string(MovName) + ": Not i32 constant");
}
assert(CondARM32::isDefined(Cond));
if (!Utils::IsAbsoluteUint(16, Imm16))
llvm::report_fatal_error(std::string(MovName) + ": Constant not i16");
const IValueT Encoding = encodeCondition(Cond) << kConditionShift | Opcode |
((Imm16 >> 12) << 16) | Rd << kRdShift |
(Imm16 & 0xfff);
emitInst(Encoding);
}
void AssemblerARM32::movw(const Operand *OpRd, const Operand *OpSrc,
CondARM32::Cond Cond) {
// MOV (immediate) - ARM section A8.8.102, encoding A2:
// movw<c> <Rd>, #<imm16>
//
// cccc00110000iiiiddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, and
// iiiiiiiiiiiiiiii=imm16.
constexpr const char *MovwName = "movw";
constexpr bool IsMovW = true;
emitMovwt(Cond, IsMovW, OpRd, OpSrc, MovwName);
}
void AssemblerARM32::movt(const Operand *OpRd, const Operand *OpSrc,
CondARM32::Cond Cond) {
// MOVT - ARM section A8.8.106, encoding A1:
// movt<c> <Rd>, #<imm16>
//
// cccc00110100iiiiddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, and
// iiiiiiiiiiiiiiii=imm16.
constexpr const char *MovtName = "movt";
constexpr bool IsMovW = false;
emitMovwt(Cond, IsMovW, OpRd, OpSrc, MovtName);
}
void AssemblerARM32::mvn(const Operand *OpRd, const Operand *OpSrc,
CondARM32::Cond Cond) {
// MVN (immediate) - ARM section A8.8.115, encoding A1:
// mvn{s}<c> <Rd>, #<const>
//
// cccc0011111s0000ddddiiiiiiiiiiii where cccc=Cond, s=SetFlags=0, dddd=Rd,
// and iiiiiiiiiiii=const
//
// MVN (register) - ARM section A8.8.116, encoding A1:
// mvn{s}<c> <Rd>, <Rm>{, <shift>
//
// cccc0001111s0000ddddiiiiitt0mmmm where cccc=Cond, s=SetFlags=0, dddd=Rd,
// mmmm=Rm, iiii defines shift constant, and tt=ShiftKind.
constexpr const char *MvnName = "mvn";
IValueT Rd = encodeGPRegister(OpRd, "Rd", MvnName);
constexpr IValueT MvnOpcode = B3 | B2 | B1 | B0; // i.e. 1111
constexpr IValueT Rn = 0;
constexpr bool SetFlags = false;
emitType01(Cond, MvnOpcode, Rd, Rn, OpSrc, SetFlags, RdIsPcAndSetFlags,
MvnName);
}
void AssemblerARM32::nop() {
// NOP - Section A8.8.119, encoding A1:
// nop<c>
//
// cccc0011001000001111000000000000 where cccc=Cond.
constexpr CondARM32::Cond Cond = CondARM32::AL;
const IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | B25 |
B24 | B21 | B15 | B14 | B13 | B12;
emitInst(Encoding);
}
void AssemblerARM32::sbc(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// SBC (register) - ARM section 18.8.162, encoding A1:
// sbc{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
//
// cccc0000110snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=Shift, tt=ShiftKind, and s=SetFlags.
//
// SBC (Immediate) - ARM section A8.8.161, encoding A1:
// sbc{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0010110snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *SbcName = "sbc";
constexpr IValueT SbcOpcode = B2 | B1; // 0110
emitType01(Cond, SbcOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
SbcName);
}
void AssemblerARM32::sdiv(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, CondARM32::Cond Cond) {
// SDIV - ARM section A8.8.165, encoding A1.
// sdiv<c> <Rd>, <Rn>, <Rm>
//
// cccc01110001dddd1111mmmm0001nnnn where cccc=Cond, dddd=Rd, nnnn=Rn, and
// mmmm=Rm.
constexpr const char *SdivName = "sdiv";
IValueT Rd = encodeGPRegister(OpRd, "Rd", SdivName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", SdivName);
IValueT Rm = encodeGPRegister(OpSrc1, "Rm", SdivName);
verifyRegNotPc(Rd, "Rd", SdivName);
verifyRegNotPc(Rn, "Rn", SdivName);
verifyRegNotPc(Rm, "Rm", SdivName);
// Assembler registers rd, rn, rm are encoded as rn, rm, rs.
constexpr IValueT SdivOpcode = 0;
emitDivOp(Cond, SdivOpcode, Rd, Rn, Rm);
}
void AssemblerARM32::str(const Operand *OpRt, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
constexpr const char *StrName = "str";
constexpr bool IsLoad = false;
IValueT Rt = encodeGPRegister(OpRt, "Rt", StrName);
const Type Ty = OpRt->getType();
switch (Ty) {
case IceType_i64:
// STRD is not implemented because target lowering handles i64 and double by
// using two (32-bit) store instructions. Note: Intentionally drop to
// default case.
llvm::report_fatal_error(std::string(StrName) + ": Type " + typeString(Ty) +
" not implemented");
default:
llvm::report_fatal_error(std::string(StrName) + ": Type " + typeString(Ty) +
" not allowed");
case IceType_i1:
case IceType_i8: {
// STRB (immediate) - ARM section A8.8.207, encoding A1:
// strb<c> <Rt>, [<Rn>{, #+/-<imm12>}] ; p=1, w=0
// strb<c> <Rt>, [<Rn>], #+/-<imm12> ; p=1, w=1
// strb<c> <Rt>, [<Rn>, #+/-<imm12>]! ; p=0, w=1
//
// cccc010pu1w0nnnnttttiiiiiiiiiiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiiiiiii=imm12, u=1 if +.
constexpr bool IsByte = true;
emitMemOp(Cond, IsLoad, IsByte, Rt, OpAddress, TInfo, StrName);
return;
}
case IceType_i16: {
// STRH (immediate) - ARM section A8.*.217, encoding A1:
// strh<c> <Rt>, [<Rn>{, #+/-<Imm8>}]
// strh<c> <Rt>, [<Rn>], #+/-<Imm8>
// strh<c> <Rt>, [<Rn>, #+/-<Imm8>]!
//
// cccc000pu1w0nnnnttttiiii1011iiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiii=Imm8, u=1 if +, pu0w is a BlockAddr, and
// pu0w0nnnn0000iiiiiiiiiiii=Address.
constexpr const char *Strh = "strh";
emitMemOpEnc3(Cond, B7 | B5 | B4, Rt, OpAddress, TInfo, Strh);
return;
}
case IceType_i32: {
// Note: Handles i32 and float stores. Target lowering handles i64 and
// double by using two (32 bit) store instructions.
//
// STR (immediate) - ARM section A8.8.207, encoding A1:
// str<c> <Rt>, [<Rn>{, #+/-<imm12>}] ; p=1, w=0
// str<c> <Rt>, [<Rn>], #+/-<imm12> ; p=1, w=1
// str<c> <Rt>, [<Rn>, #+/-<imm12>]! ; p=0, w=1
//
// cccc010pu1w0nnnnttttiiiiiiiiiiii where cccc=Cond, tttt=Rt, nnnn=Rn,
// iiiiiiiiiiii=imm12, u=1 if +.
constexpr bool IsByte = false;
emitMemOp(Cond, IsLoad, IsByte, Rt, OpAddress, TInfo, StrName);
return;
}
}
}
void AssemblerARM32::strex(const Operand *OpRd, const Operand *OpRt,
const Operand *OpAddress, CondARM32::Cond Cond,
const TargetInfo &TInfo) {
// STREXB - ARM section A8.8.213, encoding A1:
// strexb<c> <Rd>, <Rt>, [<Rn>]
//
// cccc00011100nnnndddd11111001tttt where cccc=Cond, dddd=Rd, tttt=Rt, and
// nnnn=Rn.
//
// STREXH - ARM section A8.8.215, encoding A1:
// strexh<c> <Rd>, <Rt>, [<Rn>]
//
// cccc00011110nnnndddd11111001tttt where cccc=Cond, dddd=Rd, tttt=Rt, and
// nnnn=Rn.
//
// STREX - ARM section A8.8.212, encoding A1:
// strex<c> <Rd>, <Rt>, [<Rn>]
//
// cccc00011000nnnndddd11111001tttt where cccc=Cond, dddd=Rd, tttt=Rt, and
// nnnn=Rn.
//
// STREXD - ARM section A8.8.214, encoding A1:
// strexd<c> <Rd>, <Rt>, [<Rn>]
//
// cccc00011010nnnndddd11111001tttt where cccc=Cond, dddd=Rd, tttt=Rt, and
// nnnn=Rn.
constexpr const char *StrexName = "strex";
// Note: Rt uses Rm shift in encoding.
IValueT Rt = encodeGPRegister(OpRt, "Rt", StrexName);
const Type Ty = OpRt->getType();
constexpr bool IsLoad = true;
emitMemExOp(Cond, Ty, !IsLoad, OpRd, Rt, OpAddress, TInfo, StrexName);
}
void AssemblerARM32::orr(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// ORR (register) - ARM Section A8.8.123, encoding A1:
// orr{s}<c> <Rd>, <Rn>, <Rm>
//
// cccc0001100snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=shift, tt=ShiftKind,, and s=SetFlags.
//
// ORR (register) - ARM Section A8.8.123, encoding A1:
// orr{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0001100snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8.
constexpr const char *OrrName = "orr";
constexpr IValueT OrrOpcode = B3 | B2; // i.e. 1100
emitType01(Cond, OrrOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
OrrName);
}
void AssemblerARM32::pop(const Variable *OpRt, CondARM32::Cond Cond) {
// POP - ARM section A8.8.132, encoding A2:
// pop<c> {Rt}
//
// cccc010010011101dddd000000000100 where dddd=Rt and cccc=Cond.
constexpr const char *Pop = "pop";
IValueT Rt = encodeGPRegister(OpRt, "Rt", Pop);
verifyRegsNotEq(Rt, "Rt", RegARM32::Encoded_Reg_sp, "sp", Pop);
// Same as load instruction.
constexpr bool IsLoad = true;
constexpr bool IsByte = false;
constexpr IOffsetT MaxOffset = (1 << 8) - 1;
constexpr IValueT NoShiftRight = 0;
IValueT Address =
encodeImmRegOffset(RegARM32::Encoded_Reg_sp, kWordSize,
OperandARM32Mem::PostIndex, MaxOffset, NoShiftRight);
emitMemOp(Cond, kInstTypeMemImmediate, IsLoad, IsByte, Rt, Address);
}
void AssemblerARM32::popList(const IValueT Registers, CondARM32::Cond Cond) {
// POP - ARM section A8.*.131, encoding A1:
// pop<c> <registers>
//
// cccc100010111101rrrrrrrrrrrrrrrr where cccc=Cond and
// rrrrrrrrrrrrrrrr=Registers (one bit for each GP register).
constexpr bool IsLoad = true;
emitMultiMemOp(Cond, IA_W, IsLoad, RegARM32::Encoded_Reg_sp, Registers);
}
void AssemblerARM32::push(const Operand *OpRt, CondARM32::Cond Cond) {
// PUSH - ARM section A8.8.133, encoding A2:
// push<c> {Rt}
//
// cccc010100101101dddd000000000100 where dddd=Rt and cccc=Cond.
constexpr const char *Push = "push";
IValueT Rt = encodeGPRegister(OpRt, "Rt", Push);
verifyRegsNotEq(Rt, "Rt", RegARM32::Encoded_Reg_sp, "sp", Push);
// Same as store instruction.
constexpr bool isLoad = false;
constexpr bool isByte = false;
constexpr IOffsetT MaxOffset = (1 << 8) - 1;
constexpr IValueT NoShiftRight = 0;
IValueT Address =
encodeImmRegOffset(RegARM32::Encoded_Reg_sp, -kWordSize,
OperandARM32Mem::PreIndex, MaxOffset, NoShiftRight);
emitMemOp(Cond, kInstTypeMemImmediate, isLoad, isByte, Rt, Address);
}
void AssemblerARM32::pushList(const IValueT Registers, CondARM32::Cond Cond) {
// PUSH - ARM section A8.8.133, encoding A1:
// push<c> <Registers>
//
// cccc100100101101rrrrrrrrrrrrrrrr where cccc=Cond and
// rrrrrrrrrrrrrrrr=Registers (one bit for each GP register).
constexpr bool IsLoad = false;
emitMultiMemOp(Cond, DB_W, IsLoad, RegARM32::Encoded_Reg_sp, Registers);
}
void AssemblerARM32::mla(const Operand *OpRd, const Operand *OpRn,
const Operand *OpRm, const Operand *OpRa,
CondARM32::Cond Cond) {
// MLA - ARM section A8.8.114, encoding A1.
// mla{s}<c> <Rd>, <Rn>, <Rm>, <Ra>
//
// cccc0000001sddddaaaammmm1001nnnn where cccc=Cond, s=SetFlags, dddd=Rd,
// aaaa=Ra, mmmm=Rm, and nnnn=Rn.
constexpr const char *MlaName = "mla";
IValueT Rd = encodeGPRegister(OpRd, "Rd", MlaName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", MlaName);
IValueT Rm = encodeGPRegister(OpRm, "Rm", MlaName);
IValueT Ra = encodeGPRegister(OpRa, "Ra", MlaName);
verifyRegNotPc(Rd, "Rd", MlaName);
verifyRegNotPc(Rn, "Rn", MlaName);
verifyRegNotPc(Rm, "Rm", MlaName);
verifyRegNotPc(Ra, "Ra", MlaName);
constexpr IValueT MlaOpcode = B21;
constexpr bool SetFlags = true;
// Assembler registers rd, rn, rm, ra are encoded as rn, rm, rs, rd.
emitMulOp(Cond, MlaOpcode, Ra, Rd, Rn, Rm, !SetFlags);
}
void AssemblerARM32::mls(const Operand *OpRd, const Operand *OpRn,
const Operand *OpRm, const Operand *OpRa,
CondARM32::Cond Cond) {
constexpr const char *MlsName = "mls";
IValueT Rd = encodeGPRegister(OpRd, "Rd", MlsName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", MlsName);
IValueT Rm = encodeGPRegister(OpRm, "Rm", MlsName);
IValueT Ra = encodeGPRegister(OpRa, "Ra", MlsName);
verifyRegNotPc(Rd, "Rd", MlsName);
verifyRegNotPc(Rn, "Rn", MlsName);
verifyRegNotPc(Rm, "Rm", MlsName);
verifyRegNotPc(Ra, "Ra", MlsName);
constexpr IValueT MlsOpcode = B22 | B21;
constexpr bool SetFlags = true;
// Assembler registers rd, rn, rm, ra are encoded as rn, rm, rs, rd.
emitMulOp(Cond, MlsOpcode, Ra, Rd, Rn, Rm, !SetFlags);
}
void AssemblerARM32::mul(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// MUL - ARM section A8.8.114, encoding A1.
// mul{s}<c> <Rd>, <Rn>, <Rm>
//
// cccc0000000sdddd0000mmmm1001nnnn where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, and s=SetFlags.
constexpr const char *MulName = "mul";
IValueT Rd = encodeGPRegister(OpRd, "Rd", MulName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", MulName);
IValueT Rm = encodeGPRegister(OpSrc1, "Rm", MulName);
verifyRegNotPc(Rd, "Rd", MulName);
verifyRegNotPc(Rn, "Rn", MulName);
verifyRegNotPc(Rm, "Rm", MulName);
// Assembler registers rd, rn, rm are encoded as rn, rm, rs.
constexpr IValueT MulOpcode = 0;
emitMulOp(Cond, MulOpcode, RegARM32::Encoded_Reg_r0, Rd, Rn, Rm, SetFlags);
}
void AssemblerARM32::emitRdRm(CondARM32::Cond Cond, IValueT Opcode,
const Operand *OpRd, const Operand *OpRm,
const char *InstName) {
IValueT Rd = encodeGPRegister(OpRd, "Rd", InstName);
IValueT Rm = encodeGPRegister(OpRm, "Rm", InstName);
IValueT Encoding =
(Cond << kConditionShift) | Opcode | (Rd << kRdShift) | (Rm << kRmShift);
emitInst(Encoding);
}
void AssemblerARM32::rbit(const Operand *OpRd, const Operand *OpRm,
CondARM32::Cond Cond) {
// RBIT - ARM section A8.8.144, encoding A1:
// rbit<c> <Rd>, <Rm>
//
// cccc011011111111dddd11110011mmmm where cccc=Cond, dddd=Rn, and mmmm=Rm.
constexpr const char *RbitName = "rev";
constexpr IValueT RbitOpcode = B26 | B25 | B23 | B22 | B21 | B20 | B19 | B18 |
B17 | B16 | B11 | B10 | B9 | B8 | B5 | B4;
emitRdRm(Cond, RbitOpcode, OpRd, OpRm, RbitName);
}
void AssemblerARM32::rev(const Operand *OpRd, const Operand *OpRm,
CondARM32::Cond Cond) {
// REV - ARM section A8.8.145, encoding A1:
// rev<c> <Rd>, <Rm>
//
// cccc011010111111dddd11110011mmmm where cccc=Cond, dddd=Rn, and mmmm=Rm.
constexpr const char *RevName = "rev";
constexpr IValueT RevOpcode = B26 | B25 | B23 | B21 | B20 | B19 | B18 | B17 |
B16 | B11 | B10 | B9 | B8 | B5 | B4;
emitRdRm(Cond, RevOpcode, OpRd, OpRm, RevName);
}
void AssemblerARM32::rsb(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// RSB (immediate) - ARM section A8.8.152, encoding A1.
// rsb{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0010011snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=setFlags and iiiiiiiiiiii defines the RotatedImm8 value.
//
// RSB (register) - ARM section A8.8.163, encoding A1.
// rsb{s}<c> <Rd>, <Rn>, <Rm>{, <Shift>}
//
// cccc0000011snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=shift, tt==ShiftKind, and s=SetFlags.
constexpr const char *RsbName = "rsb";
constexpr IValueT RsbOpcode = B1 | B0; // 0011
emitType01(Cond, RsbOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
RsbName);
}
void AssemblerARM32::rsc(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// RSC (immediate) - ARM section A8.8.155, encoding A1:
// rsc{s}<c> <Rd>, <Rn>, #<RotatedImm8>
//
// cccc0010111snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=shift, tt=ShiftKind, and s=SetFlags.
//
// RSC (register) - ARM section A8.8.156, encoding A1:
// rsc{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
//
// cccc0000111snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=shift, tt=ShiftKind, and s=SetFlags.
//
// RSC (register-shifted register) - ARM section A8.8.157, encoding A1:
// rsc{s}<c> <Rd>, <Rn>, <Rm>, <type> <Rs>
//
// cccc0000111fnnnnddddssss0tt1mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, ssss=Rs, tt defined <type>, and f=SetFlags.
constexpr const char *RscName = "rsc";
constexpr IValueT RscOpcode = B2 | B1 | B0; // i.e. 0111.
emitType01(Cond, RscOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
RscName);
}
void AssemblerARM32::sxt(const Operand *OpRd, const Operand *OpSrc0,
CondARM32::Cond Cond) {
constexpr const char *SxtName = "sxt";
constexpr IValueT SxtOpcode = B26 | B25 | B23 | B21;
emitSignExtend(Cond, SxtOpcode, OpRd, OpSrc0, SxtName);
}
void AssemblerARM32::sub(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, bool SetFlags,
CondARM32::Cond Cond) {
// SUB (register) - ARM section A8.8.223, encoding A1:
// sub{s}<c> <Rd>, <Rn>, <Rm>{, <shift>}
// SUB (SP minus register): See ARM section 8.8.226, encoding A1:
// sub{s}<c> <Rd>, sp, <Rm>{, <Shift>}
//
// cccc0000010snnnnddddiiiiitt0mmmm where cccc=Cond, dddd=Rd, nnnn=Rn,
// mmmm=Rm, iiiii=shift, tt=ShiftKind, and s=SetFlags.
//
// Sub (Immediate) - ARM section A8.8.222, encoding A1:
// sub{s}<c> <Rd>, <Rn>, #<RotatedImm8>
// Sub (Sp minus immediate) - ARM section A8.8.225, encoding A1:
// sub{s}<c> sp, <Rn>, #<RotatedImm8>
//
// cccc0010010snnnnddddiiiiiiiiiiii where cccc=Cond, dddd=Rd, nnnn=Rn,
// s=SetFlags and iiiiiiiiiiii=Src1Value defining RotatedImm8
constexpr const char *SubName = "sub";
constexpr IValueT SubOpcode = B1; // 0010
emitType01(Cond, SubOpcode, OpRd, OpRn, OpSrc1, SetFlags, RdIsPcAndSetFlags,
SubName);
}
namespace {
// Use a particular UDF encoding -- TRAPNaCl in LLVM: 0xE7FEDEF0
// http://llvm.org/viewvc/llvm-project?view=revision&revision=173943
const uint8_t TrapBytesRaw[] = {0xE7, 0xFE, 0xDE, 0xF0};
const auto TrapBytes =
llvm::ArrayRef<uint8_t>(TrapBytesRaw, llvm::array_lengthof(TrapBytesRaw));
} // end of anonymous namespace
llvm::ArrayRef<uint8_t> AssemblerARM32::getNonExecBundlePadding() const {
return TrapBytes;
}
void AssemblerARM32::trap() {
AssemblerBuffer::EnsureCapacity ensured(&Buffer);
for (const uint8_t &Byte : reverse_range(TrapBytes))
Buffer.emit<uint8_t>(Byte);
}
void AssemblerARM32::tst(const Operand *OpRn, const Operand *OpSrc1,
CondARM32::Cond Cond) {
// TST (register) - ARM section A8.8.241, encoding A1:
// tst<c> <Rn>, <Rm>(, <shift>}
//
// cccc00010001nnnn0000iiiiitt0mmmm where cccc=Cond, nnnn=Rn, mmmm=Rm,
// iiiii=Shift, and tt=ShiftKind.
//
// TST (immediate) - ARM section A8.8.240, encoding A1:
// tst<c> <Rn>, #<RotatedImm8>
//
// cccc00110001nnnn0000iiiiiiiiiiii where cccc=Cond, nnnn=Rn, and
// iiiiiiiiiiii defines RotatedImm8.
constexpr const char *TstName = "tst";
constexpr IValueT TstOpcode = B3; // ie. 1000
emitCompareOp(Cond, TstOpcode, OpRn, OpSrc1, TstName);
}
void AssemblerARM32::udiv(const Operand *OpRd, const Operand *OpRn,
const Operand *OpSrc1, CondARM32::Cond Cond) {
// UDIV - ARM section A8.8.248, encoding A1.
// udiv<c> <Rd>, <Rn>, <Rm>
//
// cccc01110011dddd1111mmmm0001nnnn where cccc=Cond, dddd=Rd, nnnn=Rn, and
// mmmm=Rm.
constexpr const char *UdivName = "udiv";
IValueT Rd = encodeGPRegister(OpRd, "Rd", UdivName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", UdivName);
IValueT Rm = encodeGPRegister(OpSrc1, "Rm", UdivName);
verifyRegNotPc(Rd, "Rd", UdivName);
verifyRegNotPc(Rn, "Rn", UdivName);
verifyRegNotPc(Rm, "Rm", UdivName);
// Assembler registers rd, rn, rm are encoded as rn, rm, rs.
constexpr IValueT UdivOpcode = B21;
emitDivOp(Cond, UdivOpcode, Rd, Rn, Rm);
}
void AssemblerARM32::umull(const Operand *OpRdLo, const Operand *OpRdHi,
const Operand *OpRn, const Operand *OpRm,
CondARM32::Cond Cond) {
// UMULL - ARM section A8.8.257, encoding A1:
// umull<c> <RdLo>, <RdHi>, <Rn>, <Rm>
//
// cccc0000100shhhhllllmmmm1001nnnn where hhhh=RdHi, llll=RdLo, nnnn=Rn,
// mmmm=Rm, and s=SetFlags
constexpr const char *UmullName = "umull";
IValueT RdLo = encodeGPRegister(OpRdLo, "RdLo", UmullName);
IValueT RdHi = encodeGPRegister(OpRdHi, "RdHi", UmullName);
IValueT Rn = encodeGPRegister(OpRn, "Rn", UmullName);
IValueT Rm = encodeGPRegister(OpRm, "Rm", UmullName);
verifyRegNotPc(RdLo, "RdLo", UmullName);
verifyRegNotPc(RdHi, "RdHi", UmullName);
verifyRegNotPc(Rn, "Rn", UmullName);
verifyRegNotPc(Rm, "Rm", UmullName);
verifyRegsNotEq(RdHi, "RdHi", RdLo, "RdLo", UmullName);
constexpr IValueT UmullOpcode = B23;
constexpr bool SetFlags = false;
emitMulOp(Cond, UmullOpcode, RdLo, RdHi, Rn, Rm, SetFlags);
}
void AssemblerARM32::uxt(const Operand *OpRd, const Operand *OpSrc0,
CondARM32::Cond Cond) {
constexpr const char *UxtName = "uxt";
constexpr IValueT UxtOpcode = B26 | B25 | B23 | B22 | B21;
emitSignExtend(Cond, UxtOpcode, OpRd, OpSrc0, UxtName);
}
void AssemblerARM32::vabss(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VABS - ARM section A8.8.280, encoding A2:
// vabs<c>.f32 <Sd>, <Sm>
//
// cccc11101D110000dddd101011M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vabss = "vabss";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vabss);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vabss);
constexpr IValueT S0 = 0;
constexpr IValueT VabssOpcode = B23 | B21 | B20 | B7 | B6;
emitVFPsss(Cond, VabssOpcode, Sd, S0, Sm);
}
void AssemblerARM32::vabsd(const Operand *OpDd, const Operand *OpDm,
CondARM32::Cond Cond) {
// VABS - ARM section A8.8.280, encoding A2:
// vabs<c>.f64 <Dd>, <Dm>
//
// cccc11101D110000dddd101111M0mmmm where cccc=Cond, Ddddd=Dd, and Mmmmm=Dm.
constexpr const char *Vabsd = "vabsd";
const IValueT Dd = encodeDRegister(OpDd, "Dd", Vabsd);
const IValueT Dm = encodeDRegister(OpDm, "Dm", Vabsd);
constexpr IValueT D0 = 0;
constexpr IValueT VabsdOpcode = B23 | B21 | B20 | B7 | B6;
emitVFPddd(Cond, VabsdOpcode, Dd, D0, Dm);
}
void AssemblerARM32::vabsq(const Operand *OpQd, const Operand *OpQm) {
// VABS - ARM section A8.8.280, encoding A1:
// vabs.<dt> <Qd>, <Qm>
//
// 111100111D11ss01ddd0f1101M0mmm0 where Dddd=OpQd, Mddd=OpQm, and
// <dt> in {s8, s16, s32, f32} and ss is the encoding of <dt>.
const Type ElmtTy = typeElementType(OpQd->getType());
assert(ElmtTy != IceType_i64 && "vabsq doesn't allow i64!");
constexpr const char *Vabsq = "vabsq";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vabsq));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vabsq));
constexpr IValueT Dn = 0;
const IValueT VabsqOpcode =
B24 | B23 | B21 | B20 | B16 | B9 | B8 | (encodeElmtType(ElmtTy) << 18);
constexpr bool UseQRegs = true;
emitSIMDBase(VabsqOpcode, Dd, Dn, Dm, UseQRegs, isFloatingType(ElmtTy));
}
void AssemblerARM32::vadds(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VADD (floating-point) - ARM section A8.8.283, encoding A2:
// vadd<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11100D11nnnndddd101sN0M0mmmm where cccc=Cond, s=0, ddddD=Rd, nnnnN=Rn,
// and mmmmM=Rm.
constexpr const char *Vadds = "vadds";
constexpr IValueT VaddsOpcode = B21 | B20;
emitVFPsss(Cond, VaddsOpcode, OpSd, OpSn, OpSm, Vadds);
}
void AssemblerARM32::vaddqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VADD (integer) - ARM section A8.8.282, encoding A1:
// vadd.<dt> <Qd>, <Qn>, <Qm>
//
// 111100100Dssnnn0ddd01000N1M0mmm0 where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// and dt in [i8, i16, i32, i64] where ss is the index.
assert(isScalarIntegerType(ElmtTy) &&
"vaddqi expects vector with integer element type");
constexpr const char *Vaddqi = "vaddqi";
constexpr IValueT VaddqiOpcode = B11;
emitSIMDqqq(VaddqiOpcode, ElmtTy, OpQd, OpQm, OpQn, Vaddqi);
}
void AssemblerARM32::vaddqf(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// VADD (floating-point) - ARM section A8.8.283, Encoding A1:
// vadd.f32 <Qd>, <Qn>, <Qm>
//
// 111100100D00nnn0ddd01101N1M0mmm0 where Dddd=Qd, Nnnn=Qn, and Mmmm=Qm.
assert(OpQd->getType() == IceType_v4f32 && "vaddqf expects type <4 x float>");
constexpr const char *Vaddqf = "vaddqf";
constexpr IValueT VaddqfOpcode = B11 | B8;
constexpr bool IsFloatTy = true;
emitSIMDqqqBase(VaddqfOpcode, OpQd, OpQn, OpQm, IsFloatTy, Vaddqf);
}
void AssemblerARM32::vaddd(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VADD (floating-point) - ARM section A8.8.283, encoding A2:
// vadd<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11100D11nnnndddd101sN0M0mmmm where cccc=Cond, s=1, Ddddd=Rd, Nnnnn=Rn,
// and Mmmmm=Rm.
constexpr const char *Vaddd = "vaddd";
constexpr IValueT VadddOpcode = B21 | B20;
emitVFPddd(Cond, VadddOpcode, OpDd, OpDn, OpDm, Vaddd);
}
void AssemblerARM32::vandq(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// VAND (register) - ARM section A8.8.287, encoding A1:
// vand <Qd>, <Qn>, <Qm>
//
// 111100100D00nnn0ddd00001N1M1mmm0 where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vandq = "vandq";
constexpr IValueT VandqOpcode = B8 | B4;
constexpr Type ElmtTy = IceType_i8;
emitSIMDqqq(VandqOpcode, ElmtTy, OpQd, OpQm, OpQn, Vandq);
}
void AssemblerARM32::vbslq(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// VBSL (register) - ARM section A8.8.290, encoding A1:
// vbsl <Qd>, <Qn>, <Qm>
//
// 111100110D01nnn0ddd00001N1M1mmm0 where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vbslq = "vbslq";
constexpr IValueT VbslqOpcode = B24 | B20 | B8 | B4;
constexpr Type ElmtTy = IceType_i8; // emits sz=0
emitSIMDqqq(VbslqOpcode, ElmtTy, OpQd, OpQm, OpQn, Vbslq);
}
void AssemblerARM32::vceqqi(const Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// vceq (register) - ARM section A8.8.291, encoding A1:
// vceq.<st> <Qd>, <Qn>, <Qm>
//
// 111100110Dssnnnndddd1000NQM1mmmm where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm, and
// st in [i8, i16, i32] where ss is the index.
constexpr const char *Vceq = "vceq";
constexpr IValueT VceqOpcode = B24 | B11 | B4;
emitSIMDqqq(VceqOpcode, ElmtTy, OpQd, OpQm, OpQn, Vceq);
}
void AssemblerARM32::vceqqs(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// vceq (register) - ARM section A8.8.291, encoding A2:
// vceq.f32 <Qd>, <Qn>, <Qm>
//
// 111100100D00nnnndddd1110NQM0mmmm where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vceq = "vceq";
constexpr IValueT VceqOpcode = B11 | B10 | B9;
constexpr Type ElmtTy = IceType_i8; // encoded as 0b00
emitSIMDqqq(VceqOpcode, ElmtTy, OpQd, OpQm, OpQn, Vceq);
}
void AssemblerARM32::vcgeqi(const Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// vcge (register) - ARM section A8.8.293, encoding A1:
// vcge.<st> <Qd>, <Qn>, <Qm>
//
// 1111001U0Dssnnnndddd0011NQM1mmmm where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// 0=U, and st in [s8, s16, s32] where ss is the index.
constexpr const char *Vcge = "vcge";
constexpr IValueT VcgeOpcode = B9 | B8 | B4;
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcugeqi(const Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// vcge (register) - ARM section A8.8.293, encoding A1:
// vcge.<st> <Qd>, <Qn>, <Qm>
//
// 1111001U0Dssnnnndddd0011NQM1mmmm where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// 1=U, and st in [u8, u16, u32] where ss is the index.
constexpr const char *Vcge = "vcge";
constexpr IValueT VcgeOpcode = B24 | B9 | B8 | B4;
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcgeqs(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// vcge (register) - ARM section A8.8.293, encoding A2:
// vcge.f32 <Qd>, <Qn>, <Qm>
//
// 111100110D00nnnndddd1110NQM0mmmm where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vcge = "vcge";
constexpr IValueT VcgeOpcode = B24 | B11 | B10 | B9;
constexpr Type ElmtTy = IceType_i8; // encoded as 0b00.
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcgtqi(const Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// vcgt (register) - ARM section A8.8.295, encoding A1:
// vcgt.<st> <Qd>, <Qn>, <Qm>
//
// 1111001U0Dssnnnndddd0011NQM0mmmm where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// 0=U, and st in [s8, s16, s32] where ss is the index.
constexpr const char *Vcge = "vcgt";
constexpr IValueT VcgeOpcode = B9 | B8;
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcugtqi(const Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// vcgt (register) - ARM section A8.8.295, encoding A1:
// vcgt.<st> <Qd>, <Qn>, <Qm>
//
// 111100110Dssnnnndddd0011NQM0mmmm where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// 1=U, and st in [u8, u16, u32] where ss is the index.
constexpr const char *Vcge = "vcgt";
constexpr IValueT VcgeOpcode = B24 | B9 | B8;
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcgtqs(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// vcgt (register) - ARM section A8.8.295, encoding A2:
// vcgt.f32 <Qd>, <Qn>, <Qm>
//
// 111100110D10nnnndddd1110NQM0mmmm where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vcge = "vcgt";
constexpr IValueT VcgeOpcode = B24 | B21 | B11 | B10 | B9;
constexpr Type ElmtTy = IceType_i8; // encoded as 0b00.
emitSIMDqqq(VcgeOpcode, ElmtTy, OpQd, OpQm, OpQn, Vcge);
}
void AssemblerARM32::vcmpd(const Operand *OpDd, const Operand *OpDm,
CondARM32::Cond Cond) {
constexpr const char *Vcmpd = "vcmpd";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vcmpd);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vcmpd);
constexpr IValueT VcmpdOpcode = B23 | B21 | B20 | B18 | B6;
constexpr IValueT Dn = 0;
emitVFPddd(Cond, VcmpdOpcode, Dd, Dn, Dm);
}
void AssemblerARM32::vcmpdz(const Operand *OpDd, CondARM32::Cond Cond) {
constexpr const char *Vcmpdz = "vcmpdz";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vcmpdz);
constexpr IValueT VcmpdzOpcode = B23 | B21 | B20 | B18 | B16 | B6;
constexpr IValueT Dn = 0;
constexpr IValueT Dm = 0;
emitVFPddd(Cond, VcmpdzOpcode, Dd, Dn, Dm);
}
void AssemblerARM32::vcmps(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
constexpr const char *Vcmps = "vcmps";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcmps);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcmps);
constexpr IValueT VcmpsOpcode = B23 | B21 | B20 | B18 | B6;
constexpr IValueT Sn = 0;
emitVFPsss(Cond, VcmpsOpcode, Sd, Sn, Sm);
}
void AssemblerARM32::vcmpsz(const Operand *OpSd, CondARM32::Cond Cond) {
constexpr const char *Vcmpsz = "vcmps";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcmpsz);
constexpr IValueT VcmpszOpcode = B23 | B21 | B20 | B18 | B16 | B6;
constexpr IValueT Sn = 0;
constexpr IValueT Sm = 0;
emitVFPsss(Cond, VcmpszOpcode, Sd, Sn, Sm);
}
void AssemblerARM32::emitVFPsd(CondARM32::Cond Cond, IValueT Opcode, IValueT Sd,
IValueT Dm) {
assert(Sd < RegARM32::getNumSRegs());
assert(Dm < RegARM32::getNumDRegs());
assert(CondARM32::isDefined(Cond));
constexpr IValueT VFPOpcode = B27 | B26 | B25 | B11 | B9;
const IValueT Encoding =
Opcode | VFPOpcode | (encodeCondition(Cond) << kConditionShift) |
(getYInRegXXXXY(Sd) << 22) | (getXXXXInRegXXXXY(Sd) << 12) |
(getYInRegYXXXX(Dm) << 5) | getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::vcvtdi(const Operand *OpDd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.f64.s32 <Dd>, <Sm>
//
// cccc11101D111000dddd10111M0mmmm where cccc=Cond, Ddddd=Dd, and mmmmM=Sm.
constexpr const char *Vcvtdi = "vcvtdi";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vcvtdi);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtdi);
constexpr IValueT VcvtdiOpcode = B23 | B21 | B20 | B19 | B8 | B7 | B6;
emitVFPds(Cond, VcvtdiOpcode, Dd, Sm);
}
void AssemblerARM32::vcvtdu(const Operand *OpDd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.f64.u32 <Dd>, <Sm>
//
// cccc11101D111000dddd10101M0mmmm where cccc=Cond, Ddddd=Dd, and mmmmM=Sm.
constexpr const char *Vcvtdu = "vcvtdu";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vcvtdu);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtdu);
constexpr IValueT VcvtduOpcode = B23 | B21 | B20 | B19 | B8 | B6;
emitVFPds(Cond, VcvtduOpcode, Dd, Sm);
}
void AssemblerARM32::vcvtsd(const Operand *OpSd, const Operand *OpDm,
CondARM32::Cond Cond) {
constexpr const char *Vcvtsd = "vcvtsd";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtsd);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vcvtsd);
constexpr IValueT VcvtsdOpcode =
B23 | B21 | B20 | B18 | B17 | B16 | B8 | B7 | B6;
emitVFPsd(Cond, VcvtsdOpcode, Sd, Dm);
}
void AssemblerARM32::vcvtis(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.s32.f32 <Sd>, <Sm>
//
// cccc11101D111101dddd10011M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vcvtis = "vcvtis";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtis);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtis);
constexpr IValueT VcvtisOpcode = B23 | B21 | B20 | B19 | B18 | B16 | B7 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VcvtisOpcode, Sd, S0, Sm);
}
void AssemblerARM32::vcvtid(const Operand *OpSd, const Operand *OpDm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.s32.f64 <Sd>, <Dm>
//
// cccc11101D111101dddd10111M0mmmm where cccc=Cond, ddddD=Sd, and Mmmmm=Dm.
constexpr const char *Vcvtid = "vcvtid";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtid);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vcvtid);
constexpr IValueT VcvtidOpcode =
B23 | B21 | B20 | B19 | B18 | B16 | B8 | B7 | B6;
emitVFPsd(Cond, VcvtidOpcode, Sd, Dm);
}
void AssemblerARM32::vcvtsi(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.f32.s32 <Sd>, <Sm>
//
// cccc11101D111000dddd10011M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vcvtsi = "vcvtsi";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtsi);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtsi);
constexpr IValueT VcvtsiOpcode = B23 | B21 | B20 | B19 | B7 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VcvtsiOpcode, Sd, S0, Sm);
}
void AssemblerARM32::vcvtsu(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.f32.u32 <Sd>, <Sm>
//
// cccc11101D111000dddd10001M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vcvtsu = "vcvtsu";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtsu);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtsu);
constexpr IValueT VcvtsuOpcode = B23 | B21 | B20 | B19 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VcvtsuOpcode, Sd, S0, Sm);
}
void AssemblerARM32::vcvtud(const Operand *OpSd, const Operand *OpDm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.u32.f64 <Sd>, <Dm>
//
// cccc11101D111100dddd10111M0mmmm where cccc=Cond, ddddD=Sd, and Mmmmm=Dm.
constexpr const char *Vcvtud = "vcvtud";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtud);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vcvtud);
constexpr IValueT VcvtudOpcode = B23 | B21 | B20 | B19 | B18 | B8 | B7 | B6;
emitVFPsd(Cond, VcvtudOpcode, Sd, Dm);
}
void AssemblerARM32::vcvtus(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VCVT (between floating-point and integer, Floating-point)
// - ARM Section A8.8.306, encoding A1:
// vcvt<c>.u32.f32 <Sd>, <Sm>
//
// cccc11101D111100dddd10011M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vcvtus = "vcvtus";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vcvtus);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtus);
constexpr IValueT VcvtsiOpcode = B23 | B21 | B20 | B19 | B18 | B7 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VcvtsiOpcode, Sd, S0, Sm);
}
void AssemblerARM32::vcvtqsi(const Operand *OpQd, const Operand *OpQm) {
// VCVT (between floating-point and integer, Advanced SIMD)
// - ARM Section A8.8.305, encoding A1:
// vcvt<c>.f32.s32 <Qd>, <Qm>
//
// 111100111D11ss11dddd011ooQM0mmmm where Ddddd=Qd, Mmmmm=Qm, and 10=op.
constexpr const char *Vcvtqsi = "vcvt.s32.f32";
constexpr IValueT VcvtqsiOpcode = B8;
emitSIMDCvtqq(VcvtqsiOpcode, OpQd, OpQm, Vcvtqsi);
}
void AssemblerARM32::vcvtqsu(const Operand *OpQd, const Operand *OpQm) {
// VCVT (between floating-point and integer, Advanced SIMD)
// - ARM Section A8.8.305, encoding A1:
// vcvt<c>.f32.u32 <Qd>, <Qm>
//
// 111100111D11ss11dddd011ooQM0mmmm where Ddddd=Qd, Mmmmm=Qm, and 11=op.
constexpr const char *Vcvtqsu = "vcvt.u32.f32";
constexpr IValueT VcvtqsuOpcode = B8 | B7;
emitSIMDCvtqq(VcvtqsuOpcode, OpQd, OpQm, Vcvtqsu);
}
void AssemblerARM32::vcvtqis(const Operand *OpQd, const Operand *OpQm) {
// VCVT (between floating-point and integer, Advanced SIMD)
// - ARM Section A8.8.305, encoding A1:
// vcvt<c>.f32.s32 <Qd>, <Qm>
//
// 111100111D11ss11dddd011ooQM0mmmm where Ddddd=Qd, Mmmmm=Qm, and 01=op.
constexpr const char *Vcvtqis = "vcvt.f32.s32";
constexpr IValueT VcvtqisOpcode = 0;
emitSIMDCvtqq(VcvtqisOpcode, OpQd, OpQm, Vcvtqis);
}
void AssemblerARM32::vcvtqus(const Operand *OpQd, const Operand *OpQm) {
// VCVT (between floating-point and integer, Advanced SIMD)
// - ARM Section A8.8.305, encoding A1:
// vcvt<c>.f32.u32 <Qd>, <Qm>
//
// 111100111D11ss11dddd011ooQM0mmmm where Ddddd=Qd, Mmmmm=Qm, and 01=op.
constexpr const char *Vcvtqus = "vcvt.f32.u32";
constexpr IValueT VcvtqusOpcode = B7;
emitSIMDCvtqq(VcvtqusOpcode, OpQd, OpQm, Vcvtqus);
}
void AssemblerARM32::emitVFPds(CondARM32::Cond Cond, IValueT Opcode, IValueT Dd,
IValueT Sm) {
assert(Dd < RegARM32::getNumDRegs());
assert(Sm < RegARM32::getNumSRegs());
assert(CondARM32::isDefined(Cond));
constexpr IValueT VFPOpcode = B27 | B26 | B25 | B11 | B9;
const IValueT Encoding =
Opcode | VFPOpcode | (encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (getXXXXInRegYXXXX(Dd) << 12) |
(getYInRegXXXXY(Sm) << 5) | getXXXXInRegXXXXY(Sm);
emitInst(Encoding);
}
void AssemblerARM32::vcvtds(const Operand *OpDd, const Operand *OpSm,
CondARM32::Cond Cond) {
constexpr const char *Vcvtds = "Vctds";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vcvtds);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vcvtds);
constexpr IValueT VcvtdsOpcode = B23 | B21 | B20 | B18 | B17 | B16 | B7 | B6;
emitVFPds(Cond, VcvtdsOpcode, Dd, Sm);
}
void AssemblerARM32::vdivs(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VDIV (floating-point) - ARM section A8.8.283, encoding A2:
// vdiv<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11101D00nnnndddd101sN0M0mmmm where cccc=Cond, s=0, ddddD=Rd, nnnnN=Rn,
// and mmmmM=Rm.
constexpr const char *Vdivs = "vdivs";
constexpr IValueT VdivsOpcode = B23;
emitVFPsss(Cond, VdivsOpcode, OpSd, OpSn, OpSm, Vdivs);
}
void AssemblerARM32::vdivd(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VDIV (floating-point) - ARM section A8.8.283, encoding A2:
// vdiv<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11101D00nnnndddd101sN0M0mmmm where cccc=Cond, s=1, Ddddd=Rd, Nnnnn=Rn,
// and Mmmmm=Rm.
constexpr const char *Vdivd = "vdivd";
constexpr IValueT VdivdOpcode = B23;
emitVFPddd(Cond, VdivdOpcode, OpDd, OpDn, OpDm, Vdivd);
}
void AssemblerARM32::veord(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm) {
// VEOR - ARM secdtion A8.8.315, encoding A1:
// veor<c> <Dd>, <Dn>, <Dm>
//
// 111100110D00nnnndddd0001N0M1mmmm where Ddddd=Dd, Nnnnn=Dn, and Mmmmm=Dm.
constexpr const char *Veord = "veord";
IValueT Dd = encodeDRegister(OpDd, "Dd", Veord);
IValueT Dn = encodeDRegister(OpDn, "Dn", Veord);
IValueT Dm = encodeDRegister(OpDm, "Dm", Veord);
const IValueT Encoding =
B25 | B24 | B8 | B4 |
(encodeCondition(CondARM32::Cond::kNone) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (getXXXXInRegYXXXX(Dn) << 16) |
(getXXXXInRegYXXXX(Dd) << 12) | (getYInRegYXXXX(Dn) << 7) |
(getYInRegYXXXX(Dm) << 5) | getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::veorq(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// VEOR - ARM section A8.8.316, encoding A1:
// veor <Qd>, <Qn>, <Qm>
//
// 111100110D00nnn0ddd00001N1M1mmm0 where Dddd=Qd, Nnnn=Qn, and Mmmm=Qm.
constexpr const char *Veorq = "veorq";
constexpr IValueT VeorqOpcode = B24 | B8 | B4;
emitSIMDqqq(VeorqOpcode, IceType_i8, OpQd, OpQn, OpQm, Veorq);
}
void AssemblerARM32::vldrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// VLDR - ARM section A8.8.333, encoding A1.
// vldr<c> <Dd>, [<Rn>{, #+/-<imm>}]
//
// cccc1101UD01nnnndddd1011iiiiiiii where cccc=Cond, nnnn=Rn, Ddddd=Rd,
// iiiiiiii=abs(Imm >> 2), and U=1 if Opcode>=0.
constexpr const char *Vldrd = "vldrd";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vldrd);
assert(CondARM32::isDefined(Cond));
IValueT Address;
EncodedOperand AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding = B27 | B26 | B24 | B20 | B11 | B9 | B8 |
(encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) |
(getXXXXInRegYXXXX(Dd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::vldrq(const Operand *OpQd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// This is a pseudo-instruction which loads 64-bit data into a quadword
// vector register. It is implemented by loading into the lower doubleword.
// VLDR - ARM section A8.8.333, encoding A1.
// vldr<c> <Dd>, [<Rn>{, #+/-<imm>}]
//
// cccc1101UD01nnnndddd1011iiiiiiii where cccc=Cond, nnnn=Rn, Ddddd=Rd,
// iiiiiiii=abs(Imm >> 2), and U=1 if Opcode>=0.
constexpr const char *Vldrd = "vldrd";
IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vldrd));
assert(CondARM32::isDefined(Cond));
IValueT Address;
EncodedOperand AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding = B27 | B26 | B24 | B20 | B11 | B9 | B8 |
(encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) |
(getXXXXInRegYXXXX(Dd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::vldrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// VDLR - ARM section A8.8.333, encoding A2.
// vldr<c> <Sd>, [<Rn>{, #+/-<imm>]]
//
// cccc1101UD01nnnndddd1010iiiiiiii where cccc=Cond, nnnn=Rn, ddddD=Sd,
// iiiiiiii=abs(Opcode), and U=1 if Opcode >= 0;
constexpr const char *Vldrs = "vldrs";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vldrs);
assert(CondARM32::isDefined(Cond));
IValueT Address;
EncodedOperand AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding = B27 | B26 | B24 | B20 | B11 | B9 |
(encodeCondition(Cond) << kConditionShift) |
(getYInRegXXXXY(Sd) << 22) |
(getXXXXInRegXXXXY(Sd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::emitVMem1Op(IValueT Opcode, IValueT Dd, IValueT Rn,
IValueT Rm, DRegListSize NumDRegs,
size_t ElmtSize, IValueT Align,
const char *InstName) {
assert(Utils::IsAbsoluteUint(2, Align));
IValueT EncodedElmtSize;
switch (ElmtSize) {
default: {
std::string Buffer;
llvm::raw_string_ostream StrBuf(Buffer);
StrBuf << InstName << ": found invalid vector element size " << ElmtSize;
llvm::report_fatal_error(StrBuf.str());
}
case 8:
EncodedElmtSize = 0;
break;
case 16:
EncodedElmtSize = 1;
break;
case 32:
EncodedElmtSize = 2;
break;
case 64:
EncodedElmtSize = 3;
}
const IValueT Encoding =
Opcode | (encodeCondition(CondARM32::kNone) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (Rn << kRnShift) |
(getXXXXInRegYXXXX(Dd) << kRdShift) | (NumDRegs << 8) |
(EncodedElmtSize << 6) | (Align << 4) | Rm;
emitInst(Encoding);
}
void AssemblerARM32::emitVMem1Op(IValueT Opcode, IValueT Dd, IValueT Rn,
IValueT Rm, size_t ElmtSize, IValueT Align,
const char *InstName) {
assert(Utils::IsAbsoluteUint(2, Align));
IValueT EncodedElmtSize;
switch (ElmtSize) {
default: {
std::string Buffer;
llvm::raw_string_ostream StrBuf(Buffer);
StrBuf << InstName << ": found invalid vector element size " << ElmtSize;
llvm::report_fatal_error(StrBuf.str());
}
case 8:
EncodedElmtSize = 0;
break;
case 16:
EncodedElmtSize = 1;
break;
case 32:
EncodedElmtSize = 2;
break;
case 64:
EncodedElmtSize = 3;
}
const IValueT Encoding =
Opcode | (encodeCondition(CondARM32::kNone) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) | (Rn << kRnShift) |
(getXXXXInRegYXXXX(Dd) << kRdShift) | (EncodedElmtSize << 10) |
(Align << 4) | Rm;
emitInst(Encoding);
}
void AssemblerARM32::vld1qr(size_t ElmtSize, const Operand *OpQd,
const Operand *OpAddress, const TargetInfo &TInfo) {
// VLD1 (multiple single elements) - ARM section A8.8.320, encoding A1:
// vld1.<size> <Qd>, [<Rn>]
//
// 111101000D10nnnnddd0ttttssaammmm where tttt=DRegListSize2, Dddd=Qd,
// nnnn=Rn, aa=0 (use default alignment), size=ElmtSize, and ss is the
// encoding of ElmtSize.
constexpr const char *Vld1qr = "vld1qr";
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vld1qr);
const IValueT Dd = mapQRegToDReg(Qd);
IValueT Address;
if (encodeAddress(OpAddress, Address, TInfo, NoImmOffsetAddress) !=
EncodedAsImmRegOffset)
llvm::report_fatal_error(std::string(Vld1qr) + ": malform memory address");
const IValueT Rn = mask(Address, kRnShift, 4);
constexpr IValueT Rm = RegARM32::Reg_pc;
constexpr IValueT Opcode = B26 | B21;
constexpr IValueT Align = 0; // use default alignment.
emitVMem1Op(Opcode, Dd, Rn, Rm, DRegListSize2, ElmtSize, Align, Vld1qr);
}
void AssemblerARM32::vld1(size_t ElmtSize, const Operand *OpQd,
const Operand *OpAddress, const TargetInfo &TInfo) {
// This is a pseudo-instruction for loading a single element of a quadword
// vector. For 64-bit the lower doubleword vector is loaded.
if (ElmtSize == 64) {
return vldrq(OpQd, OpAddress, Ice::CondARM32::AL, TInfo);
}
// VLD1 (single elements to one lane) - ARMv7-A/R section A8.6.308, encoding
// A1:
// VLD1<c>.<size> <list>, [<Rn>{@<align>}], <Rm>
//
// 111101001D10nnnnddddss00aaaammmm where tttt=DRegListSize2, Dddd=Qd,
// nnnn=Rn, aa=0 (use default alignment), size=ElmtSize, and ss is the
// encoding of ElmtSize.
constexpr const char *Vld1qr = "vld1qr";
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vld1qr);
const IValueT Dd = mapQRegToDReg(Qd);
IValueT Address;
if (encodeAddress(OpAddress, Address, TInfo, NoImmOffsetAddress) !=
EncodedAsImmRegOffset)
llvm::report_fatal_error(std::string(Vld1qr) + ": malform memory address");
const IValueT Rn = mask(Address, kRnShift, 4);
constexpr IValueT Rm = RegARM32::Reg_pc;
constexpr IValueT Opcode = B26 | B23 | B21;
constexpr IValueT Align = 0; // use default alignment.
emitVMem1Op(Opcode, Dd, Rn, Rm, ElmtSize, Align, Vld1qr);
}
bool AssemblerARM32::vmovqc(const Operand *OpQd, const ConstantInteger32 *Imm) {
// VMOV (immediate) - ARM section A8.8.320, encoding A1:
// VMOV.<dt> <Qd>, #<Imm>
// 1111001x1D000yyyddddcccc01p1zzzz where Qd=Ddddd, Imm=xyyyzzzz, cmode=cccc,
// and Op=p.
constexpr const char *Vmovc = "vmovc";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmovc));
IValueT Value = Imm->getValue();
const Type VecTy = OpQd->getType();
if (!isVectorType(VecTy))
return false;
IValueT Op;
IValueT Cmode;
IValueT Imm8;
if (!encodeAdvSIMDExpandImm(Value, typeElementType(VecTy), Op, Cmode, Imm8))
return false;
if (Op == 0 && mask(Cmode, 0, 1) == 1)
return false;
if (Op == 1 && Cmode != 13)
return false;
const IValueT Encoding =
(0xF << kConditionShift) | B25 | B23 | B6 | B4 |
(mask(Imm8, 7, 1) << 24) | (getYInRegYXXXX(Dd) << 22) |
(mask(Imm8, 4, 3) << 16) | (getXXXXInRegYXXXX(Dd) << 12) | (Cmode << 8) |
(Op << 5) | mask(Imm8, 0, 4);
emitInst(Encoding);
return true;
}
void AssemblerARM32::vmovd(const Operand *OpDd,
const OperandARM32FlexFpImm *OpFpImm,
CondARM32::Cond Cond) {
// VMOV (immediate) - ARM section A8.8.339, encoding A2:
// vmov<c>.f64 <Dd>, #<imm>
//
// cccc11101D11xxxxdddd10110000yyyy where cccc=Cond, ddddD=Sn, xxxxyyyy=imm.
constexpr const char *Vmovd = "vmovd";
IValueT Dd = encodeSRegister(OpDd, "Dd", Vmovd);
IValueT Imm8 = OpFpImm->getModifiedImm();
assert(Imm8 < (1 << 8));
constexpr IValueT VmovsOpcode = B23 | B21 | B20 | B8;
IValueT OpcodePlusImm8 = VmovsOpcode | ((Imm8 >> 4) << 16) | (Imm8 & 0xf);
constexpr IValueT D0 = 0;
emitVFPddd(Cond, OpcodePlusImm8, Dd, D0, D0);
}
void AssemblerARM32::vmovdd(const Operand *OpDd, const Variable *OpDm,
CondARM32::Cond Cond) {
// VMOV (register) - ARM section A8.8.340, encoding A2:
// vmov<c>.f64 <Dd>, <Sm>
//
// cccc11101D110000dddd101101M0mmmm where cccc=Cond, Ddddd=Sd, and Mmmmm=Sm.
constexpr const char *Vmovdd = "Vmovdd";
IValueT Dd = encodeSRegister(OpDd, "Dd", Vmovdd);
IValueT Dm = encodeSRegister(OpDm, "Dm", Vmovdd);
constexpr IValueT VmovddOpcode = B23 | B21 | B20 | B6;
constexpr IValueT D0 = 0;
emitVFPddd(Cond, VmovddOpcode, Dd, D0, Dm);
}
void AssemblerARM32::vmovdrr(const Operand *OpDm, const Operand *OpRt,
const Operand *OpRt2, CondARM32::Cond Cond) {
// VMOV (between two ARM core registers and a doubleword extension register).
// ARM section A8.8.345, encoding A1:
// vmov<c> <Dm>, <Rt>, <Rt2>
//
// cccc11000100xxxxyyyy101100M1mmmm where cccc=Cond, xxxx=Rt, yyyy=Rt2, and
// Mmmmm=Dm.
constexpr const char *Vmovdrr = "vmovdrr";
IValueT Dm = encodeDRegister(OpDm, "Dm", Vmovdrr);
IValueT Rt = encodeGPRegister(OpRt, "Rt", Vmovdrr);
IValueT Rt2 = encodeGPRegister(OpRt2, "Rt", Vmovdrr);
assert(Rt != RegARM32::Encoded_Reg_sp);
assert(Rt != RegARM32::Encoded_Reg_pc);
assert(Rt2 != RegARM32::Encoded_Reg_sp);
assert(Rt2 != RegARM32::Encoded_Reg_pc);
assert(Rt != Rt2);
assert(CondARM32::isDefined(Cond));
IValueT Encoding = B27 | B26 | B22 | B11 | B9 | B8 | B4 |
(encodeCondition(Cond) << kConditionShift) | (Rt2 << 16) |
(Rt << 12) | (getYInRegYXXXX(Dm) << 5) |
getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::vmovqir(const Operand *OpQn, uint32_t Index,
const Operand *OpRt, CondARM32::Cond Cond) {
// VMOV (ARM core register to scalar) - ARM section A8.8.341, encoding A1:
// vmov<c>.<size> <Dn[x]>, <Rt>
constexpr const char *Vmovdr = "vmovdr";
constexpr bool IsExtract = true;
emitInsertExtractInt(Cond, OpQn, Index, OpRt, !IsExtract, Vmovdr);
}
void AssemblerARM32::vmovqis(const Operand *OpQd, uint32_t Index,
const Operand *OpSm, CondARM32::Cond Cond) {
constexpr const char *Vmovqis = "vmovqis";
assert(Index < 4);
IValueT Sd = mapQRegToSReg(encodeQRegister(OpQd, "Qd", Vmovqis)) + Index;
IValueT Sm = encodeSRegister(OpSm, "Sm", Vmovqis);
emitMoveSS(Cond, Sd, Sm);
}
void AssemblerARM32::vmovrqi(const Operand *OpRt, const Operand *OpQn,
uint32_t Index, CondARM32::Cond Cond) {
// VMOV (scalar to ARM core register) - ARM section A8.8.342, encoding A1:
// vmov<c>.<dt> <Rt>, <Dn[x]>
constexpr const char *Vmovrd = "vmovrd";
constexpr bool IsExtract = true;
emitInsertExtractInt(Cond, OpQn, Index, OpRt, IsExtract, Vmovrd);
}
void AssemblerARM32::vmovrrd(const Operand *OpRt, const Operand *OpRt2,
const Operand *OpDm, CondARM32::Cond Cond) {
// VMOV (between two ARM core registers and a doubleword extension register).
// ARM section A8.8.345, encoding A1:
// vmov<c> <Rt>, <Rt2>, <Dm>
//
// cccc11000101xxxxyyyy101100M1mmmm where cccc=Cond, xxxx=Rt, yyyy=Rt2, and
// Mmmmm=Dm.
constexpr const char *Vmovrrd = "vmovrrd";
IValueT Rt = encodeGPRegister(OpRt, "Rt", Vmovrrd);
IValueT Rt2 = encodeGPRegister(OpRt2, "Rt", Vmovrrd);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vmovrrd);
assert(Rt != RegARM32::Encoded_Reg_sp);
assert(Rt != RegARM32::Encoded_Reg_pc);
assert(Rt2 != RegARM32::Encoded_Reg_sp);
assert(Rt2 != RegARM32::Encoded_Reg_pc);
assert(Rt != Rt2);
assert(CondARM32::isDefined(Cond));
IValueT Encoding = B27 | B26 | B22 | B20 | B11 | B9 | B8 | B4 |
(encodeCondition(Cond) << kConditionShift) | (Rt2 << 16) |
(Rt << 12) | (getYInRegYXXXX(Dm) << 5) |
getXXXXInRegYXXXX(Dm);
emitInst(Encoding);
}
void AssemblerARM32::vmovrs(const Operand *OpRt, const Operand *OpSn,
CondARM32::Cond Cond) {
// VMOV (between ARM core register and single-precision register)
// ARM section A8.8.343, encoding A1.
//
// vmov<c> <Rt>, <Sn>
//
// cccc11100001nnnntttt1010N0010000 where cccc=Cond, nnnnN = Sn, and tttt=Rt.
constexpr const char *Vmovrs = "vmovrs";
IValueT Rt = encodeGPRegister(OpRt, "Rt", Vmovrs);
IValueT Sn = encodeSRegister(OpSn, "Sn", Vmovrs);
assert(CondARM32::isDefined(Cond));
IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | B27 | B26 |
B25 | B20 | B11 | B9 | B4 | (getXXXXInRegXXXXY(Sn) << 16) |
(Rt << kRdShift) | (getYInRegXXXXY(Sn) << 7);
emitInst(Encoding);
}
void AssemblerARM32::vmovs(const Operand *OpSd,
const OperandARM32FlexFpImm *OpFpImm,
CondARM32::Cond Cond) {
// VMOV (immediate) - ARM section A8.8.339, encoding A2:
// vmov<c>.f32 <Sd>, #<imm>
//
// cccc11101D11xxxxdddd10100000yyyy where cccc=Cond, ddddD=Sn, xxxxyyyy=imm.
constexpr const char *Vmovs = "vmovs";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vmovs);
IValueT Imm8 = OpFpImm->getModifiedImm();
assert(Imm8 < (1 << 8));
constexpr IValueT VmovsOpcode = B23 | B21 | B20;
IValueT OpcodePlusImm8 = VmovsOpcode | ((Imm8 >> 4) << 16) | (Imm8 & 0xf);
constexpr IValueT S0 = 0;
emitVFPsss(Cond, OpcodePlusImm8, Sd, S0, S0);
}
void AssemblerARM32::vmovss(const Operand *OpSd, const Variable *OpSm,
CondARM32::Cond Cond) {
constexpr const char *Vmovss = "Vmovss";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vmovss);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vmovss);
emitMoveSS(Cond, Sd, Sm);
}
void AssemblerARM32::vmovsqi(const Operand *OpSd, const Operand *OpQm,
uint32_t Index, CondARM32::Cond Cond) {
constexpr const char *Vmovsqi = "vmovsqi";
const IValueT Sd = encodeSRegister(OpSd, "Sd", Vmovsqi);
assert(Index < 4);
const IValueT Sm =
mapQRegToSReg(encodeQRegister(OpQm, "Qm", Vmovsqi)) + Index;
emitMoveSS(Cond, Sd, Sm);
}
void AssemblerARM32::vmovsr(const Operand *OpSn, const Operand *OpRt,
CondARM32::Cond Cond) {
// VMOV (between ARM core register and single-precision register)
// ARM section A8.8.343, encoding A1.
//
// vmov<c> <Sn>, <Rt>
//
// cccc11100000nnnntttt1010N0010000 where cccc=Cond, nnnnN = Sn, and tttt=Rt.
constexpr const char *Vmovsr = "vmovsr";
IValueT Sn = encodeSRegister(OpSn, "Sn", Vmovsr);
IValueT Rt = encodeGPRegister(OpRt, "Rt", Vmovsr);
assert(Sn < RegARM32::getNumSRegs());
assert(Rt < RegARM32::getNumGPRegs());
assert(CondARM32::isDefined(Cond));
IValueT Encoding = (encodeCondition(Cond) << kConditionShift) | B27 | B26 |
B25 | B11 | B9 | B4 | (getXXXXInRegXXXXY(Sn) << 16) |
(Rt << kRdShift) | (getYInRegXXXXY(Sn) << 7);
emitInst(Encoding);
}
void AssemblerARM32::vmlad(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VMLA, VMLS (floating-point), ARM section A8.8.337, encoding A2:
// vmla<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11100d00nnnndddd1011n0M0mmmm where cccc=Cond, Ddddd=Dd, Nnnnn=Dn, and
// Mmmmm=Dm
constexpr const char *Vmlad = "vmlad";
constexpr IValueT VmladOpcode = 0;
emitVFPddd(Cond, VmladOpcode, OpDd, OpDn, OpDm, Vmlad);
}
void AssemblerARM32::vmlas(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VMLA, VMLS (floating-point), ARM section A8.8.337, encoding A2:
// vmla<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11100d00nnnndddd1010n0M0mmmm where cccc=Cond, ddddD=Sd, nnnnN=Sn, and
// mmmmM=Sm
constexpr const char *Vmlas = "vmlas";
constexpr IValueT VmlasOpcode = 0;
emitVFPsss(Cond, VmlasOpcode, OpSd, OpSn, OpSm, Vmlas);
}
void AssemblerARM32::vmlsd(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VMLA, VMLS (floating-point), ARM section A8.8.337, encoding A2:
// vmls<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11100d00nnnndddd1011n1M0mmmm where cccc=Cond, Ddddd=Dd, Nnnnn=Dn, and
// Mmmmm=Dm
constexpr const char *Vmlad = "vmlad";
constexpr IValueT VmladOpcode = B6;
emitVFPddd(Cond, VmladOpcode, OpDd, OpDn, OpDm, Vmlad);
}
void AssemblerARM32::vmlss(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VMLA, VMLS (floating-point), ARM section A8.8.337, encoding A2:
// vmls<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11100d00nnnndddd1010n1M0mmmm where cccc=Cond, ddddD=Sd, nnnnN=Sn, and
// mmmmM=Sm
constexpr const char *Vmlas = "vmlas";
constexpr IValueT VmlasOpcode = B6;
emitVFPsss(Cond, VmlasOpcode, OpSd, OpSn, OpSm, Vmlas);
}
void AssemblerARM32::vmrsAPSR_nzcv(CondARM32::Cond Cond) {
// MVRS - ARM section A*.8.348, encoding A1:
// vmrs<c> APSR_nzcv, FPSCR
//
// cccc111011110001tttt101000010000 where tttt=0x15 (i.e. when Rt=pc, use
// APSR_nzcv instead).
assert(CondARM32::isDefined(Cond));
IValueT Encoding = B27 | B26 | B25 | B23 | B22 | B21 | B20 | B16 | B15 | B14 |
B13 | B12 | B11 | B9 | B4 |
(encodeCondition(Cond) << kConditionShift);
emitInst(Encoding);
}
void AssemblerARM32::vmuls(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VMUL (floating-point) - ARM section A8.8.351, encoding A2:
// vmul<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11100D10nnnndddd101sN0M0mmmm where cccc=Cond, s=0, ddddD=Rd, nnnnN=Rn,
// and mmmmM=Rm.
constexpr const char *Vmuls = "vmuls";
constexpr IValueT VmulsOpcode = B21;
emitVFPsss(Cond, VmulsOpcode, OpSd, OpSn, OpSm, Vmuls);
}
void AssemblerARM32::vmuld(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VMUL (floating-point) - ARM section A8.8.351, encoding A2:
// vmul<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11100D10nnnndddd101sN0M0mmmm where cccc=Cond, s=1, Ddddd=Rd, Nnnnn=Rn,
// and Mmmmm=Rm.
constexpr const char *Vmuld = "vmuld";
constexpr IValueT VmuldOpcode = B21;
emitVFPddd(Cond, VmuldOpcode, OpDd, OpDn, OpDm, Vmuld);
}
void AssemblerARM32::vmulqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQn, const Operand *OpQm) {
// VMUL, VMULL (integer and polynomial) - ARM section A8.8.350, encoding A1:
// vmul<c>.<dt> <Qd>, <Qn>, <Qm>
//
// 111100100Dssnnn0ddd01001NqM1mmm0 where Dddd=Qd, Nnnn=Qn, Mmmm=Qm, and
// dt in [i8, i16, i32] where ss is the index.
assert(isScalarIntegerType(ElmtTy) &&
"vmulqi expects vector with integer element type");
assert(ElmtTy != IceType_i64 && "vmulqi on i64 vector not allowed");
constexpr const char *Vmulqi = "vmulqi";
constexpr IValueT VmulqiOpcode = B11 | B8 | B4;
emitSIMDqqq(VmulqiOpcode, ElmtTy, OpQd, OpQn, OpQm, Vmulqi);
}
void AssemblerARM32::vmulh(Type ElmtTy, const Operand *OpQd,
const Operand *OpQn, const Operand *OpQm,
bool Unsigned) {
// Pseudo-instruction for multiplying the corresponding elements in the lower
// halves of two quadword vectors, and returning the high halves.
// VMULL (integer and polynomial) - ARMv7-A/R section A8.6.337, encoding A1:
// VMUL<c>.<dt> <Dd>, <Dn>, <Dm>
//
// 1111001U1Dssnnnndddd11o0N0M0mmmm
assert(isScalarIntegerType(ElmtTy) &&
"vmull expects vector with integer element type");
assert(ElmtTy != IceType_i64 && "vmull on i64 vector not allowed");
constexpr const char *Vmull = "vmull";
constexpr IValueT ElmtShift = 20;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
const IValueT VmullOpcode =
B25 | (Unsigned ? B24 : 0) | B23 | (B20) | B11 | B10;
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vmull);
const IValueT Qn = encodeQRegister(OpQn, "Qn", Vmull);
const IValueT Qm = encodeQRegister(OpQm, "Qm", Vmull);
const IValueT Dd = mapQRegToDReg(Qd);
const IValueT Dn = mapQRegToDReg(Qn);
const IValueT Dm = mapQRegToDReg(Qm);
constexpr bool UseQRegs = false;
constexpr bool IsFloatTy = false;
emitSIMDBase(VmullOpcode | (ElmtSize << ElmtShift), Dd, Dn, Dm, UseQRegs,
IsFloatTy);
// Shift and narrow to obtain high halves.
constexpr IValueT VshrnOpcode = B25 | B23 | B11 | B4;
const IValueT Imm6 = encodeSIMDShiftImm6(ST_Vshr, IceType_i16, 16);
constexpr IValueT ImmShift = 16;
emitSIMDBase(VshrnOpcode | (Imm6 << ImmShift), Dd, 0, Dd, UseQRegs,
IsFloatTy);
}
void AssemblerARM32::vmlap(Type ElmtTy, const Operand *OpQd,
const Operand *OpQn, const Operand *OpQm) {
// Pseudo-instruction for multiplying the corresponding elements in the lower
// halves of two quadword vectors, and pairwise-adding the results.
// VMULL (integer and polynomial) - ARM section A8.8.350, encoding A1:
// vmull<c>.<dt> <Qd>, <Qn>, <Qm>
//
// 1111001U1Dssnnnndddd11o0N0M0mmmm
assert(isScalarIntegerType(ElmtTy) &&
"vmull expects vector with integer element type");
assert(ElmtTy != IceType_i64 && "vmull on i64 vector not allowed");
constexpr const char *Vmull = "vmull";
constexpr IValueT ElmtShift = 20;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
bool Unsigned = false;
const IValueT VmullOpcode =
B25 | (Unsigned ? B24 : 0) | B23 | (B20) | B11 | B10;
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmull));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vmull));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vmull));
constexpr bool UseQRegs = false;
constexpr bool IsFloatTy = false;
emitSIMDBase(VmullOpcode | (ElmtSize << ElmtShift), Dd, Dn, Dm, UseQRegs,
IsFloatTy);
// VPADD - ARM section A8.8.280, encoding A1:
// vpadd.<dt> <Dd>, <Dm>, <Dn>
//
// 111100100Dssnnnndddd1011NQM1mmmm where Ddddd=<Dd>, Mmmmm=<Dm>, and
// Nnnnn=<Dn> and ss is the encoding of <dt>.
assert(ElmtTy != IceType_i64 && "vpadd doesn't allow i64!");
const IValueT VpaddOpcode =
B25 | B11 | B9 | B8 | B4 | ((encodeElmtType(ElmtTy) + 1) << 20);
emitSIMDBase(VpaddOpcode, Dd, Dd, Dd + 1, UseQRegs, IsFloatTy);
}
void AssemblerARM32::vdup(Type ElmtTy, const Operand *OpQd, const Operand *OpQn,
IValueT Idx) {
// VDUP (scalar) - ARMv7-A/R section A8.6.302, encoding A1:
// VDUP<c>.<size> <Qd>, <Dm[x]>
//
// 111100111D11iiiiddd011000QM0mmmm where Dddd=<Qd>, Mmmmm=<Dm>, and
// iiii=imm4 encodes <size> and [x].
constexpr const char *Vdup = "vdup";
const IValueT VdupOpcode = B25 | B24 | B23 | B21 | B20 | B11 | B10;
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vdup));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vdup));
constexpr bool UseQRegs = true;
constexpr bool IsFloatTy = false;
IValueT Imm4 = 0;
bool Lower = true;
switch (ElmtTy) {
case IceType_i8:
assert(Idx < 16);
Lower = Idx < 8;
Imm4 = 1 | ((Idx & 0x7) << 1);
break;
case IceType_i16:
assert(Idx < 8);
Lower = Idx < 4;
Imm4 = 2 | ((Idx & 0x3) << 2);
break;
case IceType_i32:
case IceType_f32:
assert(Idx < 4);
Lower = Idx < 2;
Imm4 = 4 | ((Idx & 0x1) << 3);
break;
default:
assert(false && "vdup only supports 8, 16, and 32-bit elements");
break;
}
emitSIMDBase(VdupOpcode, Dd, Imm4, Dn + (Lower ? 0 : 1), UseQRegs, IsFloatTy);
}
void AssemblerARM32::vzip(Type ElmtTy, const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// Pseudo-instruction which interleaves the elements of the lower halves of
// two quadword registers.
// Vzip - ARMv7-A/R section A8.6.410, encoding A1:
// VZIP<c>.<size> <Dd>, <Dm>
//
// 111100111D11ss10dddd00011QM0mmmm where Ddddd=<Dd>, Mmmmm=<Dm>, and
// ss=<size>
assert(ElmtTy != IceType_i64 && "vzip on i64 vector not allowed");
constexpr const char *Vzip = "vzip";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vzip));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vzip));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vzip));
constexpr bool UseQRegs = false;
constexpr bool IsFloatTy = false;
// VMOV Dd, Dm
// 111100100D10mmmmdddd0001MQM1mmmm
constexpr IValueT VmovOpcode = B25 | B21 | B8 | B4;
// Copy lower half of second source to upper half of destination.
emitSIMDBase(VmovOpcode, Dd + 1, Dm, Dm, UseQRegs, IsFloatTy);
// Copy lower half of first source to lower half of destination.
if (Dd != Dn)
emitSIMDBase(VmovOpcode, Dd, Dn, Dn, UseQRegs, IsFloatTy);
constexpr IValueT ElmtShift = 18;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
if (ElmtTy != IceType_i32 && ElmtTy != IceType_f32) {
constexpr IValueT VzipOpcode = B25 | B24 | B23 | B21 | B20 | B17 | B8 | B7;
// Zip the lower and upper half of destination.
emitSIMDBase(VzipOpcode | (ElmtSize << ElmtShift), Dd, 0, Dd + 1, UseQRegs,
IsFloatTy);
} else {
constexpr IValueT VtrnOpcode = B25 | B24 | B23 | B21 | B20 | B17 | B7;
emitSIMDBase(VtrnOpcode | (ElmtSize << ElmtShift), Dd, 0, Dd + 1, UseQRegs,
IsFloatTy);
}
}
void AssemblerARM32::vmulqf(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// VMUL (floating-point) - ARM section A8.8.351, encoding A1:
// vmul.f32 <Qd>, <Qn>, <Qm>
//
// 111100110D00nnn0ddd01101MqM1mmm0 where Dddd=Qd, Nnnn=Qn, and Mmmm=Qm.
assert(OpQd->getType() == IceType_v4f32 && "vmulqf expects type <4 x float>");
constexpr const char *Vmulqf = "vmulqf";
constexpr IValueT VmulqfOpcode = B24 | B11 | B8 | B4;
constexpr bool IsFloatTy = true;
emitSIMDqqqBase(VmulqfOpcode, OpQd, OpQn, OpQm, IsFloatTy, Vmulqf);
}
void AssemblerARM32::vmvnq(const Operand *OpQd, const Operand *OpQm) {
// VMVN (integer) - ARM section A8.8.354, encoding A1:
// vmvn <Qd>, <Qm>
//
// 111100111D110000dddd01011QM0mmmm where Dddd=Qd, Mmmm=Qm, and 1=Q.
// TODO(jpp) xxx: unify
constexpr const char *Vmvn = "vmvn";
constexpr IValueT VmvnOpcode = B24 | B23 | B21 | B20 | B10 | B8 | B7;
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vmvn);
constexpr IValueT Qn = 0;
const IValueT Qm = encodeQRegister(OpQm, "Qm", Vmvn);
constexpr bool UseQRegs = true;
constexpr bool IsFloat = false;
emitSIMDBase(VmvnOpcode, mapQRegToDReg(Qd), mapQRegToDReg(Qn),
mapQRegToDReg(Qm), UseQRegs, IsFloat);
}
void AssemblerARM32::vmovlq(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// Pseudo-instruction to copy the first source operand and insert the lower
// half of the second operand into the lower half of the destination.
// VMOV (register) - ARMv7-A/R section A8.6.327, encoding A1:
// VMOV<c> <Dd>, <Dm>
//
// 111100111D110000ddd001011QM0mmm0 where Dddd=Qd, Mmmm=Qm, and Q=0.
constexpr const char *Vmov = "vmov";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmov));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vmov));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vmov));
constexpr bool UseQRegs = false;
constexpr bool IsFloat = false;
const IValueT VmovOpcode = B25 | B21 | B8 | B4;
if (Dd != Dm)
emitSIMDBase(VmovOpcode, Dd, Dm, Dm, UseQRegs, IsFloat);
if (Dd + 1 != Dn + 1)
emitSIMDBase(VmovOpcode, Dd + 1, Dn + 1, Dn + 1, UseQRegs, IsFloat);
}
void AssemblerARM32::vmovhq(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// Pseudo-instruction to copy the first source operand and insert the high
// half of the second operand into the high half of the destination.
// VMOV (register) - ARMv7-A/R section A8.6.327, encoding A1:
// VMOV<c> <Dd>, <Dm>
//
// 111100111D110000ddd001011QM0mmm0 where Dddd=Qd, Mmmm=Qm, and Q=0.
constexpr const char *Vmov = "vmov";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmov));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vmov));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vmov));
constexpr bool UseQRegs = false;
constexpr bool IsFloat = false;
const IValueT VmovOpcode = B25 | B21 | B8 | B4;
if (Dd != Dn)
emitSIMDBase(VmovOpcode, Dd, Dn, Dn, UseQRegs, IsFloat);
if (Dd + 1 != Dm + 1)
emitSIMDBase(VmovOpcode, Dd + 1, Dm + 1, Dm + 1, UseQRegs, IsFloat);
}
void AssemblerARM32::vmovhlq(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// Pseudo-instruction to copy the first source operand and insert the high
// half of the second operand into the lower half of the destination.
// VMOV (register) - ARMv7-A/R section A8.6.327, encoding A1:
// VMOV<c> <Dd>, <Dm>
//
// 111100111D110000ddd001011QM0mmm0 where Dddd=Qd, Mmmm=Qm, and Q=0.
constexpr const char *Vmov = "vmov";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmov));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vmov));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vmov));
constexpr bool UseQRegs = false;
constexpr bool IsFloat = false;
const IValueT VmovOpcode = B25 | B21 | B8 | B4;
if (Dd != Dm + 1)
emitSIMDBase(VmovOpcode, Dd, Dm + 1, Dm + 1, UseQRegs, IsFloat);
if (Dd + 1 != Dn + 1)
emitSIMDBase(VmovOpcode, Dd + 1, Dn + 1, Dn + 1, UseQRegs, IsFloat);
}
void AssemblerARM32::vmovlhq(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// Pseudo-instruction to copy the first source operand and insert the lower
// half of the second operand into the high half of the destination.
// VMOV (register) - ARMv7-A/R section A8.6.327, encoding A1:
// VMOV<c> <Dd>, <Dm>
//
// 111100111D110000ddd001011QM0mmm0 where Dddd=Qd, Mmmm=Qm, and Q=0.
constexpr const char *Vmov = "vmov";
const IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Qd", Vmov));
const IValueT Dn = mapQRegToDReg(encodeQRegister(OpQn, "Qn", Vmov));
const IValueT Dm = mapQRegToDReg(encodeQRegister(OpQm, "Qm", Vmov));
constexpr bool UseQRegs = false;
constexpr bool IsFloat = false;
const IValueT VmovOpcode = B25 | B21 | B8 | B4;
if (Dd + 1 != Dm)
emitSIMDBase(VmovOpcode, Dd + 1, Dm, Dm, UseQRegs, IsFloat);
if (Dd != Dn)
emitSIMDBase(VmovOpcode, Dd, Dn, Dn, UseQRegs, IsFloat);
}
void AssemblerARM32::vnegqs(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm) {
// VNEG - ARM section A8.8.355, encoding A1:
// vneg.<dt> <Qd>, <Qm>
//
// 111111111D11ss01dddd0F111QM0mmmm where Dddd=Qd, and Mmmm=Qm, and:
// * dt=s8 -> 00=ss, 0=F
// * dt=s16 -> 01=ss, 0=F
// * dt=s32 -> 10=ss, 0=F
// * dt=s32 -> 10=ss, 1=F
constexpr const char *Vneg = "vneg";
constexpr IValueT VnegOpcode = B24 | B23 | B21 | B20 | B16 | B9 | B8 | B7;
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vneg);
constexpr IValueT Qn = 0;
const IValueT Qm = encodeQRegister(OpQm, "Qm", Vneg);
constexpr bool UseQRegs = true;
constexpr IValueT ElmtShift = 18;
const IValueT ElmtSize = encodeElmtType(ElmtTy);
assert(Utils::IsUint(2, ElmtSize));
emitSIMDBase(VnegOpcode | (ElmtSize << ElmtShift), mapQRegToDReg(Qd),
mapQRegToDReg(Qn), mapQRegToDReg(Qm), UseQRegs,
isFloatingType(ElmtTy));
}
void AssemblerARM32::vorrq(const Operand *OpQd, const Operand *OpQm,
const Operand *OpQn) {
// VORR (register) - ARM section A8.8.360, encoding A1:
// vorr <Qd>, <Qn>, <Qm>
//
// 111100100D10nnn0ddd00001N1M1mmm0 where Dddd=OpQd, Nnnn=OpQm, and Mmmm=OpQm.
constexpr const char *Vorrq = "vorrq";
constexpr IValueT VorrqOpcode = B21 | B8 | B4;
constexpr Type ElmtTy = IceType_i8;
emitSIMDqqq(VorrqOpcode, ElmtTy, OpQd, OpQm, OpQn, Vorrq);
}
void AssemblerARM32::vstrd(const Operand *OpDd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// VSTR - ARM section A8.8.413, encoding A1:
// vstr<c> <Dd>, [<Rn>{, #+/-<Imm>}]
//
// cccc1101UD00nnnndddd1011iiiiiiii where cccc=Cond, nnnn=Rn, Ddddd=Rd,
// iiiiiiii=abs(Imm >> 2), and U=1 if Imm>=0.
constexpr const char *Vstrd = "vstrd";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vstrd);
assert(CondARM32::isDefined(Cond));
IValueT Address;
IValueT AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding = B27 | B26 | B24 | B11 | B9 | B8 |
(encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) |
(getXXXXInRegYXXXX(Dd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::vstrq(const Operand *OpQd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// This is a pseudo-instruction which stores 64-bit data into a quadword
// vector register. It is implemented by storing into the lower doubleword.
// VSTR - ARM section A8.8.413, encoding A1:
// vstr<c> <Dd>, [<Rn>{, #+/-<Imm>}]
//
// cccc1101UD00nnnndddd1011iiiiiiii where cccc=Cond, nnnn=Rn, Ddddd=Rd,
// iiiiiiii=abs(Imm >> 2), and U=1 if Imm>=0.
constexpr const char *Vstrd = "vstrd";
IValueT Dd = mapQRegToDReg(encodeQRegister(OpQd, "Dd", Vstrd));
assert(CondARM32::isDefined(Cond));
IValueT Address;
IValueT AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding = B27 | B26 | B24 | B11 | B9 | B8 |
(encodeCondition(Cond) << kConditionShift) |
(getYInRegYXXXX(Dd) << 22) |
(getXXXXInRegYXXXX(Dd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::vstrs(const Operand *OpSd, const Operand *OpAddress,
CondARM32::Cond Cond, const TargetInfo &TInfo) {
// VSTR - ARM section A8.8.413, encoding A2:
// vstr<c> <Sd>, [<Rn>{, #+/-<imm>]]
//
// cccc1101UD01nnnndddd1010iiiiiiii where cccc=Cond, nnnn=Rn, ddddD=Sd,
// iiiiiiii=abs(Opcode), and U=1 if Opcode >= 0;
constexpr const char *Vstrs = "vstrs";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vstrs);
assert(CondARM32::isDefined(Cond));
IValueT Address;
IValueT AddressEncoding =
encodeAddress(OpAddress, Address, TInfo, RotatedImm8Div4Address);
(void)AddressEncoding;
assert(AddressEncoding == EncodedAsImmRegOffset);
IValueT Encoding =
B27 | B26 | B24 | B11 | B9 | (encodeCondition(Cond) << kConditionShift) |
(getYInRegXXXXY(Sd) << 22) | (getXXXXInRegXXXXY(Sd) << 12) | Address;
emitInst(Encoding);
}
void AssemblerARM32::vst1qr(size_t ElmtSize, const Operand *OpQd,
const Operand *OpAddress, const TargetInfo &TInfo) {
// VST1 (multiple single elements) - ARM section A8.8.404, encoding A1:
// vst1.<size> <Qd>, [<Rn>]
//
// 111101000D00nnnnddd0ttttssaammmm where tttt=DRegListSize2, Dddd=Qd,
// nnnn=Rn, aa=0 (use default alignment), size=ElmtSize, and ss is the
// encoding of ElmtSize.
constexpr const char *Vst1qr = "vst1qr";
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vst1qr);
const IValueT Dd = mapQRegToDReg(Qd);
IValueT Address;
if (encodeAddress(OpAddress, Address, TInfo, NoImmOffsetAddress) !=
EncodedAsImmRegOffset)
llvm::report_fatal_error(std::string(Vst1qr) + ": malform memory address");
const IValueT Rn = mask(Address, kRnShift, 4);
constexpr IValueT Rm = RegARM32::Reg_pc;
constexpr IValueT Opcode = B26;
constexpr IValueT Align = 0; // use default alignment.
emitVMem1Op(Opcode, Dd, Rn, Rm, DRegListSize2, ElmtSize, Align, Vst1qr);
}
void AssemblerARM32::vst1(size_t ElmtSize, const Operand *OpQd,
const Operand *OpAddress, const TargetInfo &TInfo) {
// This is a pseudo-instruction for storing a single element of a quadword
// vector. For 64-bit the lower doubleword vector is stored.
if (ElmtSize == 64) {
return vstrq(OpQd, OpAddress, Ice::CondARM32::AL, TInfo);
}
// VST1 (single element from one lane) - ARMv7-A/R section A8.6.392, encoding
// A1:
// VST1<c>.<size> <list>, [<Rn>{@<align>}], <Rm>
//
// 111101001D00nnnnddd0ss00aaaammmm where Dddd=Qd, nnnn=Rn,
// aaaa=0 (use default alignment), size=ElmtSize, and ss is the
// encoding of ElmtSize.
constexpr const char *Vst1qr = "vst1qr";
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vst1qr);
const IValueT Dd = mapQRegToDReg(Qd);
IValueT Address;
if (encodeAddress(OpAddress, Address, TInfo, NoImmOffsetAddress) !=
EncodedAsImmRegOffset)
llvm::report_fatal_error(std::string(Vst1qr) + ": malform memory address");
const IValueT Rn = mask(Address, kRnShift, 4);
constexpr IValueT Rm = RegARM32::Reg_pc;
constexpr IValueT Opcode = B26 | B23;
constexpr IValueT Align = 0; // use default alignment.
emitVMem1Op(Opcode, Dd, Rn, Rm, ElmtSize, Align, Vst1qr);
}
void AssemblerARM32::vsubs(const Operand *OpSd, const Operand *OpSn,
const Operand *OpSm, CondARM32::Cond Cond) {
// VSUB (floating-point) - ARM section A8.8.415, encoding A2:
// vsub<c>.f32 <Sd>, <Sn>, <Sm>
//
// cccc11100D11nnnndddd101sN1M0mmmm where cccc=Cond, s=0, ddddD=Rd, nnnnN=Rn,
// and mmmmM=Rm.
constexpr const char *Vsubs = "vsubs";
constexpr IValueT VsubsOpcode = B21 | B20 | B6;
emitVFPsss(Cond, VsubsOpcode, OpSd, OpSn, OpSm, Vsubs);
}
void AssemblerARM32::vsubd(const Operand *OpDd, const Operand *OpDn,
const Operand *OpDm, CondARM32::Cond Cond) {
// VSUB (floating-point) - ARM section A8.8.415, encoding A2:
// vsub<c>.f64 <Dd>, <Dn>, <Dm>
//
// cccc11100D11nnnndddd101sN1M0mmmm where cccc=Cond, s=1, Ddddd=Rd, Nnnnn=Rn,
// and Mmmmm=Rm.
constexpr const char *Vsubd = "vsubd";
constexpr IValueT VsubdOpcode = B21 | B20 | B6;
emitVFPddd(Cond, VsubdOpcode, OpDd, OpDn, OpDm, Vsubd);
}
void AssemblerARM32::vqaddqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VQADD (integer) - ARM section A8.6.369, encoding A1:
// vqadd<c><q>.s<size> {<Qd>,} <Qn>, <Qm>
//
// 111100100Dssnnn0ddd00000N1M1mmm0 where Dddd=OpQd, Nnnn=OpQn, Mmmm=OpQm,
// size is 8, 16, 32, or 64.
assert(isScalarIntegerType(ElmtTy) &&
"vqaddqi expects vector with integer element type");
constexpr const char *Vqaddqi = "vqaddqi";
constexpr IValueT VqaddqiOpcode = B4;
emitSIMDqqq(VqaddqiOpcode, ElmtTy, OpQd, OpQm, OpQn, Vqaddqi);
}
void AssemblerARM32::vqaddqu(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VQADD (integer) - ARM section A8.6.369, encoding A1:
// vqadd<c><q>.s<size> {<Qd>,} <Qn>, <Qm>
//
// 111100110Dssnnn0ddd00000N1M1mmm0 where Dddd=OpQd, Nnnn=OpQn, Mmmm=OpQm,
// size is 8, 16, 32, or 64.
assert(isScalarIntegerType(ElmtTy) &&
"vqaddqu expects vector with integer element type");
constexpr const char *Vqaddqu = "vqaddqu";
constexpr IValueT VqaddquOpcode = B24 | B4;
emitSIMDqqq(VqaddquOpcode, ElmtTy, OpQd, OpQm, OpQn, Vqaddqu);
}
void AssemblerARM32::vqsubqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VQSUB (integer) - ARM section A8.6.369, encoding A1:
// vqsub<c><q>.s<size> {<Qd>,} <Qn>, <Qm>
//
// 111100100Dssnnn0ddd00010N1M1mmm0 where Dddd=OpQd, Nnnn=OpQn, Mmmm=OpQm,
// size is 8, 16, 32, or 64.
assert(isScalarIntegerType(ElmtTy) &&
"vqsubqi expects vector with integer element type");
constexpr const char *Vqsubqi = "vqsubqi";
constexpr IValueT VqsubqiOpcode = B9 | B4;
emitSIMDqqq(VqsubqiOpcode, ElmtTy, OpQd, OpQm, OpQn, Vqsubqi);
}
void AssemblerARM32::vqsubqu(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VQSUB (integer) - ARM section A8.6.369, encoding A1:
// vqsub<c><q>.s<size> {<Qd>,} <Qn>, <Qm>
//
// 111100110Dssnnn0ddd00010N1M1mmm0 where Dddd=OpQd, Nnnn=OpQn, Mmmm=OpQm,
// size is 8, 16, 32, or 64.
assert(isScalarIntegerType(ElmtTy) &&
"vqsubqu expects vector with integer element type");
constexpr const char *Vqsubqu = "vqsubqu";
constexpr IValueT VqsubquOpcode = B24 | B9 | B4;
emitSIMDqqq(VqsubquOpcode, ElmtTy, OpQd, OpQm, OpQn, Vqsubqu);
}
void AssemblerARM32::vsubqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VSUB (integer) - ARM section A8.8.414, encoding A1:
// vsub.<dt> <Qd>, <Qn>, <Qm>
//
// 111100110Dssnnn0ddd01000N1M0mmm0 where Dddd=OpQd, Nnnn=OpQm, Mmmm=OpQm,
// and dt in [i8, i16, i32, i64] where ss is the index.
assert(isScalarIntegerType(ElmtTy) &&
"vsubqi expects vector with integer element type");
constexpr const char *Vsubqi = "vsubqi";
constexpr IValueT VsubqiOpcode = B24 | B11;
emitSIMDqqq(VsubqiOpcode, ElmtTy, OpQd, OpQm, OpQn, Vsubqi);
}
void AssemblerARM32::vqmovn2(Type DestElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn,
bool Unsigned, bool Saturating) {
// Pseudo-instruction for packing two quadword vectors into one quadword
// vector, narrowing each element using saturation or truncation.
// VQMOVN - ARMv7-A/R section A8.6.361, encoding A1:
// V{Q}MOVN{U}N<c>.<type><size> <Dd>, <Qm>
//
// 111100111D11ss10dddd0010opM0mmm0 where Ddddd=OpQd, op = 10, Mmmm=OpQm,
// ss is 00 (16-bit), 01 (32-bit), or 10 (64-bit).
assert(DestElmtTy != IceType_i64 &&
"vmovn doesn't allow i64 destination vector elements!");
constexpr const char *Vqmovn = "vqmovn";
constexpr bool UseQRegs = false;
constexpr bool IsFloatTy = false;
const IValueT Qd = encodeQRegister(OpQd, "Qd", Vqmovn);
const IValueT Qm = encodeQRegister(OpQm, "Qm", Vqmovn);
const IValueT Qn = encodeQRegister(OpQn, "Qn", Vqmovn);
const IValueT Dd = mapQRegToDReg(Qd);
const IValueT Dm = mapQRegToDReg(Qm);
const IValueT Dn = mapQRegToDReg(Qn);
IValueT VqmovnOpcode = B25 | B24 | B23 | B21 | B20 | B17 | B9 |
(Saturating ? (Unsigned ? B6 : B7) : 0);
constexpr IValueT ElmtShift = 18;
VqmovnOpcode |= (encodeElmtType(DestElmtTy) << ElmtShift);
if (Qm != Qd) {
// Narrow second source operand to upper half of destination.
emitSIMDBase(VqmovnOpcode, Dd + 1, 0, Dn, UseQRegs, IsFloatTy);
// Narrow first source operand to lower half of destination.
emitSIMDBase(VqmovnOpcode, Dd + 0, 0, Dm, UseQRegs, IsFloatTy);
} else if (Qn != Qd) {
// Narrow first source operand to lower half of destination.
emitSIMDBase(VqmovnOpcode, Dd + 0, 0, Dm, UseQRegs, IsFloatTy);
// Narrow second source operand to upper half of destination.
emitSIMDBase(VqmovnOpcode, Dd + 1, 0, Dn, UseQRegs, IsFloatTy);
} else {
// Narrow first source operand to lower half of destination.
emitSIMDBase(VqmovnOpcode, Dd, 0, Dm, UseQRegs, IsFloatTy);
// VMOV Dd, Dm
// 111100100D10mmmmdddd0001MQM1mmmm
const IValueT VmovOpcode = B25 | B21 | B8 | B4;
emitSIMDBase(VmovOpcode, Dd + 1, Dd, Dd, UseQRegs, IsFloatTy);
}
}
void AssemblerARM32::vsubqf(const Operand *OpQd, const Operand *OpQn,
const Operand *OpQm) {
// VSUB (floating-point) - ARM section A8.8.415, Encoding A1:
// vsub.f32 <Qd>, <Qn>, <Qm>
//
// 111100100D10nnn0ddd01101N1M0mmm0 where Dddd=Qd, Nnnn=Qn, and Mmmm=Qm.
assert(OpQd->getType() == IceType_v4f32 && "vsubqf expects type <4 x float>");
constexpr const char *Vsubqf = "vsubqf";
constexpr IValueT VsubqfOpcode = B21 | B11 | B8;
emitSIMDqqq(VsubqfOpcode, IceType_f32, OpQd, OpQn, OpQm, Vsubqf);
}
void AssemblerARM32::emitVStackOp(CondARM32::Cond Cond, IValueT Opcode,
const Variable *OpBaseReg,
SizeT NumConsecRegs) {
const IValueT BaseReg = getEncodedSRegNum(OpBaseReg);
const IValueT DLastBit = mask(BaseReg, 0, 1); // Last bit of base register.
const IValueT Rd = mask(BaseReg, 1, 4); // Top 4 bits of base register.
assert(0 < NumConsecRegs);
(void)VpushVpopMaxConsecRegs;
assert(NumConsecRegs <= VpushVpopMaxConsecRegs);
assert((BaseReg + NumConsecRegs) <= RegARM32::getNumSRegs());
assert(CondARM32::isDefined(Cond));
const IValueT Encoding = Opcode | (Cond << kConditionShift) | DLastBit |
(Rd << kRdShift) | NumConsecRegs;
emitInst(Encoding);
}
void AssemblerARM32::vpop(const Variable *OpBaseReg, SizeT NumConsecRegs,
CondARM32::Cond Cond) {
// Note: Current implementation assumes that OpBaseReg is defined using S
// registers. It doesn't implement the D register form.
//
// VPOP - ARM section A8.8.367, encoding A2:
// vpop<c> <RegList>
//
// cccc11001D111101dddd1010iiiiiiii where cccc=Cond, ddddD=BaseReg, and
// iiiiiiii=NumConsecRegs.
constexpr IValueT VpopOpcode =
B27 | B26 | B23 | B21 | B20 | B19 | B18 | B16 | B11 | B9;
emitVStackOp(Cond, VpopOpcode, OpBaseReg, NumConsecRegs);
}
void AssemblerARM32::vpush(const Variable *OpBaseReg, SizeT NumConsecRegs,
CondARM32::Cond Cond) {
// Note: Current implementation assumes that OpBaseReg is defined using S
// registers. It doesn't implement the D register form.
//
// VPUSH - ARM section A8.8.368, encoding A2:
// vpush<c> <RegList>
//
// cccc11010D101101dddd1010iiiiiiii where cccc=Cond, ddddD=BaseReg, and
// iiiiiiii=NumConsecRegs.
constexpr IValueT VpushOpcode =
B27 | B26 | B24 | B21 | B19 | B18 | B16 | B11 | B9;
emitVStackOp(Cond, VpushOpcode, OpBaseReg, NumConsecRegs);
}
void AssemblerARM32::vshlqi(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VSHL - ARM section A8.8.396, encoding A1:
// vshl Qd, Qm, Qn
//
// 1111001U0Dssnnnndddd0100NQM0mmmm where Ddddd=Qd, Mmmmm=Qm, Nnnnn=Qn, 0=U,
// 1=Q
assert(isScalarIntegerType(ElmtTy) &&
"vshl expects vector with integer element type");
constexpr const char *Vshl = "vshl";
constexpr IValueT VshlOpcode = B10 | B6;
emitSIMDqqq(VshlOpcode, ElmtTy, OpQd, OpQn, OpQm, Vshl);
}
void AssemblerARM32::vshlqc(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm,
const ConstantInteger32 *Imm6) {
// VSHL - ARM section A8.8.395, encoding A1:
// vshl Qd, Qm, #Imm
//
// 1111001U1Diiiiiidddd0101LQM1mmmm where Ddddd=Qd, Mmmmm=Qm, iiiiii=Imm6,
// 0=U, 1=Q, 0=L.
assert(isScalarIntegerType(ElmtTy) &&
"vshl expects vector with integer element type");
constexpr const char *Vshl = "vshl";
constexpr IValueT VshlOpcode = B23 | B10 | B8 | B4;
emitSIMDShiftqqc(VshlOpcode, OpQd, OpQm,
encodeSIMDShiftImm6(ST_Vshl, ElmtTy, Imm6), Vshl);
}
void AssemblerARM32::vshrqc(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const ConstantInteger32 *Imm6,
InstARM32::FPSign Sign) {
// VSHR - ARM section A8.8.398, encoding A1:
// vshr Qd, Qm, #Imm
//
// 1111001U1Diiiiiidddd0101LQM1mmmm where Ddddd=Qd, Mmmmm=Qm, iiiiii=Imm6,
// U=Unsigned, Q=1, L=0.
assert(isScalarIntegerType(ElmtTy) &&
"vshr expects vector with integer element type");
constexpr const char *Vshr = "vshr";
const IValueT VshrOpcode =
(Sign == InstARM32::FS_Unsigned ? B24 : 0) | B23 | B4;
emitSIMDShiftqqc(VshrOpcode, OpQd, OpQm,
encodeSIMDShiftImm6(ST_Vshr, ElmtTy, Imm6), Vshr);
}
void AssemblerARM32::vshlqu(Type ElmtTy, const Operand *OpQd,
const Operand *OpQm, const Operand *OpQn) {
// VSHL - ARM section A8.8.396, encoding A1:
// vshl Qd, Qm, Qn
//
// 1111001U0Dssnnnndddd0100NQM0mmmm where Ddddd=Qd, Mmmmm=Qm, Nnnnn=Qn, 1=U,
// 1=Q
assert(isScalarIntegerType(ElmtTy) &&
"vshl expects vector with integer element type");
constexpr const char *Vshl = "vshl";
constexpr IValueT VshlOpcode = B24 | B10 | B6;
emitSIMDqqq(VshlOpcode, ElmtTy, OpQd, OpQn, OpQm, Vshl);
}
void AssemblerARM32::vsqrtd(const Operand *OpDd, const Operand *OpDm,
CondARM32::Cond Cond) {
// VSQRT - ARM section A8.8.401, encoding A1:
// vsqrt<c>.f64 <Dd>, <Dm>
//
// cccc11101D110001dddd101111M0mmmm where cccc=Cond, Ddddd=Sd, and Mmmmm=Sm.
constexpr const char *Vsqrtd = "vsqrtd";
IValueT Dd = encodeDRegister(OpDd, "Dd", Vsqrtd);
IValueT Dm = encodeDRegister(OpDm, "Dm", Vsqrtd);
constexpr IValueT VsqrtdOpcode = B23 | B21 | B20 | B16 | B7 | B6;
constexpr IValueT D0 = 0;
emitVFPddd(Cond, VsqrtdOpcode, Dd, D0, Dm);
}
void AssemblerARM32::vsqrts(const Operand *OpSd, const Operand *OpSm,
CondARM32::Cond Cond) {
// VSQRT - ARM section A8.8.401, encoding A1:
// vsqrt<c>.f32 <Sd>, <Sm>
//
// cccc11101D110001dddd101011M0mmmm where cccc=Cond, ddddD=Sd, and mmmmM=Sm.
constexpr const char *Vsqrts = "vsqrts";
IValueT Sd = encodeSRegister(OpSd, "Sd", Vsqrts);
IValueT Sm = encodeSRegister(OpSm, "Sm", Vsqrts);
constexpr IValueT VsqrtsOpcode = B23 | B21 | B20 | B16 | B7 | B6;
constexpr IValueT S0 = 0;
emitVFPsss(Cond, VsqrtsOpcode, Sd, S0, Sm);
}
} // end of namespace ARM32
} // end of namespace Ice