freebsd-dev/contrib/llvm/utils/TableGen/X86RecognizableInstr.cpp
Dimitry Andric f785676f2a Upgrade our copy of llvm/clang to 3.4 release. This version supports
all of the features in the current working draft of the upcoming C++
standard, provisionally named C++1y.

The code generator's performance is greatly increased, and the loop
auto-vectorizer is now enabled at -Os and -O2 in addition to -O3.  The
PowerPC backend has made several major improvements to code generation
quality and compile time, and the X86, SPARC, ARM32, Aarch64 and SystemZ
backends have all seen major feature work.

Release notes for llvm and clang can be found here:
<http://llvm.org/releases/3.4/docs/ReleaseNotes.html>
<http://llvm.org/releases/3.4/tools/clang/docs/ReleaseNotes.html>

MFC after:	1 month
2014-02-16 19:44:07 +00:00

1487 lines
50 KiB
C++

//===- X86RecognizableInstr.cpp - Disassembler instruction spec --*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file is part of the X86 Disassembler Emitter.
// It contains the implementation of a single recognizable instruction.
// Documentation for the disassembler emitter in general can be found in
// X86DisasemblerEmitter.h.
//
//===----------------------------------------------------------------------===//
#include "X86RecognizableInstr.h"
#include "X86DisassemblerShared.h"
#include "X86ModRMFilters.h"
#include "llvm/Support/ErrorHandling.h"
#include <string>
using namespace llvm;
#define MRM_MAPPING \
MAP(C1, 33) \
MAP(C2, 34) \
MAP(C3, 35) \
MAP(C4, 36) \
MAP(C8, 37) \
MAP(C9, 38) \
MAP(CA, 39) \
MAP(CB, 40) \
MAP(E8, 41) \
MAP(F0, 42) \
MAP(F8, 45) \
MAP(F9, 46) \
MAP(D0, 47) \
MAP(D1, 48) \
MAP(D4, 49) \
MAP(D5, 50) \
MAP(D6, 51) \
MAP(D8, 52) \
MAP(D9, 53) \
MAP(DA, 54) \
MAP(DB, 55) \
MAP(DC, 56) \
MAP(DD, 57) \
MAP(DE, 58) \
MAP(DF, 59)
// A clone of X86 since we can't depend on something that is generated.
namespace X86Local {
enum {
Pseudo = 0,
RawFrm = 1,
AddRegFrm = 2,
MRMDestReg = 3,
MRMDestMem = 4,
MRMSrcReg = 5,
MRMSrcMem = 6,
MRM0r = 16, MRM1r = 17, MRM2r = 18, MRM3r = 19,
MRM4r = 20, MRM5r = 21, MRM6r = 22, MRM7r = 23,
MRM0m = 24, MRM1m = 25, MRM2m = 26, MRM3m = 27,
MRM4m = 28, MRM5m = 29, MRM6m = 30, MRM7m = 31,
MRMInitReg = 32,
RawFrmImm8 = 43,
RawFrmImm16 = 44,
#define MAP(from, to) MRM_##from = to,
MRM_MAPPING
#undef MAP
lastMRM
};
enum {
TB = 1,
REP = 2,
D8 = 3, D9 = 4, DA = 5, DB = 6,
DC = 7, DD = 8, DE = 9, DF = 10,
XD = 11, XS = 12,
T8 = 13, P_TA = 14,
A6 = 15, A7 = 16, T8XD = 17, T8XS = 18, TAXD = 19,
XOP8 = 20, XOP9 = 21, XOPA = 22
};
}
// If rows are added to the opcode extension tables, then corresponding entries
// must be added here.
//
// If the row corresponds to a single byte (i.e., 8f), then add an entry for
// that byte to ONE_BYTE_EXTENSION_TABLES.
//
// If the row corresponds to two bytes where the first is 0f, add an entry for
// the second byte to TWO_BYTE_EXTENSION_TABLES.
//
// If the row corresponds to some other set of bytes, you will need to modify
// the code in RecognizableInstr::emitDecodePath() as well, and add new prefixes
// to the X86 TD files, except in two cases: if the first two bytes of such a
// new combination are 0f 38 or 0f 3a, you just have to add maps called
// THREE_BYTE_38_EXTENSION_TABLES and THREE_BYTE_3A_EXTENSION_TABLES and add a
// switch(Opcode) just below the case X86Local::T8: or case X86Local::TA: line
// in RecognizableInstr::emitDecodePath().
#define ONE_BYTE_EXTENSION_TABLES \
EXTENSION_TABLE(80) \
EXTENSION_TABLE(81) \
EXTENSION_TABLE(82) \
EXTENSION_TABLE(83) \
EXTENSION_TABLE(8f) \
EXTENSION_TABLE(c0) \
EXTENSION_TABLE(c1) \
EXTENSION_TABLE(c6) \
EXTENSION_TABLE(c7) \
EXTENSION_TABLE(d0) \
EXTENSION_TABLE(d1) \
EXTENSION_TABLE(d2) \
EXTENSION_TABLE(d3) \
EXTENSION_TABLE(f6) \
EXTENSION_TABLE(f7) \
EXTENSION_TABLE(fe) \
EXTENSION_TABLE(ff)
#define TWO_BYTE_EXTENSION_TABLES \
EXTENSION_TABLE(00) \
EXTENSION_TABLE(01) \
EXTENSION_TABLE(0d) \
EXTENSION_TABLE(18) \
EXTENSION_TABLE(71) \
EXTENSION_TABLE(72) \
EXTENSION_TABLE(73) \
EXTENSION_TABLE(ae) \
EXTENSION_TABLE(ba) \
EXTENSION_TABLE(c7)
#define THREE_BYTE_38_EXTENSION_TABLES \
EXTENSION_TABLE(F3)
#define XOP9_MAP_EXTENSION_TABLES \
EXTENSION_TABLE(01) \
EXTENSION_TABLE(02)
using namespace X86Disassembler;
/// needsModRMForDecode - Indicates whether a particular instruction requires a
/// ModR/M byte for the instruction to be properly decoded. For example, a
/// MRMDestReg instruction needs the Mod field in the ModR/M byte to be set to
/// 0b11.
///
/// @param form - The form of the instruction.
/// @return - true if the form implies that a ModR/M byte is required, false
/// otherwise.
static bool needsModRMForDecode(uint8_t form) {
if (form == X86Local::MRMDestReg ||
form == X86Local::MRMDestMem ||
form == X86Local::MRMSrcReg ||
form == X86Local::MRMSrcMem ||
(form >= X86Local::MRM0r && form <= X86Local::MRM7r) ||
(form >= X86Local::MRM0m && form <= X86Local::MRM7m))
return true;
else
return false;
}
/// isRegFormat - Indicates whether a particular form requires the Mod field of
/// the ModR/M byte to be 0b11.
///
/// @param form - The form of the instruction.
/// @return - true if the form implies that Mod must be 0b11, false
/// otherwise.
static bool isRegFormat(uint8_t form) {
if (form == X86Local::MRMDestReg ||
form == X86Local::MRMSrcReg ||
(form >= X86Local::MRM0r && form <= X86Local::MRM7r))
return true;
else
return false;
}
/// byteFromBitsInit - Extracts a value at most 8 bits in width from a BitsInit.
/// Useful for switch statements and the like.
///
/// @param init - A reference to the BitsInit to be decoded.
/// @return - The field, with the first bit in the BitsInit as the lowest
/// order bit.
static uint8_t byteFromBitsInit(BitsInit &init) {
int width = init.getNumBits();
assert(width <= 8 && "Field is too large for uint8_t!");
int index;
uint8_t mask = 0x01;
uint8_t ret = 0;
for (index = 0; index < width; index++) {
if (static_cast<BitInit*>(init.getBit(index))->getValue())
ret |= mask;
mask <<= 1;
}
return ret;
}
/// byteFromRec - Extract a value at most 8 bits in with from a Record given the
/// name of the field.
///
/// @param rec - The record from which to extract the value.
/// @param name - The name of the field in the record.
/// @return - The field, as translated by byteFromBitsInit().
static uint8_t byteFromRec(const Record* rec, const std::string &name) {
BitsInit* bits = rec->getValueAsBitsInit(name);
return byteFromBitsInit(*bits);
}
RecognizableInstr::RecognizableInstr(DisassemblerTables &tables,
const CodeGenInstruction &insn,
InstrUID uid) {
UID = uid;
Rec = insn.TheDef;
Name = Rec->getName();
Spec = &tables.specForUID(UID);
if (!Rec->isSubClassOf("X86Inst")) {
ShouldBeEmitted = false;
return;
}
Prefix = byteFromRec(Rec, "Prefix");
Opcode = byteFromRec(Rec, "Opcode");
Form = byteFromRec(Rec, "FormBits");
SegOvr = byteFromRec(Rec, "SegOvrBits");
HasOpSizePrefix = Rec->getValueAsBit("hasOpSizePrefix");
HasAdSizePrefix = Rec->getValueAsBit("hasAdSizePrefix");
HasREX_WPrefix = Rec->getValueAsBit("hasREX_WPrefix");
HasVEXPrefix = Rec->getValueAsBit("hasVEXPrefix");
HasVEX_4VPrefix = Rec->getValueAsBit("hasVEX_4VPrefix");
HasVEX_4VOp3Prefix = Rec->getValueAsBit("hasVEX_4VOp3Prefix");
HasVEX_WPrefix = Rec->getValueAsBit("hasVEX_WPrefix");
HasMemOp4Prefix = Rec->getValueAsBit("hasMemOp4Prefix");
IgnoresVEX_L = Rec->getValueAsBit("ignoresVEX_L");
HasEVEXPrefix = Rec->getValueAsBit("hasEVEXPrefix");
HasEVEX_L2Prefix = Rec->getValueAsBit("hasEVEX_L2");
HasEVEX_K = Rec->getValueAsBit("hasEVEX_K");
HasEVEX_KZ = Rec->getValueAsBit("hasEVEX_Z");
HasEVEX_B = Rec->getValueAsBit("hasEVEX_B");
HasLockPrefix = Rec->getValueAsBit("hasLockPrefix");
IsCodeGenOnly = Rec->getValueAsBit("isCodeGenOnly");
Name = Rec->getName();
AsmString = Rec->getValueAsString("AsmString");
Operands = &insn.Operands.OperandList;
IsSSE = (HasOpSizePrefix && (Name.find("16") == Name.npos)) ||
(Name.find("CRC32") != Name.npos);
HasFROperands = hasFROperands();
HasVEX_LPrefix = Rec->getValueAsBit("hasVEX_L");
// Check for 64-bit inst which does not require REX
Is32Bit = false;
Is64Bit = false;
// FIXME: Is there some better way to check for In64BitMode?
std::vector<Record*> Predicates = Rec->getValueAsListOfDefs("Predicates");
for (unsigned i = 0, e = Predicates.size(); i != e; ++i) {
if (Predicates[i]->getName().find("32Bit") != Name.npos) {
Is32Bit = true;
break;
}
if (Predicates[i]->getName().find("64Bit") != Name.npos) {
Is64Bit = true;
break;
}
}
// FIXME: These instructions aren't marked as 64-bit in any way
Is64Bit |= Rec->getName() == "JMP64pcrel32" ||
Rec->getName() == "MASKMOVDQU64" ||
Rec->getName() == "POPFS64" ||
Rec->getName() == "POPGS64" ||
Rec->getName() == "PUSHFS64" ||
Rec->getName() == "PUSHGS64" ||
Rec->getName() == "REX64_PREFIX" ||
Rec->getName().find("MOV64") != Name.npos ||
Rec->getName().find("PUSH64") != Name.npos ||
Rec->getName().find("POP64") != Name.npos;
ShouldBeEmitted = true;
}
void RecognizableInstr::processInstr(DisassemblerTables &tables,
const CodeGenInstruction &insn,
InstrUID uid)
{
// Ignore "asm parser only" instructions.
if (insn.TheDef->getValueAsBit("isAsmParserOnly"))
return;
RecognizableInstr recogInstr(tables, insn, uid);
recogInstr.emitInstructionSpecifier(tables);
if (recogInstr.shouldBeEmitted())
recogInstr.emitDecodePath(tables);
}
#define EVEX_KB(n) (HasEVEX_KZ && HasEVEX_B ? n##_KZ_B : \
(HasEVEX_K && HasEVEX_B ? n##_K_B : \
(HasEVEX_KZ ? n##_KZ : \
(HasEVEX_K? n##_K : (HasEVEX_B ? n##_B : n)))))
InstructionContext RecognizableInstr::insnContext() const {
InstructionContext insnContext;
if (HasEVEXPrefix) {
if (HasVEX_LPrefix && HasEVEX_L2Prefix) {
errs() << "Don't support VEX.L if EVEX_L2 is enabled: " << Name << "\n";
llvm_unreachable("Don't support VEX.L if EVEX_L2 is enabled");
}
// VEX_L & VEX_W
if (HasVEX_LPrefix && HasVEX_WPrefix) {
if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_L_W_OPSIZE);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_L_W_XS);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_L_W_XD);
else
insnContext = EVEX_KB(IC_EVEX_L_W);
} else if (HasVEX_LPrefix) {
// VEX_L
if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_L_OPSIZE);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_L_XS);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_L_XD);
else
insnContext = EVEX_KB(IC_EVEX_L);
}
else if (HasEVEX_L2Prefix && HasVEX_WPrefix) {
// EVEX_L2 & VEX_W
if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_L2_W_OPSIZE);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_L2_W_XS);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_L2_W_XD);
else
insnContext = EVEX_KB(IC_EVEX_L2_W);
} else if (HasEVEX_L2Prefix) {
// EVEX_L2
if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_L2_OPSIZE);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_L2_XD);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_L2_XS);
else
insnContext = EVEX_KB(IC_EVEX_L2);
}
else if (HasVEX_WPrefix) {
// VEX_W
if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_W_OPSIZE);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_W_XS);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_W_XD);
else
insnContext = EVEX_KB(IC_EVEX_W);
}
// No L, no W
else if (HasOpSizePrefix)
insnContext = EVEX_KB(IC_EVEX_OPSIZE);
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = EVEX_KB(IC_EVEX_XD);
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = EVEX_KB(IC_EVEX_XS);
else
insnContext = EVEX_KB(IC_EVEX);
/// eof EVEX
} else if (HasVEX_4VPrefix || HasVEX_4VOp3Prefix|| HasVEXPrefix) {
if (HasVEX_LPrefix && HasVEX_WPrefix) {
if (HasOpSizePrefix)
insnContext = IC_VEX_L_W_OPSIZE;
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = IC_VEX_L_W_XS;
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = IC_VEX_L_W_XD;
else
insnContext = IC_VEX_L_W;
} else if (HasOpSizePrefix && HasVEX_LPrefix)
insnContext = IC_VEX_L_OPSIZE;
else if (HasOpSizePrefix && HasVEX_WPrefix)
insnContext = IC_VEX_W_OPSIZE;
else if (HasOpSizePrefix)
insnContext = IC_VEX_OPSIZE;
else if (HasVEX_LPrefix &&
(Prefix == X86Local::XS || Prefix == X86Local::T8XS))
insnContext = IC_VEX_L_XS;
else if (HasVEX_LPrefix && (Prefix == X86Local::XD ||
Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD))
insnContext = IC_VEX_L_XD;
else if (HasVEX_WPrefix &&
(Prefix == X86Local::XS || Prefix == X86Local::T8XS))
insnContext = IC_VEX_W_XS;
else if (HasVEX_WPrefix && (Prefix == X86Local::XD ||
Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD))
insnContext = IC_VEX_W_XD;
else if (HasVEX_WPrefix)
insnContext = IC_VEX_W;
else if (HasVEX_LPrefix)
insnContext = IC_VEX_L;
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = IC_VEX_XD;
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = IC_VEX_XS;
else
insnContext = IC_VEX;
} else if (Is64Bit || HasREX_WPrefix) {
if (HasREX_WPrefix && HasOpSizePrefix)
insnContext = IC_64BIT_REXW_OPSIZE;
else if (HasOpSizePrefix && (Prefix == X86Local::XD ||
Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD))
insnContext = IC_64BIT_XD_OPSIZE;
else if (HasOpSizePrefix &&
(Prefix == X86Local::XS || Prefix == X86Local::T8XS))
insnContext = IC_64BIT_XS_OPSIZE;
else if (HasOpSizePrefix)
insnContext = IC_64BIT_OPSIZE;
else if (HasAdSizePrefix)
insnContext = IC_64BIT_ADSIZE;
else if (HasREX_WPrefix &&
(Prefix == X86Local::XS || Prefix == X86Local::T8XS))
insnContext = IC_64BIT_REXW_XS;
else if (HasREX_WPrefix && (Prefix == X86Local::XD ||
Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD))
insnContext = IC_64BIT_REXW_XD;
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = IC_64BIT_XD;
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS)
insnContext = IC_64BIT_XS;
else if (HasREX_WPrefix)
insnContext = IC_64BIT_REXW;
else
insnContext = IC_64BIT;
} else {
if (HasOpSizePrefix && (Prefix == X86Local::XD ||
Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD))
insnContext = IC_XD_OPSIZE;
else if (HasOpSizePrefix &&
(Prefix == X86Local::XS || Prefix == X86Local::T8XS))
insnContext = IC_XS_OPSIZE;
else if (HasOpSizePrefix)
insnContext = IC_OPSIZE;
else if (HasAdSizePrefix)
insnContext = IC_ADSIZE;
else if (Prefix == X86Local::XD || Prefix == X86Local::T8XD ||
Prefix == X86Local::TAXD)
insnContext = IC_XD;
else if (Prefix == X86Local::XS || Prefix == X86Local::T8XS ||
Prefix == X86Local::REP)
insnContext = IC_XS;
else
insnContext = IC;
}
return insnContext;
}
RecognizableInstr::filter_ret RecognizableInstr::filter() const {
///////////////////
// FILTER_STRONG
//
// Filter out intrinsics
assert(Rec->isSubClassOf("X86Inst") && "Can only filter X86 instructions");
if (Form == X86Local::Pseudo ||
(IsCodeGenOnly && Name.find("_REV") == Name.npos &&
Name.find("INC32") == Name.npos && Name.find("DEC32") == Name.npos))
return FILTER_STRONG;
// Filter out artificial instructions but leave in the LOCK_PREFIX so it is
// printed as a separate "instruction".
if (Name.find("_Int") != Name.npos ||
Name.find("Int_") != Name.npos)
return FILTER_STRONG;
// Filter out instructions with segment override prefixes.
// They're too messy to handle now and we'll special case them if needed.
if (SegOvr)
return FILTER_STRONG;
/////////////////
// FILTER_WEAK
//
// Filter out instructions with a LOCK prefix;
// prefer forms that do not have the prefix
if (HasLockPrefix)
return FILTER_WEAK;
// Filter out alternate forms of AVX instructions
if (Name.find("_alt") != Name.npos ||
(Name.find("r64r") != Name.npos && Name.find("r64r64") == Name.npos && Name.find("r64r8") == Name.npos) ||
Name.find("_64mr") != Name.npos ||
Name.find("rr64") != Name.npos)
return FILTER_WEAK;
// Special cases.
if (Name == "PUSH64i16" ||
Name == "MOVPQI2QImr" ||
Name == "VMOVPQI2QImr" ||
Name == "VMASKMOVDQU64")
return FILTER_WEAK;
// XACQUIRE and XRELEASE reuse REPNE and REP respectively.
// For now, just prefer the REP versions.
if (Name == "XACQUIRE_PREFIX" ||
Name == "XRELEASE_PREFIX")
return FILTER_WEAK;
return FILTER_NORMAL;
}
bool RecognizableInstr::hasFROperands() const {
const std::vector<CGIOperandList::OperandInfo> &OperandList = *Operands;
unsigned numOperands = OperandList.size();
for (unsigned operandIndex = 0; operandIndex < numOperands; ++operandIndex) {
const std::string &recName = OperandList[operandIndex].Rec->getName();
if (recName.find("FR") != recName.npos)
return true;
}
return false;
}
void RecognizableInstr::handleOperand(bool optional, unsigned &operandIndex,
unsigned &physicalOperandIndex,
unsigned &numPhysicalOperands,
const unsigned *operandMapping,
OperandEncoding (*encodingFromString)
(const std::string&,
bool hasOpSizePrefix)) {
if (optional) {
if (physicalOperandIndex >= numPhysicalOperands)
return;
} else {
assert(physicalOperandIndex < numPhysicalOperands);
}
while (operandMapping[operandIndex] != operandIndex) {
Spec->operands[operandIndex].encoding = ENCODING_DUP;
Spec->operands[operandIndex].type =
(OperandType)(TYPE_DUP0 + operandMapping[operandIndex]);
++operandIndex;
}
const std::string &typeName = (*Operands)[operandIndex].Rec->getName();
Spec->operands[operandIndex].encoding = encodingFromString(typeName,
HasOpSizePrefix);
Spec->operands[operandIndex].type = typeFromString(typeName,
IsSSE,
HasREX_WPrefix,
HasOpSizePrefix);
++operandIndex;
++physicalOperandIndex;
}
void RecognizableInstr::emitInstructionSpecifier(DisassemblerTables &tables) {
Spec->name = Name;
if (!ShouldBeEmitted)
return;
switch (filter()) {
case FILTER_WEAK:
Spec->filtered = true;
break;
case FILTER_STRONG:
ShouldBeEmitted = false;
return;
case FILTER_NORMAL:
break;
}
Spec->insnContext = insnContext();
const std::vector<CGIOperandList::OperandInfo> &OperandList = *Operands;
unsigned numOperands = OperandList.size();
unsigned numPhysicalOperands = 0;
// operandMapping maps from operands in OperandList to their originals.
// If operandMapping[i] != i, then the entry is a duplicate.
unsigned operandMapping[X86_MAX_OPERANDS];
assert(numOperands <= X86_MAX_OPERANDS && "X86_MAX_OPERANDS is not large enough");
for (unsigned operandIndex = 0; operandIndex < numOperands; ++operandIndex) {
if (OperandList[operandIndex].Constraints.size()) {
const CGIOperandList::ConstraintInfo &Constraint =
OperandList[operandIndex].Constraints[0];
if (Constraint.isTied()) {
operandMapping[operandIndex] = operandIndex;
operandMapping[Constraint.getTiedOperand()] = operandIndex;
} else {
++numPhysicalOperands;
operandMapping[operandIndex] = operandIndex;
}
} else {
++numPhysicalOperands;
operandMapping[operandIndex] = operandIndex;
}
}
#define HANDLE_OPERAND(class) \
handleOperand(false, \
operandIndex, \
physicalOperandIndex, \
numPhysicalOperands, \
operandMapping, \
class##EncodingFromString);
#define HANDLE_OPTIONAL(class) \
handleOperand(true, \
operandIndex, \
physicalOperandIndex, \
numPhysicalOperands, \
operandMapping, \
class##EncodingFromString);
// operandIndex should always be < numOperands
unsigned operandIndex = 0;
// physicalOperandIndex should always be < numPhysicalOperands
unsigned physicalOperandIndex = 0;
switch (Form) {
case X86Local::RawFrm:
// Operand 1 (optional) is an address or immediate.
// Operand 2 (optional) is an immediate.
assert(numPhysicalOperands <= 2 &&
"Unexpected number of operands for RawFrm");
HANDLE_OPTIONAL(relocation)
HANDLE_OPTIONAL(immediate)
break;
case X86Local::AddRegFrm:
// Operand 1 is added to the opcode.
// Operand 2 (optional) is an address.
assert(numPhysicalOperands >= 1 && numPhysicalOperands <= 2 &&
"Unexpected number of operands for AddRegFrm");
HANDLE_OPERAND(opcodeModifier)
HANDLE_OPTIONAL(relocation)
break;
case X86Local::MRMDestReg:
// Operand 1 is a register operand in the R/M field.
// Operand 2 is a register operand in the Reg/Opcode field.
// - In AVX, there is a register operand in the VEX.vvvv field here -
// Operand 3 (optional) is an immediate.
if (HasVEX_4VPrefix)
assert(numPhysicalOperands >= 3 && numPhysicalOperands <= 4 &&
"Unexpected number of operands for MRMDestRegFrm with VEX_4V");
else
assert(numPhysicalOperands >= 2 && numPhysicalOperands <= 3 &&
"Unexpected number of operands for MRMDestRegFrm");
HANDLE_OPERAND(rmRegister)
if (HasVEX_4VPrefix)
// FIXME: In AVX, the register below becomes the one encoded
// in ModRMVEX and the one above the one in the VEX.VVVV field
HANDLE_OPERAND(vvvvRegister)
HANDLE_OPERAND(roRegister)
HANDLE_OPTIONAL(immediate)
break;
case X86Local::MRMDestMem:
// Operand 1 is a memory operand (possibly SIB-extended)
// Operand 2 is a register operand in the Reg/Opcode field.
// - In AVX, there is a register operand in the VEX.vvvv field here -
// Operand 3 (optional) is an immediate.
if (HasVEX_4VPrefix)
assert(numPhysicalOperands >= 3 && numPhysicalOperands <= 4 &&
"Unexpected number of operands for MRMDestMemFrm with VEX_4V");
else
assert(numPhysicalOperands >= 2 && numPhysicalOperands <= 3 &&
"Unexpected number of operands for MRMDestMemFrm");
HANDLE_OPERAND(memory)
if (HasEVEX_K)
HANDLE_OPERAND(writemaskRegister)
if (HasVEX_4VPrefix)
// FIXME: In AVX, the register below becomes the one encoded
// in ModRMVEX and the one above the one in the VEX.VVVV field
HANDLE_OPERAND(vvvvRegister)
HANDLE_OPERAND(roRegister)
HANDLE_OPTIONAL(immediate)
break;
case X86Local::MRMSrcReg:
// Operand 1 is a register operand in the Reg/Opcode field.
// Operand 2 is a register operand in the R/M field.
// - In AVX, there is a register operand in the VEX.vvvv field here -
// Operand 3 (optional) is an immediate.
// Operand 4 (optional) is an immediate.
if (HasVEX_4VPrefix || HasVEX_4VOp3Prefix)
assert(numPhysicalOperands >= 3 && numPhysicalOperands <= 5 &&
"Unexpected number of operands for MRMSrcRegFrm with VEX_4V");
else
assert(numPhysicalOperands >= 2 && numPhysicalOperands <= 4 &&
"Unexpected number of operands for MRMSrcRegFrm");
HANDLE_OPERAND(roRegister)
if (HasEVEX_K)
HANDLE_OPERAND(writemaskRegister)
if (HasVEX_4VPrefix)
// FIXME: In AVX, the register below becomes the one encoded
// in ModRMVEX and the one above the one in the VEX.VVVV field
HANDLE_OPERAND(vvvvRegister)
if (HasMemOp4Prefix)
HANDLE_OPERAND(immediate)
HANDLE_OPERAND(rmRegister)
if (HasVEX_4VOp3Prefix)
HANDLE_OPERAND(vvvvRegister)
if (!HasMemOp4Prefix)
HANDLE_OPTIONAL(immediate)
HANDLE_OPTIONAL(immediate) // above might be a register in 7:4
HANDLE_OPTIONAL(immediate)
break;
case X86Local::MRMSrcMem:
// Operand 1 is a register operand in the Reg/Opcode field.
// Operand 2 is a memory operand (possibly SIB-extended)
// - In AVX, there is a register operand in the VEX.vvvv field here -
// Operand 3 (optional) is an immediate.
if (HasVEX_4VPrefix || HasVEX_4VOp3Prefix)
assert(numPhysicalOperands >= 3 && numPhysicalOperands <= 5 &&
"Unexpected number of operands for MRMSrcMemFrm with VEX_4V");
else
assert(numPhysicalOperands >= 2 && numPhysicalOperands <= 3 &&
"Unexpected number of operands for MRMSrcMemFrm");
HANDLE_OPERAND(roRegister)
if (HasEVEX_K)
HANDLE_OPERAND(writemaskRegister)
if (HasVEX_4VPrefix)
// FIXME: In AVX, the register below becomes the one encoded
// in ModRMVEX and the one above the one in the VEX.VVVV field
HANDLE_OPERAND(vvvvRegister)
if (HasMemOp4Prefix)
HANDLE_OPERAND(immediate)
HANDLE_OPERAND(memory)
if (HasVEX_4VOp3Prefix)
HANDLE_OPERAND(vvvvRegister)
if (!HasMemOp4Prefix)
HANDLE_OPTIONAL(immediate)
HANDLE_OPTIONAL(immediate) // above might be a register in 7:4
break;
case X86Local::MRM0r:
case X86Local::MRM1r:
case X86Local::MRM2r:
case X86Local::MRM3r:
case X86Local::MRM4r:
case X86Local::MRM5r:
case X86Local::MRM6r:
case X86Local::MRM7r:
{
// Operand 1 is a register operand in the R/M field.
// Operand 2 (optional) is an immediate or relocation.
// Operand 3 (optional) is an immediate.
unsigned kOp = (HasEVEX_K) ? 1:0;
unsigned Op4v = (HasVEX_4VPrefix) ? 1:0;
if (numPhysicalOperands > 3 + kOp + Op4v)
llvm_unreachable("Unexpected number of operands for MRMnr");
}
if (HasVEX_4VPrefix)
HANDLE_OPERAND(vvvvRegister)
if (HasEVEX_K)
HANDLE_OPERAND(writemaskRegister)
HANDLE_OPTIONAL(rmRegister)
HANDLE_OPTIONAL(relocation)
HANDLE_OPTIONAL(immediate)
break;
case X86Local::MRM0m:
case X86Local::MRM1m:
case X86Local::MRM2m:
case X86Local::MRM3m:
case X86Local::MRM4m:
case X86Local::MRM5m:
case X86Local::MRM6m:
case X86Local::MRM7m:
{
// Operand 1 is a memory operand (possibly SIB-extended)
// Operand 2 (optional) is an immediate or relocation.
unsigned kOp = (HasEVEX_K) ? 1:0;
unsigned Op4v = (HasVEX_4VPrefix) ? 1:0;
if (numPhysicalOperands < 1 + kOp + Op4v ||
numPhysicalOperands > 2 + kOp + Op4v)
llvm_unreachable("Unexpected number of operands for MRMnm");
}
if (HasVEX_4VPrefix)
HANDLE_OPERAND(vvvvRegister)
if (HasEVEX_K)
HANDLE_OPERAND(writemaskRegister)
HANDLE_OPERAND(memory)
HANDLE_OPTIONAL(relocation)
break;
case X86Local::RawFrmImm8:
// operand 1 is a 16-bit immediate
// operand 2 is an 8-bit immediate
assert(numPhysicalOperands == 2 &&
"Unexpected number of operands for X86Local::RawFrmImm8");
HANDLE_OPERAND(immediate)
HANDLE_OPERAND(immediate)
break;
case X86Local::RawFrmImm16:
// operand 1 is a 16-bit immediate
// operand 2 is a 16-bit immediate
HANDLE_OPERAND(immediate)
HANDLE_OPERAND(immediate)
break;
case X86Local::MRM_F8:
if (Opcode == 0xc6) {
assert(numPhysicalOperands == 1 &&
"Unexpected number of operands for X86Local::MRM_F8");
HANDLE_OPERAND(immediate)
} else if (Opcode == 0xc7) {
assert(numPhysicalOperands == 1 &&
"Unexpected number of operands for X86Local::MRM_F8");
HANDLE_OPERAND(relocation)
}
break;
case X86Local::MRMInitReg:
// Ignored.
break;
}
#undef HANDLE_OPERAND
#undef HANDLE_OPTIONAL
}
void RecognizableInstr::emitDecodePath(DisassemblerTables &tables) const {
// Special cases where the LLVM tables are not complete
#define MAP(from, to) \
case X86Local::MRM_##from: \
filter = new ExactFilter(0x##from); \
break;
OpcodeType opcodeType = (OpcodeType)-1;
ModRMFilter* filter = NULL;
uint8_t opcodeToSet = 0;
switch (Prefix) {
default: llvm_unreachable("Invalid prefix!");
// Extended two-byte opcodes can start with f2 0f, f3 0f, or 0f
case X86Local::XD:
case X86Local::XS:
case X86Local::TB:
opcodeType = TWOBYTE;
switch (Opcode) {
default:
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
break;
#define EXTENSION_TABLE(n) case 0x##n:
TWO_BYTE_EXTENSION_TABLES
#undef EXTENSION_TABLE
switch (Form) {
default:
llvm_unreachable("Unhandled two-byte extended opcode");
case X86Local::MRM0r:
case X86Local::MRM1r:
case X86Local::MRM2r:
case X86Local::MRM3r:
case X86Local::MRM4r:
case X86Local::MRM5r:
case X86Local::MRM6r:
case X86Local::MRM7r:
filter = new ExtendedFilter(true, Form - X86Local::MRM0r);
break;
case X86Local::MRM0m:
case X86Local::MRM1m:
case X86Local::MRM2m:
case X86Local::MRM3m:
case X86Local::MRM4m:
case X86Local::MRM5m:
case X86Local::MRM6m:
case X86Local::MRM7m:
filter = new ExtendedFilter(false, Form - X86Local::MRM0m);
break;
MRM_MAPPING
} // switch (Form)
break;
} // switch (Opcode)
opcodeToSet = Opcode;
break;
case X86Local::T8:
case X86Local::T8XD:
case X86Local::T8XS:
opcodeType = THREEBYTE_38;
switch (Opcode) {
default:
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
break;
#define EXTENSION_TABLE(n) case 0x##n:
THREE_BYTE_38_EXTENSION_TABLES
#undef EXTENSION_TABLE
switch (Form) {
default:
llvm_unreachable("Unhandled two-byte extended opcode");
case X86Local::MRM0r:
case X86Local::MRM1r:
case X86Local::MRM2r:
case X86Local::MRM3r:
case X86Local::MRM4r:
case X86Local::MRM5r:
case X86Local::MRM6r:
case X86Local::MRM7r:
filter = new ExtendedFilter(true, Form - X86Local::MRM0r);
break;
case X86Local::MRM0m:
case X86Local::MRM1m:
case X86Local::MRM2m:
case X86Local::MRM3m:
case X86Local::MRM4m:
case X86Local::MRM5m:
case X86Local::MRM6m:
case X86Local::MRM7m:
filter = new ExtendedFilter(false, Form - X86Local::MRM0m);
break;
MRM_MAPPING
} // switch (Form)
break;
} // switch (Opcode)
opcodeToSet = Opcode;
break;
case X86Local::P_TA:
case X86Local::TAXD:
opcodeType = THREEBYTE_3A;
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
opcodeToSet = Opcode;
break;
case X86Local::A6:
opcodeType = THREEBYTE_A6;
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
opcodeToSet = Opcode;
break;
case X86Local::A7:
opcodeType = THREEBYTE_A7;
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
opcodeToSet = Opcode;
break;
case X86Local::XOP8:
opcodeType = XOP8_MAP;
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
opcodeToSet = Opcode;
break;
case X86Local::XOP9:
opcodeType = XOP9_MAP;
switch (Opcode) {
default:
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
break;
#define EXTENSION_TABLE(n) case 0x##n:
XOP9_MAP_EXTENSION_TABLES
#undef EXTENSION_TABLE
switch (Form) {
default:
llvm_unreachable("Unhandled XOP9 extended opcode");
case X86Local::MRM0r:
case X86Local::MRM1r:
case X86Local::MRM2r:
case X86Local::MRM3r:
case X86Local::MRM4r:
case X86Local::MRM5r:
case X86Local::MRM6r:
case X86Local::MRM7r:
filter = new ExtendedFilter(true, Form - X86Local::MRM0r);
break;
case X86Local::MRM0m:
case X86Local::MRM1m:
case X86Local::MRM2m:
case X86Local::MRM3m:
case X86Local::MRM4m:
case X86Local::MRM5m:
case X86Local::MRM6m:
case X86Local::MRM7m:
filter = new ExtendedFilter(false, Form - X86Local::MRM0m);
break;
MRM_MAPPING
} // switch (Form)
break;
} // switch (Opcode)
opcodeToSet = Opcode;
break;
case X86Local::XOPA:
opcodeType = XOPA_MAP;
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
opcodeToSet = Opcode;
break;
case X86Local::D8:
case X86Local::D9:
case X86Local::DA:
case X86Local::DB:
case X86Local::DC:
case X86Local::DD:
case X86Local::DE:
case X86Local::DF:
assert(Opcode >= 0xc0 && "Unexpected opcode for an escape opcode");
opcodeType = ONEBYTE;
if (Form == X86Local::AddRegFrm) {
Spec->modifierType = MODIFIER_MODRM;
Spec->modifierBase = Opcode;
filter = new AddRegEscapeFilter(Opcode);
} else {
filter = new EscapeFilter(true, Opcode);
}
opcodeToSet = 0xd8 + (Prefix - X86Local::D8);
break;
case X86Local::REP:
case 0:
opcodeType = ONEBYTE;
switch (Opcode) {
#define EXTENSION_TABLE(n) case 0x##n:
ONE_BYTE_EXTENSION_TABLES
#undef EXTENSION_TABLE
switch (Form) {
default:
llvm_unreachable("Fell through the cracks of a single-byte "
"extended opcode");
case X86Local::MRM0r:
case X86Local::MRM1r:
case X86Local::MRM2r:
case X86Local::MRM3r:
case X86Local::MRM4r:
case X86Local::MRM5r:
case X86Local::MRM6r:
case X86Local::MRM7r:
filter = new ExtendedFilter(true, Form - X86Local::MRM0r);
break;
case X86Local::MRM0m:
case X86Local::MRM1m:
case X86Local::MRM2m:
case X86Local::MRM3m:
case X86Local::MRM4m:
case X86Local::MRM5m:
case X86Local::MRM6m:
case X86Local::MRM7m:
filter = new ExtendedFilter(false, Form - X86Local::MRM0m);
break;
MRM_MAPPING
} // switch (Form)
break;
case 0xd8:
case 0xd9:
case 0xda:
case 0xdb:
case 0xdc:
case 0xdd:
case 0xde:
case 0xdf:
filter = new EscapeFilter(false, Form - X86Local::MRM0m);
break;
default:
if (needsModRMForDecode(Form))
filter = new ModFilter(isRegFormat(Form));
else
filter = new DumbFilter();
break;
} // switch (Opcode)
opcodeToSet = Opcode;
} // switch (Prefix)
assert(opcodeType != (OpcodeType)-1 &&
"Opcode type not set");
assert(filter && "Filter not set");
if (Form == X86Local::AddRegFrm) {
if(Spec->modifierType != MODIFIER_MODRM) {
assert(opcodeToSet < 0xf9 &&
"Not enough room for all ADDREG_FRM operands");
uint8_t currentOpcode;
for (currentOpcode = opcodeToSet;
currentOpcode < opcodeToSet + 8;
++currentOpcode)
tables.setTableFields(opcodeType,
insnContext(),
currentOpcode,
*filter,
UID, Is32Bit, IgnoresVEX_L);
Spec->modifierType = MODIFIER_OPCODE;
Spec->modifierBase = opcodeToSet;
} else {
// modifierBase was set where MODIFIER_MODRM was set
tables.setTableFields(opcodeType,
insnContext(),
opcodeToSet,
*filter,
UID, Is32Bit, IgnoresVEX_L);
}
} else {
tables.setTableFields(opcodeType,
insnContext(),
opcodeToSet,
*filter,
UID, Is32Bit, IgnoresVEX_L);
Spec->modifierType = MODIFIER_NONE;
Spec->modifierBase = opcodeToSet;
}
delete filter;
#undef MAP
}
#define TYPE(str, type) if (s == str) return type;
OperandType RecognizableInstr::typeFromString(const std::string &s,
bool isSSE,
bool hasREX_WPrefix,
bool hasOpSizePrefix) {
if (isSSE) {
// For SSE instructions, we ignore the OpSize prefix and force operand
// sizes.
TYPE("GR16", TYPE_R16)
TYPE("GR32", TYPE_R32)
TYPE("GR64", TYPE_R64)
}
if(hasREX_WPrefix) {
// For instructions with a REX_W prefix, a declared 32-bit register encoding
// is special.
TYPE("GR32", TYPE_R32)
}
if(!hasOpSizePrefix) {
// For instructions without an OpSize prefix, a declared 16-bit register or
// immediate encoding is special.
TYPE("GR16", TYPE_R16)
TYPE("i16imm", TYPE_IMM16)
}
TYPE("i16mem", TYPE_Mv)
TYPE("i16imm", TYPE_IMMv)
TYPE("i16i8imm", TYPE_IMMv)
TYPE("GR16", TYPE_Rv)
TYPE("i32mem", TYPE_Mv)
TYPE("i32imm", TYPE_IMMv)
TYPE("i32i8imm", TYPE_IMM32)
TYPE("u32u8imm", TYPE_IMM32)
TYPE("GR32", TYPE_Rv)
TYPE("GR32orGR64", TYPE_R32)
TYPE("i64mem", TYPE_Mv)
TYPE("i64i32imm", TYPE_IMM64)
TYPE("i64i8imm", TYPE_IMM64)
TYPE("GR64", TYPE_R64)
TYPE("i8mem", TYPE_M8)
TYPE("i8imm", TYPE_IMM8)
TYPE("GR8", TYPE_R8)
TYPE("VR128", TYPE_XMM128)
TYPE("VR128X", TYPE_XMM128)
TYPE("f128mem", TYPE_M128)
TYPE("f256mem", TYPE_M256)
TYPE("f512mem", TYPE_M512)
TYPE("FR64", TYPE_XMM64)
TYPE("FR64X", TYPE_XMM64)
TYPE("f64mem", TYPE_M64FP)
TYPE("sdmem", TYPE_M64FP)
TYPE("FR32", TYPE_XMM32)
TYPE("FR32X", TYPE_XMM32)
TYPE("f32mem", TYPE_M32FP)
TYPE("ssmem", TYPE_M32FP)
TYPE("RST", TYPE_ST)
TYPE("i128mem", TYPE_M128)
TYPE("i256mem", TYPE_M256)
TYPE("i512mem", TYPE_M512)
TYPE("i64i32imm_pcrel", TYPE_REL64)
TYPE("i16imm_pcrel", TYPE_REL16)
TYPE("i32imm_pcrel", TYPE_REL32)
TYPE("SSECC", TYPE_IMM3)
TYPE("AVXCC", TYPE_IMM5)
TYPE("brtarget", TYPE_RELv)
TYPE("uncondbrtarget", TYPE_RELv)
TYPE("brtarget8", TYPE_REL8)
TYPE("f80mem", TYPE_M80FP)
TYPE("lea32mem", TYPE_LEA)
TYPE("lea64_32mem", TYPE_LEA)
TYPE("lea64mem", TYPE_LEA)
TYPE("VR64", TYPE_MM64)
TYPE("i64imm", TYPE_IMMv)
TYPE("opaque32mem", TYPE_M1616)
TYPE("opaque48mem", TYPE_M1632)
TYPE("opaque80mem", TYPE_M1664)
TYPE("opaque512mem", TYPE_M512)
TYPE("SEGMENT_REG", TYPE_SEGMENTREG)
TYPE("DEBUG_REG", TYPE_DEBUGREG)
TYPE("CONTROL_REG", TYPE_CONTROLREG)
TYPE("offset8", TYPE_MOFFS8)
TYPE("offset16", TYPE_MOFFS16)
TYPE("offset32", TYPE_MOFFS32)
TYPE("offset64", TYPE_MOFFS64)
TYPE("VR256", TYPE_XMM256)
TYPE("VR256X", TYPE_XMM256)
TYPE("VR512", TYPE_XMM512)
TYPE("VK8", TYPE_VK8)
TYPE("VK8WM", TYPE_VK8)
TYPE("VK16", TYPE_VK16)
TYPE("VK16WM", TYPE_VK16)
TYPE("GR16_NOAX", TYPE_Rv)
TYPE("GR32_NOAX", TYPE_Rv)
TYPE("GR64_NOAX", TYPE_R64)
TYPE("vx32mem", TYPE_M32)
TYPE("vy32mem", TYPE_M32)
TYPE("vz32mem", TYPE_M32)
TYPE("vx64mem", TYPE_M64)
TYPE("vy64mem", TYPE_M64)
TYPE("vy64xmem", TYPE_M64)
TYPE("vz64mem", TYPE_M64)
errs() << "Unhandled type string " << s << "\n";
llvm_unreachable("Unhandled type string");
}
#undef TYPE
#define ENCODING(str, encoding) if (s == str) return encoding;
OperandEncoding RecognizableInstr::immediateEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
if(!hasOpSizePrefix) {
// For instructions without an OpSize prefix, a declared 16-bit register or
// immediate encoding is special.
ENCODING("i16imm", ENCODING_IW)
}
ENCODING("i32i8imm", ENCODING_IB)
ENCODING("u32u8imm", ENCODING_IB)
ENCODING("SSECC", ENCODING_IB)
ENCODING("AVXCC", ENCODING_IB)
ENCODING("i16imm", ENCODING_Iv)
ENCODING("i16i8imm", ENCODING_IB)
ENCODING("i32imm", ENCODING_Iv)
ENCODING("i64i32imm", ENCODING_ID)
ENCODING("i64i8imm", ENCODING_IB)
ENCODING("i8imm", ENCODING_IB)
// This is not a typo. Instructions like BLENDVPD put
// register IDs in 8-bit immediates nowadays.
ENCODING("FR32", ENCODING_IB)
ENCODING("FR64", ENCODING_IB)
ENCODING("VR128", ENCODING_IB)
ENCODING("VR256", ENCODING_IB)
ENCODING("FR32X", ENCODING_IB)
ENCODING("FR64X", ENCODING_IB)
ENCODING("VR128X", ENCODING_IB)
ENCODING("VR256X", ENCODING_IB)
ENCODING("VR512", ENCODING_IB)
errs() << "Unhandled immediate encoding " << s << "\n";
llvm_unreachable("Unhandled immediate encoding");
}
OperandEncoding RecognizableInstr::rmRegisterEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("GR16", ENCODING_RM)
ENCODING("GR32", ENCODING_RM)
ENCODING("GR32orGR64", ENCODING_RM)
ENCODING("GR64", ENCODING_RM)
ENCODING("GR8", ENCODING_RM)
ENCODING("VR128", ENCODING_RM)
ENCODING("VR128X", ENCODING_RM)
ENCODING("FR64", ENCODING_RM)
ENCODING("FR32", ENCODING_RM)
ENCODING("FR64X", ENCODING_RM)
ENCODING("FR32X", ENCODING_RM)
ENCODING("VR64", ENCODING_RM)
ENCODING("VR256", ENCODING_RM)
ENCODING("VR256X", ENCODING_RM)
ENCODING("VR512", ENCODING_RM)
ENCODING("VK8", ENCODING_RM)
ENCODING("VK16", ENCODING_RM)
errs() << "Unhandled R/M register encoding " << s << "\n";
llvm_unreachable("Unhandled R/M register encoding");
}
OperandEncoding RecognizableInstr::roRegisterEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("GR16", ENCODING_REG)
ENCODING("GR32", ENCODING_REG)
ENCODING("GR32orGR64", ENCODING_REG)
ENCODING("GR64", ENCODING_REG)
ENCODING("GR8", ENCODING_REG)
ENCODING("VR128", ENCODING_REG)
ENCODING("FR64", ENCODING_REG)
ENCODING("FR32", ENCODING_REG)
ENCODING("VR64", ENCODING_REG)
ENCODING("SEGMENT_REG", ENCODING_REG)
ENCODING("DEBUG_REG", ENCODING_REG)
ENCODING("CONTROL_REG", ENCODING_REG)
ENCODING("VR256", ENCODING_REG)
ENCODING("VR256X", ENCODING_REG)
ENCODING("VR128X", ENCODING_REG)
ENCODING("FR64X", ENCODING_REG)
ENCODING("FR32X", ENCODING_REG)
ENCODING("VR512", ENCODING_REG)
ENCODING("VK8", ENCODING_REG)
ENCODING("VK16", ENCODING_REG)
ENCODING("VK8WM", ENCODING_REG)
ENCODING("VK16WM", ENCODING_REG)
errs() << "Unhandled reg/opcode register encoding " << s << "\n";
llvm_unreachable("Unhandled reg/opcode register encoding");
}
OperandEncoding RecognizableInstr::vvvvRegisterEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("GR32", ENCODING_VVVV)
ENCODING("GR64", ENCODING_VVVV)
ENCODING("FR32", ENCODING_VVVV)
ENCODING("FR64", ENCODING_VVVV)
ENCODING("VR128", ENCODING_VVVV)
ENCODING("VR256", ENCODING_VVVV)
ENCODING("FR32X", ENCODING_VVVV)
ENCODING("FR64X", ENCODING_VVVV)
ENCODING("VR128X", ENCODING_VVVV)
ENCODING("VR256X", ENCODING_VVVV)
ENCODING("VR512", ENCODING_VVVV)
ENCODING("VK8", ENCODING_VVVV)
ENCODING("VK16", ENCODING_VVVV)
errs() << "Unhandled VEX.vvvv register encoding " << s << "\n";
llvm_unreachable("Unhandled VEX.vvvv register encoding");
}
OperandEncoding RecognizableInstr::writemaskRegisterEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("VK8WM", ENCODING_WRITEMASK)
ENCODING("VK16WM", ENCODING_WRITEMASK)
errs() << "Unhandled mask register encoding " << s << "\n";
llvm_unreachable("Unhandled mask register encoding");
}
OperandEncoding RecognizableInstr::memoryEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("i16mem", ENCODING_RM)
ENCODING("i32mem", ENCODING_RM)
ENCODING("i64mem", ENCODING_RM)
ENCODING("i8mem", ENCODING_RM)
ENCODING("ssmem", ENCODING_RM)
ENCODING("sdmem", ENCODING_RM)
ENCODING("f128mem", ENCODING_RM)
ENCODING("f256mem", ENCODING_RM)
ENCODING("f512mem", ENCODING_RM)
ENCODING("f64mem", ENCODING_RM)
ENCODING("f32mem", ENCODING_RM)
ENCODING("i128mem", ENCODING_RM)
ENCODING("i256mem", ENCODING_RM)
ENCODING("i512mem", ENCODING_RM)
ENCODING("f80mem", ENCODING_RM)
ENCODING("lea32mem", ENCODING_RM)
ENCODING("lea64_32mem", ENCODING_RM)
ENCODING("lea64mem", ENCODING_RM)
ENCODING("opaque32mem", ENCODING_RM)
ENCODING("opaque48mem", ENCODING_RM)
ENCODING("opaque80mem", ENCODING_RM)
ENCODING("opaque512mem", ENCODING_RM)
ENCODING("vx32mem", ENCODING_RM)
ENCODING("vy32mem", ENCODING_RM)
ENCODING("vz32mem", ENCODING_RM)
ENCODING("vx64mem", ENCODING_RM)
ENCODING("vy64mem", ENCODING_RM)
ENCODING("vy64xmem", ENCODING_RM)
ENCODING("vz64mem", ENCODING_RM)
errs() << "Unhandled memory encoding " << s << "\n";
llvm_unreachable("Unhandled memory encoding");
}
OperandEncoding RecognizableInstr::relocationEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
if(!hasOpSizePrefix) {
// For instructions without an OpSize prefix, a declared 16-bit register or
// immediate encoding is special.
ENCODING("i16imm", ENCODING_IW)
}
ENCODING("i16imm", ENCODING_Iv)
ENCODING("i16i8imm", ENCODING_IB)
ENCODING("i32imm", ENCODING_Iv)
ENCODING("i32i8imm", ENCODING_IB)
ENCODING("i64i32imm", ENCODING_ID)
ENCODING("i64i8imm", ENCODING_IB)
ENCODING("i8imm", ENCODING_IB)
ENCODING("i64i32imm_pcrel", ENCODING_ID)
ENCODING("i16imm_pcrel", ENCODING_IW)
ENCODING("i32imm_pcrel", ENCODING_ID)
ENCODING("brtarget", ENCODING_Iv)
ENCODING("brtarget8", ENCODING_IB)
ENCODING("i64imm", ENCODING_IO)
ENCODING("offset8", ENCODING_Ia)
ENCODING("offset16", ENCODING_Ia)
ENCODING("offset32", ENCODING_Ia)
ENCODING("offset64", ENCODING_Ia)
errs() << "Unhandled relocation encoding " << s << "\n";
llvm_unreachable("Unhandled relocation encoding");
}
OperandEncoding RecognizableInstr::opcodeModifierEncodingFromString
(const std::string &s,
bool hasOpSizePrefix) {
ENCODING("RST", ENCODING_I)
ENCODING("GR32", ENCODING_Rv)
ENCODING("GR64", ENCODING_RO)
ENCODING("GR16", ENCODING_Rv)
ENCODING("GR8", ENCODING_RB)
ENCODING("GR16_NOAX", ENCODING_Rv)
ENCODING("GR32_NOAX", ENCODING_Rv)
ENCODING("GR64_NOAX", ENCODING_RO)
errs() << "Unhandled opcode modifier encoding " << s << "\n";
llvm_unreachable("Unhandled opcode modifier encoding");
}
#undef ENCODING