1 //===- EDEmitter.cpp - Generate instruction descriptions for ED -*- C++ -*-===//
3 // The LLVM Compiler Infrastructure
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
8 //===----------------------------------------------------------------------===//
10 // This tablegen backend is responsible for emitting a description of each
11 // instruction in a format that the enhanced disassembler can use to tokenize
12 // and parse instructions.
14 //===----------------------------------------------------------------------===//
16 #include "EDEmitter.h"
18 #include "AsmWriterInst.h"
19 #include "CodeGenTarget.h"
21 #include "llvm/TableGen/Record.h"
22 #include "llvm/MC/EDInstInfo.h"
23 #include "llvm/Support/ErrorHandling.h"
24 #include "llvm/Support/Format.h"
25 #include "llvm/Support/raw_ostream.h"
32 ///////////////////////////////////////////////////////////
33 // Support classes for emitting nested C data structures //
34 ///////////////////////////////////////////////////////////
41 std::vector<std::string> Entries;
43 EnumEmitter(const char *N) : Name(N) {
45 int addEntry(const char *e) {
46 Entries.push_back(std::string(e));
47 return Entries.size() - 1;
49 void emit(raw_ostream &o, unsigned int &i) {
50 o.indent(i) << "enum " << Name.c_str() << " {" << "\n";
53 unsigned int index = 0;
54 unsigned int numEntries = Entries.size();
55 for (index = 0; index < numEntries; ++index) {
56 o.indent(i) << Entries[index];
57 if (index < (numEntries - 1))
63 o.indent(i) << "};" << "\n";
66 void emitAsFlags(raw_ostream &o, unsigned int &i) {
67 o.indent(i) << "enum " << Name.c_str() << " {" << "\n";
70 unsigned int index = 0;
71 unsigned int numEntries = Entries.size();
72 unsigned int flag = 1;
73 for (index = 0; index < numEntries; ++index) {
74 o.indent(i) << Entries[index] << " = " << format("0x%x", flag);
75 if (index < (numEntries - 1))
82 o.indent(i) << "};" << "\n";
86 class ConstantEmitter {
88 virtual ~ConstantEmitter() { }
89 virtual void emit(raw_ostream &o, unsigned int &i) = 0;
92 class LiteralConstantEmitter : public ConstantEmitter {
100 LiteralConstantEmitter(int number = 0) :
104 void set(const char *string) {
109 bool is(const char *string) {
110 return !strcmp(String, string);
112 void emit(raw_ostream &o, unsigned int &i) {
120 class CompoundConstantEmitter : public ConstantEmitter {
122 unsigned int Padding;
123 std::vector<ConstantEmitter *> Entries;
125 CompoundConstantEmitter(unsigned int padding = 0) : Padding(padding) {
127 CompoundConstantEmitter &addEntry(ConstantEmitter *e) {
128 Entries.push_back(e);
132 ~CompoundConstantEmitter() {
133 while (Entries.size()) {
134 ConstantEmitter *entry = Entries.back();
139 void emit(raw_ostream &o, unsigned int &i) {
144 unsigned int numEntries = Entries.size();
146 unsigned int numToPrint;
149 if (numEntries > Padding) {
150 fprintf(stderr, "%u entries but %u padding\n", numEntries, Padding);
151 llvm_unreachable("More entries than padding");
153 numToPrint = Padding;
155 numToPrint = numEntries;
158 for (index = 0; index < numToPrint; ++index) {
160 if (index < numEntries)
161 Entries[index]->emit(o, i);
165 if (index < (numToPrint - 1))
175 class FlagsConstantEmitter : public ConstantEmitter {
177 std::vector<std::string> Flags;
179 FlagsConstantEmitter() {
181 FlagsConstantEmitter &addEntry(const char *f) {
182 Flags.push_back(std::string(f));
185 void emit(raw_ostream &o, unsigned int &i) {
187 unsigned int numFlags = Flags.size();
191 for (index = 0; index < numFlags; ++index) {
192 o << Flags[index].c_str();
193 if (index < (numFlags - 1))
200 EDEmitter::EDEmitter(RecordKeeper &R) : Records(R) {
203 /// populateOperandOrder - Accepts a CodeGenInstruction and generates its
204 /// AsmWriterInst for the desired assembly syntax, giving an ordered list of
205 /// operands in the order they appear in the printed instruction. Then, for
206 /// each entry in that list, determines the index of the same operand in the
207 /// CodeGenInstruction, and emits the resulting mapping into an array, filling
208 /// in unused slots with -1.
210 /// @arg operandOrder - The array that will be populated with the operand
211 /// mapping. Each entry will contain -1 (invalid index
212 /// into the operands present in the AsmString) or a number
213 /// representing an index in the operand descriptor array.
214 /// @arg inst - The instruction to use when looking up the operands
215 /// @arg syntax - The syntax to use, according to LLVM's enumeration
216 void populateOperandOrder(CompoundConstantEmitter *operandOrder,
217 const CodeGenInstruction &inst,
219 unsigned int numArgs = 0;
221 AsmWriterInst awInst(inst, syntax, -1, -1);
223 std::vector<AsmWriterOperand>::iterator operandIterator;
225 for (operandIterator = awInst.Operands.begin();
226 operandIterator != awInst.Operands.end();
228 if (operandIterator->OperandType ==
229 AsmWriterOperand::isMachineInstrOperand) {
230 operandOrder->addEntry(
231 new LiteralConstantEmitter(operandIterator->CGIOpNo));
237 /////////////////////////////////////////////////////
238 // Support functions for handling X86 instructions //
239 /////////////////////////////////////////////////////
241 #define SET(flag) { type->set(flag); return 0; }
243 #define REG(str) if (name == str) SET("kOperandTypeRegister");
244 #define MEM(str) if (name == str) SET("kOperandTypeX86Memory");
245 #define LEA(str) if (name == str) SET("kOperandTypeX86EffectiveAddress");
246 #define IMM(str) if (name == str) SET("kOperandTypeImmediate");
247 #define PCR(str) if (name == str) SET("kOperandTypeX86PCRelative");
249 /// X86TypeFromOpName - Processes the name of a single X86 operand (which is
250 /// actually its type) and translates it into an operand type
252 /// @arg flags - The type object to set
253 /// @arg name - The name of the operand
254 static int X86TypeFromOpName(LiteralConstantEmitter *type,
255 const std::string &name) {
321 PCR("i64i32imm_pcrel");
328 PCR("uncondbrtarget");
331 // all I, ARM mode only, conditional/unconditional
345 /// X86PopulateOperands - Handles all the operands in an X86 instruction, adding
346 /// the appropriate flags to their descriptors
348 /// @operandFlags - A reference the array of operand flag objects
349 /// @inst - The instruction to use as a source of information
350 static void X86PopulateOperands(
351 LiteralConstantEmitter *(&operandTypes)[EDIS_MAX_OPERANDS],
352 const CodeGenInstruction &inst) {
353 if (!inst.TheDef->isSubClassOf("X86Inst"))
357 unsigned int numOperands = inst.Operands.size();
359 for (index = 0; index < numOperands; ++index) {
360 const CGIOperandList::OperandInfo &operandInfo = inst.Operands[index];
361 Record &rec = *operandInfo.Rec;
363 if (X86TypeFromOpName(operandTypes[index], rec.getName()) &&
364 !rec.isSubClassOf("PointerLikeRegClass")) {
365 errs() << "Operand type: " << rec.getName().c_str() << "\n";
366 errs() << "Operand name: " << operandInfo.Name.c_str() << "\n";
367 errs() << "Instruction name: " << inst.TheDef->getName().c_str() << "\n";
368 llvm_unreachable("Unhandled type");
373 /// decorate1 - Decorates a named operand with a new flag
375 /// @operandFlags - The array of operand flag objects, which don't have names
376 /// @inst - The CodeGenInstruction, which provides a way to translate
377 /// between names and operand indices
378 /// @opName - The name of the operand
379 /// @flag - The name of the flag to add
380 static inline void decorate1(
381 FlagsConstantEmitter *(&operandFlags)[EDIS_MAX_OPERANDS],
382 const CodeGenInstruction &inst,
384 const char *opFlag) {
387 opIndex = inst.Operands.getOperandNamed(std::string(opName));
389 operandFlags[opIndex]->addEntry(opFlag);
392 #define DECORATE1(opName, opFlag) decorate1(operandFlags, inst, opName, opFlag)
394 #define MOV(source, target) { \
395 instType.set("kInstructionTypeMove"); \
396 DECORATE1(source, "kOperandFlagSource"); \
397 DECORATE1(target, "kOperandFlagTarget"); \
400 #define BRANCH(target) { \
401 instType.set("kInstructionTypeBranch"); \
402 DECORATE1(target, "kOperandFlagTarget"); \
405 #define PUSH(source) { \
406 instType.set("kInstructionTypePush"); \
407 DECORATE1(source, "kOperandFlagSource"); \
410 #define POP(target) { \
411 instType.set("kInstructionTypePop"); \
412 DECORATE1(target, "kOperandFlagTarget"); \
415 #define CALL(target) { \
416 instType.set("kInstructionTypeCall"); \
417 DECORATE1(target, "kOperandFlagTarget"); \
421 instType.set("kInstructionTypeReturn"); \
424 /// X86ExtractSemantics - Performs various checks on the name of an X86
425 /// instruction to determine what sort of an instruction it is and then adds
426 /// the appropriate flags to the instruction and its operands
428 /// @arg instType - A reference to the type for the instruction as a whole
429 /// @arg operandFlags - A reference to the array of operand flag object pointers
430 /// @arg inst - A reference to the original instruction
431 static void X86ExtractSemantics(
432 LiteralConstantEmitter &instType,
433 FlagsConstantEmitter *(&operandFlags)[EDIS_MAX_OPERANDS],
434 const CodeGenInstruction &inst) {
435 const std::string &name = inst.TheDef->getName();
437 if (name.find("MOV") != name.npos) {
438 if (name.find("MOV_V") != name.npos) {
439 // ignore (this is a pseudoinstruction)
440 } else if (name.find("MASK") != name.npos) {
441 // ignore (this is a masking move)
442 } else if (name.find("r0") != name.npos) {
443 // ignore (this is a pseudoinstruction)
444 } else if (name.find("PS") != name.npos ||
445 name.find("PD") != name.npos) {
446 // ignore (this is a shuffling move)
447 } else if (name.find("MOVS") != name.npos) {
448 // ignore (this is a string move)
449 } else if (name.find("_F") != name.npos) {
450 // TODO handle _F moves to ST(0)
451 } else if (name.find("a") != name.npos) {
452 // TODO handle moves to/from %ax
453 } else if (name.find("CMOV") != name.npos) {
455 } else if (name.find("PC") != name.npos) {
462 if (name.find("JMP") != name.npos ||
463 name.find("J") == 0) {
464 if (name.find("FAR") != name.npos && name.find("i") != name.npos) {
471 if (name.find("PUSH") != name.npos) {
472 if (name.find("CS") != name.npos ||
473 name.find("DS") != name.npos ||
474 name.find("ES") != name.npos ||
475 name.find("FS") != name.npos ||
476 name.find("GS") != name.npos ||
477 name.find("SS") != name.npos) {
478 instType.set("kInstructionTypePush");
479 // TODO add support for fixed operands
480 } else if (name.find("F") != name.npos) {
481 // ignore (this pushes onto the FP stack)
482 } else if (name.find("A") != name.npos) {
483 // ignore (pushes all GP registoers onto the stack)
484 } else if (name[name.length() - 1] == 'm') {
486 } else if (name.find("i") != name.npos) {
493 if (name.find("POP") != name.npos) {
494 if (name.find("POPCNT") != name.npos) {
495 // ignore (not a real pop)
496 } else if (name.find("CS") != name.npos ||
497 name.find("DS") != name.npos ||
498 name.find("ES") != name.npos ||
499 name.find("FS") != name.npos ||
500 name.find("GS") != name.npos ||
501 name.find("SS") != name.npos) {
502 instType.set("kInstructionTypePop");
503 // TODO add support for fixed operands
504 } else if (name.find("F") != name.npos) {
505 // ignore (this pops from the FP stack)
506 } else if (name.find("A") != name.npos) {
507 // ignore (pushes all GP registoers onto the stack)
508 } else if (name[name.length() - 1] == 'm') {
515 if (name.find("CALL") != name.npos) {
516 if (name.find("ADJ") != name.npos) {
517 // ignore (not a call)
518 } else if (name.find("SYSCALL") != name.npos) {
519 // ignore (doesn't go anywhere we know about)
520 } else if (name.find("VMCALL") != name.npos) {
521 // ignore (rather different semantics than a regular call)
522 } else if (name.find("FAR") != name.npos && name.find("i") != name.npos) {
529 if (name.find("RET") != name.npos) {
541 /////////////////////////////////////////////////////
542 // Support functions for handling ARM instructions //
543 /////////////////////////////////////////////////////
545 #define SET(flag) { type->set(flag); return 0; }
547 #define REG(str) if (name == str) SET("kOperandTypeRegister");
548 #define IMM(str) if (name == str) SET("kOperandTypeImmediate");
550 #define MISC(str, type) if (name == str) SET(type);
552 /// ARMFlagFromOpName - Processes the name of a single ARM operand (which is
553 /// actually its type) and translates it into an operand type
555 /// @arg type - The type object to set
556 /// @arg name - The name of the operand
557 static int ARMFlagFromOpName(LiteralConstantEmitter *type,
558 const std::string &name) {
576 REG("VecListThreeD");
579 REG("VecListOneDAllLanes");
580 REG("VecListTwoDAllLanes");
581 REG("VecListTwoQAllLanes");
586 IMM("i32imm_hilo16");
587 IMM("bf_inv_mask_imm");
590 IMM("jtblock_operand");
594 IMM("coproc_option_imm");
597 IMM("cpinst_operand");
629 IMM("imm0_65535_expr");
633 IMM("jt2block_operand");
634 IMM("t_imm0_1020s4");
642 IMM("neon_vcvt_imm32");
649 IMM("postidx_imm8s4");
653 IMM("VectorIndex16");
654 IMM("VectorIndex32");
656 MISC("brtarget", "kOperandTypeARMBranchTarget"); // ?
657 MISC("uncondbrtarget", "kOperandTypeARMBranchTarget"); // ?
658 MISC("t_brtarget", "kOperandTypeARMBranchTarget"); // ?
659 MISC("t_bcctarget", "kOperandTypeARMBranchTarget"); // ?
660 MISC("t_cbtarget", "kOperandTypeARMBranchTarget"); // ?
661 MISC("bltarget", "kOperandTypeARMBranchTarget"); // ?
663 MISC("br_target", "kOperandTypeARMBranchTarget"); // ?
664 MISC("bl_target", "kOperandTypeARMBranchTarget"); // ?
665 MISC("blx_target", "kOperandTypeARMBranchTarget"); // ?
667 MISC("t_bltarget", "kOperandTypeARMBranchTarget"); // ?
668 MISC("t_blxtarget", "kOperandTypeARMBranchTarget"); // ?
669 MISC("so_reg_imm", "kOperandTypeARMSoRegReg"); // R, R, I
670 MISC("so_reg_reg", "kOperandTypeARMSoRegImm"); // R, R, I
671 MISC("shift_so_reg_reg", "kOperandTypeARMSoRegReg"); // R, R, I
672 MISC("shift_so_reg_imm", "kOperandTypeARMSoRegImm"); // R, R, I
673 MISC("t2_so_reg", "kOperandTypeThumb2SoReg"); // R, I
674 MISC("so_imm", "kOperandTypeARMSoImm"); // I
675 MISC("rot_imm", "kOperandTypeARMRotImm"); // I
676 MISC("t2_so_imm", "kOperandTypeThumb2SoImm"); // I
677 MISC("so_imm2part", "kOperandTypeARMSoImm2Part"); // I
678 MISC("pred", "kOperandTypeARMPredicate"); // I, R
679 MISC("it_pred", "kOperandTypeARMPredicate"); // I
680 MISC("addrmode_imm12", "kOperandTypeAddrModeImm12"); // R, I
681 MISC("ldst_so_reg", "kOperandTypeLdStSOReg"); // R, R, I
682 MISC("postidx_reg", "kOperandTypeARMAddrMode3Offset"); // R, I
683 MISC("addrmode2", "kOperandTypeARMAddrMode2"); // R, R, I
684 MISC("am2offset_reg", "kOperandTypeARMAddrMode2Offset"); // R, I
685 MISC("am2offset_imm", "kOperandTypeARMAddrMode2Offset"); // R, I
686 MISC("addrmode3", "kOperandTypeARMAddrMode3"); // R, R, I
687 MISC("am3offset", "kOperandTypeARMAddrMode3Offset"); // R, I
688 MISC("ldstm_mode", "kOperandTypeARMLdStmMode"); // I
689 MISC("addrmode5", "kOperandTypeARMAddrMode5"); // R, I
690 MISC("addrmode6", "kOperandTypeARMAddrMode6"); // R, R, I, I
691 MISC("am6offset", "kOperandTypeARMAddrMode6Offset"); // R, I, I
692 MISC("addrmode6dup", "kOperandTypeARMAddrMode6"); // R, R, I, I
693 MISC("addrmode6oneL32", "kOperandTypeARMAddrMode6"); // R, R, I, I
694 MISC("addrmodepc", "kOperandTypeARMAddrModePC"); // R, I
695 MISC("addr_offset_none", "kOperandTypeARMAddrMode7"); // R
696 MISC("reglist", "kOperandTypeARMRegisterList"); // I, R, ...
697 MISC("dpr_reglist", "kOperandTypeARMDPRRegisterList"); // I, R, ...
698 MISC("spr_reglist", "kOperandTypeARMSPRRegisterList"); // I, R, ...
699 MISC("it_mask", "kOperandTypeThumbITMask"); // I
700 MISC("t2addrmode_reg", "kOperandTypeThumb2AddrModeReg"); // R
701 MISC("t2addrmode_posimm8", "kOperandTypeThumb2AddrModeImm8"); // R, I
702 MISC("t2addrmode_negimm8", "kOperandTypeThumb2AddrModeImm8"); // R, I
703 MISC("t2addrmode_imm8", "kOperandTypeThumb2AddrModeImm8"); // R, I
704 MISC("t2am_imm8_offset", "kOperandTypeThumb2AddrModeImm8Offset");//I
705 MISC("t2addrmode_imm12", "kOperandTypeThumb2AddrModeImm12"); // R, I
706 MISC("t2addrmode_so_reg", "kOperandTypeThumb2AddrModeSoReg"); // R, R, I
707 MISC("t2addrmode_imm8s4", "kOperandTypeThumb2AddrModeImm8s4"); // R, I
708 MISC("t2addrmode_imm0_1020s4", "kOperandTypeThumb2AddrModeImm8s4"); // R, I
709 MISC("t2am_imm8s4_offset", "kOperandTypeThumb2AddrModeImm8s4Offset");
711 MISC("tb_addrmode", "kOperandTypeARMTBAddrMode"); // I
712 MISC("t_addrmode_rrs1", "kOperandTypeThumbAddrModeRegS1"); // R, R
713 MISC("t_addrmode_rrs2", "kOperandTypeThumbAddrModeRegS2"); // R, R
714 MISC("t_addrmode_rrs4", "kOperandTypeThumbAddrModeRegS4"); // R, R
715 MISC("t_addrmode_is1", "kOperandTypeThumbAddrModeImmS1"); // R, I
716 MISC("t_addrmode_is2", "kOperandTypeThumbAddrModeImmS2"); // R, I
717 MISC("t_addrmode_is4", "kOperandTypeThumbAddrModeImmS4"); // R, I
718 MISC("t_addrmode_rr", "kOperandTypeThumbAddrModeRR"); // R, R
719 MISC("t_addrmode_sp", "kOperandTypeThumbAddrModeSP"); // R, I
720 MISC("t_addrmode_pc", "kOperandTypeThumbAddrModePC"); // R, I
721 MISC("addrmode_tbb", "kOperandTypeThumbAddrModeRR"); // R, R
722 MISC("addrmode_tbh", "kOperandTypeThumbAddrModeRR"); // R, R
733 /// ARMPopulateOperands - Handles all the operands in an ARM instruction, adding
734 /// the appropriate flags to their descriptors
736 /// @operandFlags - A reference the array of operand flag objects
737 /// @inst - The instruction to use as a source of information
738 static void ARMPopulateOperands(
739 LiteralConstantEmitter *(&operandTypes)[EDIS_MAX_OPERANDS],
740 const CodeGenInstruction &inst) {
741 if (!inst.TheDef->isSubClassOf("InstARM") &&
742 !inst.TheDef->isSubClassOf("InstThumb"))
746 unsigned int numOperands = inst.Operands.size();
748 if (numOperands > EDIS_MAX_OPERANDS) {
749 errs() << "numOperands == " << numOperands << " > " <<
750 EDIS_MAX_OPERANDS << '\n';
751 llvm_unreachable("Too many operands");
754 for (index = 0; index < numOperands; ++index) {
755 const CGIOperandList::OperandInfo &operandInfo = inst.Operands[index];
756 Record &rec = *operandInfo.Rec;
758 if (ARMFlagFromOpName(operandTypes[index], rec.getName())) {
759 errs() << "Operand type: " << rec.getName() << '\n';
760 errs() << "Operand name: " << operandInfo.Name << '\n';
761 errs() << "Instruction name: " << inst.TheDef->getName() << '\n';
762 throw("Unhandled type in EDEmitter");
767 #define BRANCH(target) { \
768 instType.set("kInstructionTypeBranch"); \
769 DECORATE1(target, "kOperandFlagTarget"); \
772 /// ARMExtractSemantics - Performs various checks on the name of an ARM
773 /// instruction to determine what sort of an instruction it is and then adds
774 /// the appropriate flags to the instruction and its operands
776 /// @arg instType - A reference to the type for the instruction as a whole
777 /// @arg operandTypes - A reference to the array of operand type object pointers
778 /// @arg operandFlags - A reference to the array of operand flag object pointers
779 /// @arg inst - A reference to the original instruction
780 static void ARMExtractSemantics(
781 LiteralConstantEmitter &instType,
782 LiteralConstantEmitter *(&operandTypes)[EDIS_MAX_OPERANDS],
783 FlagsConstantEmitter *(&operandFlags)[EDIS_MAX_OPERANDS],
784 const CodeGenInstruction &inst) {
785 const std::string &name = inst.TheDef->getName();
787 if (name == "tBcc" ||
796 if (name == "tBLr9" ||
797 name == "BLr9_pred" ||
798 name == "tBLXi_r9" ||
799 name == "tBLXr_r9" ||
806 opIndex = inst.Operands.getOperandNamed("func");
807 if (operandTypes[opIndex]->is("kOperandTypeImmediate"))
808 operandTypes[opIndex]->set("kOperandTypeARMBranchTarget");
814 /// populateInstInfo - Fills an array of InstInfos with information about each
815 /// instruction in a target
817 /// @arg infoArray - The array of InstInfo objects to populate
818 /// @arg target - The CodeGenTarget to use as a source of instructions
819 static void populateInstInfo(CompoundConstantEmitter &infoArray,
820 CodeGenTarget &target) {
821 const std::vector<const CodeGenInstruction*> &numberedInstructions =
822 target.getInstructionsByEnumValue();
825 unsigned int numInstructions = numberedInstructions.size();
827 for (index = 0; index < numInstructions; ++index) {
828 const CodeGenInstruction& inst = *numberedInstructions[index];
830 CompoundConstantEmitter *infoStruct = new CompoundConstantEmitter;
831 infoArray.addEntry(infoStruct);
833 LiteralConstantEmitter *instType = new LiteralConstantEmitter;
834 infoStruct->addEntry(instType);
836 LiteralConstantEmitter *numOperandsEmitter =
837 new LiteralConstantEmitter(inst.Operands.size());
838 infoStruct->addEntry(numOperandsEmitter);
840 CompoundConstantEmitter *operandTypeArray = new CompoundConstantEmitter;
841 infoStruct->addEntry(operandTypeArray);
843 LiteralConstantEmitter *operandTypes[EDIS_MAX_OPERANDS];
845 CompoundConstantEmitter *operandFlagArray = new CompoundConstantEmitter;
846 infoStruct->addEntry(operandFlagArray);
848 FlagsConstantEmitter *operandFlags[EDIS_MAX_OPERANDS];
850 for (unsigned operandIndex = 0;
851 operandIndex < EDIS_MAX_OPERANDS;
853 operandTypes[operandIndex] = new LiteralConstantEmitter;
854 operandTypeArray->addEntry(operandTypes[operandIndex]);
856 operandFlags[operandIndex] = new FlagsConstantEmitter;
857 operandFlagArray->addEntry(operandFlags[operandIndex]);
860 unsigned numSyntaxes = 0;
862 // We don't need to do anything for pseudo-instructions, as we'll never
863 // see them here. We'll only see real instructions.
864 // We still need to emit null initializers for everything.
865 if (!inst.isPseudo) {
866 if (target.getName() == "X86") {
867 X86PopulateOperands(operandTypes, inst);
868 X86ExtractSemantics(*instType, operandFlags, inst);
871 else if (target.getName() == "ARM") {
872 ARMPopulateOperands(operandTypes, inst);
873 ARMExtractSemantics(*instType, operandTypes, operandFlags, inst);
878 CompoundConstantEmitter *operandOrderArray = new CompoundConstantEmitter;
880 infoStruct->addEntry(operandOrderArray);
882 for (unsigned syntaxIndex = 0;
883 syntaxIndex < EDIS_MAX_SYNTAXES;
885 CompoundConstantEmitter *operandOrder =
886 new CompoundConstantEmitter(EDIS_MAX_OPERANDS);
888 operandOrderArray->addEntry(operandOrder);
890 if (syntaxIndex < numSyntaxes) {
891 populateOperandOrder(operandOrder, inst, syntaxIndex);
899 static void emitCommonEnums(raw_ostream &o, unsigned int &i) {
900 EnumEmitter operandTypes("OperandTypes");
901 operandTypes.addEntry("kOperandTypeNone");
902 operandTypes.addEntry("kOperandTypeImmediate");
903 operandTypes.addEntry("kOperandTypeRegister");
904 operandTypes.addEntry("kOperandTypeX86Memory");
905 operandTypes.addEntry("kOperandTypeX86EffectiveAddress");
906 operandTypes.addEntry("kOperandTypeX86PCRelative");
907 operandTypes.addEntry("kOperandTypeARMBranchTarget");
908 operandTypes.addEntry("kOperandTypeARMSoRegReg");
909 operandTypes.addEntry("kOperandTypeARMSoRegImm");
910 operandTypes.addEntry("kOperandTypeARMSoImm");
911 operandTypes.addEntry("kOperandTypeARMRotImm");
912 operandTypes.addEntry("kOperandTypeARMSoImm2Part");
913 operandTypes.addEntry("kOperandTypeARMPredicate");
914 operandTypes.addEntry("kOperandTypeAddrModeImm12");
915 operandTypes.addEntry("kOperandTypeLdStSOReg");
916 operandTypes.addEntry("kOperandTypeARMAddrMode2");
917 operandTypes.addEntry("kOperandTypeARMAddrMode2Offset");
918 operandTypes.addEntry("kOperandTypeARMAddrMode3");
919 operandTypes.addEntry("kOperandTypeARMAddrMode3Offset");
920 operandTypes.addEntry("kOperandTypeARMLdStmMode");
921 operandTypes.addEntry("kOperandTypeARMAddrMode5");
922 operandTypes.addEntry("kOperandTypeARMAddrMode6");
923 operandTypes.addEntry("kOperandTypeARMAddrMode6Offset");
924 operandTypes.addEntry("kOperandTypeARMAddrMode7");
925 operandTypes.addEntry("kOperandTypeARMAddrModePC");
926 operandTypes.addEntry("kOperandTypeARMRegisterList");
927 operandTypes.addEntry("kOperandTypeARMDPRRegisterList");
928 operandTypes.addEntry("kOperandTypeARMSPRRegisterList");
929 operandTypes.addEntry("kOperandTypeARMTBAddrMode");
930 operandTypes.addEntry("kOperandTypeThumbITMask");
931 operandTypes.addEntry("kOperandTypeThumbAddrModeImmS1");
932 operandTypes.addEntry("kOperandTypeThumbAddrModeImmS2");
933 operandTypes.addEntry("kOperandTypeThumbAddrModeImmS4");
934 operandTypes.addEntry("kOperandTypeThumbAddrModeRegS1");
935 operandTypes.addEntry("kOperandTypeThumbAddrModeRegS2");
936 operandTypes.addEntry("kOperandTypeThumbAddrModeRegS4");
937 operandTypes.addEntry("kOperandTypeThumbAddrModeRR");
938 operandTypes.addEntry("kOperandTypeThumbAddrModeSP");
939 operandTypes.addEntry("kOperandTypeThumbAddrModePC");
940 operandTypes.addEntry("kOperandTypeThumb2AddrModeReg");
941 operandTypes.addEntry("kOperandTypeThumb2SoReg");
942 operandTypes.addEntry("kOperandTypeThumb2SoImm");
943 operandTypes.addEntry("kOperandTypeThumb2AddrModeImm8");
944 operandTypes.addEntry("kOperandTypeThumb2AddrModeImm8Offset");
945 operandTypes.addEntry("kOperandTypeThumb2AddrModeImm12");
946 operandTypes.addEntry("kOperandTypeThumb2AddrModeSoReg");
947 operandTypes.addEntry("kOperandTypeThumb2AddrModeImm8s4");
948 operandTypes.addEntry("kOperandTypeThumb2AddrModeImm8s4Offset");
949 operandTypes.emit(o, i);
953 EnumEmitter operandFlags("OperandFlags");
954 operandFlags.addEntry("kOperandFlagSource");
955 operandFlags.addEntry("kOperandFlagTarget");
956 operandFlags.emitAsFlags(o, i);
960 EnumEmitter instructionTypes("InstructionTypes");
961 instructionTypes.addEntry("kInstructionTypeNone");
962 instructionTypes.addEntry("kInstructionTypeMove");
963 instructionTypes.addEntry("kInstructionTypeBranch");
964 instructionTypes.addEntry("kInstructionTypePush");
965 instructionTypes.addEntry("kInstructionTypePop");
966 instructionTypes.addEntry("kInstructionTypeCall");
967 instructionTypes.addEntry("kInstructionTypeReturn");
968 instructionTypes.emit(o, i);
973 void EDEmitter::run(raw_ostream &o) {
976 CompoundConstantEmitter infoArray;
977 CodeGenTarget target(Records);
979 populateInstInfo(infoArray, target);
981 emitCommonEnums(o, i);
983 o << "static const llvm::EDInstInfo instInfo" << target.getName() << "[] = ";
984 infoArray.emit(o, i);
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