//===----------------------------------------------------------------------===//
#include "TGParser.h"
-#include "llvm/TableGen/Record.h"
+#include "llvm/ADT/STLExtras.h"
+#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringExtras.h"
+#include "llvm/Support/CommandLine.h"
+#include "llvm/TableGen/Record.h"
#include <algorithm>
#include <sstream>
-#include "llvm/ADT/SmallVector.h"
-#include "llvm/Support/CommandLine.h"
using namespace llvm;
//===----------------------------------------------------------------------===//
namespace llvm {
struct SubClassReference {
- SMLoc RefLoc;
+ SMRange RefRange;
Record *Rec;
std::vector<Init*> TemplateArgs;
- SubClassReference() : Rec(0) {}
+ SubClassReference() : Rec(nullptr) {}
- bool isInvalid() const { return Rec == 0; }
+ bool isInvalid() const { return Rec == nullptr; }
};
struct SubMultiClassReference {
- SMLoc RefLoc;
+ SMRange RefRange;
MultiClass *MC;
std::vector<Init*> TemplateArgs;
- SubMultiClassReference() : MC(0) {}
+ SubMultiClassReference() : MC(nullptr) {}
- bool isInvalid() const { return MC == 0; }
+ bool isInvalid() const { return MC == nullptr; }
void dump() const;
};
} // end namespace llvm
bool TGParser::AddValue(Record *CurRec, SMLoc Loc, const RecordVal &RV) {
- if (CurRec == 0)
+ if (!CurRec)
CurRec = &CurMultiClass->Rec;
if (RecordVal *ERV = CurRec->getValue(RV.getNameInit())) {
const std::vector<unsigned> &BitList, Init *V) {
if (!V) return false;
- if (CurRec == 0) CurRec = &CurMultiClass->Rec;
+ if (!CurRec) CurRec = &CurMultiClass->Rec;
RecordVal *RV = CurRec->getValue(ValName);
- if (RV == 0)
+ if (!RV)
return Error(Loc, "Value '" + ValName->getAsUnquotedString()
+ "' unknown!");
// Do not allow assignments like 'X = X'. This will just cause infinite loops
// in the resolution machinery.
if (BitList.empty())
- if (VarInit *VI = dynamic_cast<VarInit*>(V))
+ if (VarInit *VI = dyn_cast<VarInit>(V))
if (VI->getNameInit() == ValName)
return false;
// initializer.
//
if (!BitList.empty()) {
- BitsInit *CurVal = dynamic_cast<BitsInit*>(RV->getValue());
- if (CurVal == 0)
+ BitsInit *CurVal = dyn_cast<BitsInit>(RV->getValue());
+ if (!CurVal)
return Error(Loc, "Value '" + ValName->getAsUnquotedString()
+ "' is not a bits type");
// Convert the incoming value to a bits type of the appropriate size...
Init *BI = V->convertInitializerTo(BitsRecTy::get(BitList.size()));
- if (BI == 0) {
- V->convertInitializerTo(BitsRecTy::get(BitList.size()));
+ if (!BI) {
return Error(Loc, "Initializer is not compatible with bit range");
}
// We should have a BitsInit type now.
- BitsInit *BInit = dynamic_cast<BitsInit*>(BI);
- assert(BInit != 0);
+ BitsInit *BInit = dyn_cast<BitsInit>(BI);
+ assert(BInit != nullptr);
SmallVector<Init *, 16> NewBits(CurVal->getNumBits());
}
for (unsigned i = 0, e = CurVal->getNumBits(); i != e; ++i)
- if (NewBits[i] == 0)
+ if (!NewBits[i])
NewBits[i] = CurVal->getBit(i);
V = BitsInit::get(NewBits);
}
- if (RV->setValue(V))
+ if (RV->setValue(V)) {
+ std::string InitType = "";
+ if (BitsInit *BI = dyn_cast<BitsInit>(V)) {
+ InitType = (Twine("' of type bit initializer with length ") +
+ Twine(BI->getNumBits())).str();
+ }
return Error(Loc, "Value '" + ValName->getAsUnquotedString() + "' of type '"
+ RV->getType()->getAsString() +
"' is incompatible with initializer '" + V->getAsString()
+ + InitType
+ "'");
+ }
return false;
}
// Add all of the values in the subclass into the current class.
const std::vector<RecordVal> &Vals = SC->getValues();
for (unsigned i = 0, e = Vals.size(); i != e; ++i)
- if (AddValue(CurRec, SubClass.RefLoc, Vals[i]))
+ if (AddValue(CurRec, SubClass.RefRange.Start, Vals[i]))
return true;
const std::vector<Init *> &TArgs = SC->getTemplateArgs();
// Ensure that an appropriate number of template arguments are specified.
if (TArgs.size() < SubClass.TemplateArgs.size())
- return Error(SubClass.RefLoc, "More template args specified than expected");
+ return Error(SubClass.RefRange.Start,
+ "More template args specified than expected");
// Loop over all of the template arguments, setting them to the specified
// value or leaving them as the default if necessary.
for (unsigned i = 0, e = TArgs.size(); i != e; ++i) {
if (i < SubClass.TemplateArgs.size()) {
// If a value is specified for this template arg, set it now.
- if (SetValue(CurRec, SubClass.RefLoc, TArgs[i], std::vector<unsigned>(),
- SubClass.TemplateArgs[i]))
+ if (SetValue(CurRec, SubClass.RefRange.Start, TArgs[i],
+ std::vector<unsigned>(), SubClass.TemplateArgs[i]))
return true;
// Resolve it next.
CurRec->removeValue(TArgs[i]);
} else if (!CurRec->getValue(TArgs[i])->getValue()->isComplete()) {
- return Error(SubClass.RefLoc,"Value not specified for template argument #"
+ return Error(SubClass.RefRange.Start,
+ "Value not specified for template argument #"
+ utostr(i) + " (" + TArgs[i]->getAsUnquotedString()
+ ") of subclass '" + SC->getNameInitAsString() + "'!");
}
// Since everything went well, we can now set the "superclass" list for the
// current record.
const std::vector<Record*> &SCs = SC->getSuperClasses();
+ ArrayRef<SMRange> SCRanges = SC->getSuperClassRanges();
for (unsigned i = 0, e = SCs.size(); i != e; ++i) {
if (CurRec->isSubClassOf(SCs[i]))
- return Error(SubClass.RefLoc,
+ return Error(SubClass.RefRange.Start,
"Already subclass of '" + SCs[i]->getName() + "'!\n");
- CurRec->addSuperClass(SCs[i]);
+ CurRec->addSuperClass(SCs[i], SCRanges[i]);
}
if (CurRec->isSubClassOf(SC))
- return Error(SubClass.RefLoc,
+ return Error(SubClass.RefRange.Start,
"Already subclass of '" + SC->getName() + "'!\n");
- CurRec->addSuperClass(SC);
+ CurRec->addSuperClass(SC, SubClass.RefRange);
return false;
}
// Add all of the values in the subclass into the current class.
const std::vector<RecordVal> &SMCVals = SMC->Rec.getValues();
for (unsigned i = 0, e = SMCVals.size(); i != e; ++i)
- if (AddValue(CurRec, SubMultiClass.RefLoc, SMCVals[i]))
+ if (AddValue(CurRec, SubMultiClass.RefRange.Start, SMCVals[i]))
return true;
- int newDefStart = CurMC->DefPrototypes.size();
+ unsigned newDefStart = CurMC->DefPrototypes.size();
// Add all of the defs in the subclass into the current multiclass.
for (MultiClass::RecordVector::const_iterator i = SMC->DefPrototypes.begin(),
i != iend;
++i) {
// Clone the def and add it to the current multiclass
- Record *NewDef = new Record(**i);
+ auto NewDef = make_unique<Record>(**i);
// Add all of the values in the superclass into the current def.
for (unsigned i = 0, e = MCVals.size(); i != e; ++i)
- if (AddValue(NewDef, SubMultiClass.RefLoc, MCVals[i]))
+ if (AddValue(NewDef.get(), SubMultiClass.RefRange.Start, MCVals[i]))
return true;
- CurMC->DefPrototypes.push_back(NewDef);
+ CurMC->DefPrototypes.push_back(std::move(NewDef));
}
const std::vector<Init *> &SMCTArgs = SMC->Rec.getTemplateArgs();
// Ensure that an appropriate number of template arguments are
// specified.
if (SMCTArgs.size() < SubMultiClass.TemplateArgs.size())
- return Error(SubMultiClass.RefLoc,
+ return Error(SubMultiClass.RefRange.Start,
"More template args specified than expected");
// Loop over all of the template arguments, setting them to the specified
if (i < SubMultiClass.TemplateArgs.size()) {
// If a value is specified for this template arg, set it in the
// superclass now.
- if (SetValue(CurRec, SubMultiClass.RefLoc, SMCTArgs[i],
+ if (SetValue(CurRec, SubMultiClass.RefRange.Start, SMCTArgs[i],
std::vector<unsigned>(),
SubMultiClass.TemplateArgs[i]))
return true;
// If a value is specified for this template arg, set it in the
// new defs now.
- for (MultiClass::RecordVector::iterator j =
- CurMC->DefPrototypes.begin() + newDefStart,
- jend = CurMC->DefPrototypes.end();
- j != jend;
- ++j) {
- Record *Def = *j;
-
- if (SetValue(Def, SubMultiClass.RefLoc, SMCTArgs[i],
+ for (const auto &Def :
+ makeArrayRef(CurMC->DefPrototypes).slice(newDefStart)) {
+ if (SetValue(Def.get(), SubMultiClass.RefRange.Start, SMCTArgs[i],
std::vector<unsigned>(),
SubMultiClass.TemplateArgs[i]))
return true;
Def->removeValue(SMCTArgs[i]);
}
} else if (!CurRec->getValue(SMCTArgs[i])->getValue()->isComplete()) {
- return Error(SubMultiClass.RefLoc,
+ return Error(SubMultiClass.RefRange.Start,
"Value not specified for template argument #"
+ utostr(i) + " (" + SMCTArgs[i]->getAsUnquotedString()
+ ") of subclass '" + SMC->Rec.getNameInitAsString() + "'!");
if (IterVals.size() != Loops.size()) {
assert(IterVals.size() < Loops.size());
ForeachLoop &CurLoop = Loops[IterVals.size()];
- ListInit *List = dynamic_cast<ListInit *>(CurLoop.ListValue);
- if (List == 0) {
+ ListInit *List = dyn_cast<ListInit>(CurLoop.ListValue);
+ if (!List) {
Error(Loc, "Loop list is not a list");
return true;
}
// Process each value.
for (int64_t i = 0; i < List->getSize(); ++i) {
- Init *ItemVal = List->resolveListElementReference(*CurRec, 0, i);
+ Init *ItemVal = List->resolveListElementReference(*CurRec, nullptr, i);
IterVals.push_back(IterRecord(CurLoop.IterVar, ItemVal));
if (ProcessForeachDefs(CurRec, Loc, IterVals))
return true;
// This is the bottom of the recursion. We have all of the iterator values
// for this point in the iteration space. Instantiate a new record to
// reflect this combination of values.
- Record *IterRec = new Record(*CurRec);
+ auto IterRec = make_unique<Record>(*CurRec);
// Set the iterator values now.
for (unsigned i = 0, e = IterVals.size(); i != e; ++i) {
VarInit *IterVar = IterVals[i].IterVar;
- TypedInit *IVal = dynamic_cast<TypedInit *>(IterVals[i].IterValue);
- if (IVal == 0) {
- Error(Loc, "foreach iterator value is untyped");
- return true;
- }
+ TypedInit *IVal = dyn_cast<TypedInit>(IterVals[i].IterValue);
+ if (!IVal)
+ return Error(Loc, "foreach iterator value is untyped");
IterRec->addValue(RecordVal(IterVar->getName(), IVal->getType(), false));
- if (SetValue(IterRec, Loc, IterVar->getName(),
- std::vector<unsigned>(), IVal)) {
- Error(Loc, "when instantiating this def");
- return true;
- }
+ if (SetValue(IterRec.get(), Loc, IterVar->getName(),
+ std::vector<unsigned>(), IVal))
+ return Error(Loc, "when instantiating this def");
// Resolve it next.
IterRec->resolveReferencesTo(IterRec->getValue(IterVar->getName()));
}
if (Records.getDef(IterRec->getNameInitAsString())) {
- Error(Loc, "def already exists: " + IterRec->getNameInitAsString());
- return true;
+ // If this record is anonymous, it's no problem, just generate a new name
+ if (!IterRec->isAnonymous())
+ return Error(Loc, "def already exists: " +IterRec->getNameInitAsString());
+
+ IterRec->setName(GetNewAnonymousName());
}
- Records.addDef(IterRec);
- IterRec->resolveReferences();
+ Record *IterRecSave = IterRec.get(); // Keep a copy before release.
+ Records.addDef(std::move(IterRec));
+ IterRecSave->resolveReferences();
return false;
}
K == tgtok::MultiClass || K == tgtok::Foreach;
}
-static std::string GetNewAnonymousName() {
- static unsigned AnonCounter = 0;
- return "anonymous."+utostr(AnonCounter++);
+/// GetNewAnonymousName - Generate a unique anonymous name that can be used as
+/// an identifier.
+std::string TGParser::GetNewAnonymousName() {
+ return "anonymous_" + utostr(AnonCounter++);
}
/// ParseObjectName - If an object name is specified, return it. Otherwise,
-/// return an anonymous name.
+/// return 0.
/// ObjectName ::= Value [ '#' Value ]*
/// ObjectName ::= /*empty*/
///
// These are all of the tokens that can begin an object body.
// Some of these can also begin values but we disallow those cases
// because they are unlikely to be useful.
- return StringInit::get(GetNewAnonymousName());
+ return nullptr;
default:
break;
}
- Record *CurRec = 0;
+ Record *CurRec = nullptr;
if (CurMultiClass)
CurRec = &CurMultiClass->Rec;
- RecTy *Type = 0;
+ RecTy *Type = nullptr;
if (CurRec) {
- const TypedInit *CurRecName =
- dynamic_cast<const TypedInit *>(CurRec->getNameInit());
+ const TypedInit *CurRecName = dyn_cast<TypedInit>(CurRec->getNameInit());
if (!CurRecName) {
TokError("Record name is not typed!");
- return 0;
+ return nullptr;
}
Type = CurRecName->getType();
}
Record *TGParser::ParseClassID() {
if (Lex.getCode() != tgtok::Id) {
TokError("expected name for ClassID");
- return 0;
+ return nullptr;
}
Record *Result = Records.getClass(Lex.getCurStrVal());
- if (Result == 0)
+ if (!Result)
TokError("Couldn't find class '" + Lex.getCurStrVal() + "'");
Lex.Lex();
///
MultiClass *TGParser::ParseMultiClassID() {
if (Lex.getCode() != tgtok::Id) {
- TokError("expected name for ClassID");
- return 0;
+ TokError("expected name for MultiClassID");
+ return nullptr;
}
- MultiClass *Result = MultiClasses[Lex.getCurStrVal()];
- if (Result == 0)
- TokError("Couldn't find class '" + Lex.getCurStrVal() + "'");
-
- Lex.Lex();
- return Result;
-}
-
-Record *TGParser::ParseDefmID() {
- if (Lex.getCode() != tgtok::Id) {
- TokError("expected multiclass name");
- return 0;
- }
-
- MultiClass *MC = MultiClasses[Lex.getCurStrVal()];
- if (MC == 0) {
+ MultiClass *Result = MultiClasses[Lex.getCurStrVal()].get();
+ if (!Result)
TokError("Couldn't find multiclass '" + Lex.getCurStrVal() + "'");
- return 0;
- }
Lex.Lex();
- return &MC->Rec;
+ return Result;
}
-
/// ParseSubClassReference - Parse a reference to a subclass or to a templated
/// subclass. This returns a SubClassRefTy with a null Record* on error.
///
SubClassReference TGParser::
ParseSubClassReference(Record *CurRec, bool isDefm) {
SubClassReference Result;
- Result.RefLoc = Lex.getLoc();
+ Result.RefRange.Start = Lex.getLoc();
- if (isDefm)
- Result.Rec = ParseDefmID();
- else
+ if (isDefm) {
+ if (MultiClass *MC = ParseMultiClassID())
+ Result.Rec = &MC->Rec;
+ } else {
Result.Rec = ParseClassID();
- if (Result.Rec == 0) return Result;
+ }
+ if (!Result.Rec) return Result;
// If there is no template arg list, we're done.
- if (Lex.getCode() != tgtok::less)
+ if (Lex.getCode() != tgtok::less) {
+ Result.RefRange.End = Lex.getLoc();
return Result;
+ }
Lex.Lex(); // Eat the '<'
if (Lex.getCode() == tgtok::greater) {
TokError("subclass reference requires a non-empty list of template values");
- Result.Rec = 0;
+ Result.Rec = nullptr;
return Result;
}
Result.TemplateArgs = ParseValueList(CurRec, Result.Rec);
if (Result.TemplateArgs.empty()) {
- Result.Rec = 0; // Error parsing value list.
+ Result.Rec = nullptr; // Error parsing value list.
return Result;
}
if (Lex.getCode() != tgtok::greater) {
TokError("expected '>' in template value list");
- Result.Rec = 0;
+ Result.Rec = nullptr;
return Result;
}
Lex.Lex();
+ Result.RefRange.End = Lex.getLoc();
return Result;
}
SubMultiClassReference TGParser::
ParseSubMultiClassReference(MultiClass *CurMC) {
SubMultiClassReference Result;
- Result.RefLoc = Lex.getLoc();
+ Result.RefRange.Start = Lex.getLoc();
Result.MC = ParseMultiClassID();
- if (Result.MC == 0) return Result;
+ if (!Result.MC) return Result;
// If there is no template arg list, we're done.
- if (Lex.getCode() != tgtok::less)
+ if (Lex.getCode() != tgtok::less) {
+ Result.RefRange.End = Lex.getLoc();
return Result;
+ }
Lex.Lex(); // Eat the '<'
if (Lex.getCode() == tgtok::greater) {
TokError("subclass reference requires a non-empty list of template values");
- Result.MC = 0;
+ Result.MC = nullptr;
return Result;
}
Result.TemplateArgs = ParseValueList(&CurMC->Rec, &Result.MC->Rec);
if (Result.TemplateArgs.empty()) {
- Result.MC = 0; // Error parsing value list.
+ Result.MC = nullptr; // Error parsing value list.
return Result;
}
if (Lex.getCode() != tgtok::greater) {
TokError("expected '>' in template value list");
- Result.MC = 0;
+ Result.MC = nullptr;
return Result;
}
Lex.Lex();
+ Result.RefRange.End = Lex.getLoc();
return Result;
}
///
RecTy *TGParser::ParseType() {
switch (Lex.getCode()) {
- default: TokError("Unknown token when expecting a type"); return 0;
+ default: TokError("Unknown token when expecting a type"); return nullptr;
case tgtok::String: Lex.Lex(); return StringRecTy::get();
case tgtok::Code: Lex.Lex(); return StringRecTy::get();
case tgtok::Bit: Lex.Lex(); return BitRecTy::get();
case tgtok::Dag: Lex.Lex(); return DagRecTy::get();
case tgtok::Id:
if (Record *R = ParseClassID()) return RecordRecTy::get(R);
- return 0;
+ return nullptr;
case tgtok::Bits: {
if (Lex.Lex() != tgtok::less) { // Eat 'bits'
TokError("expected '<' after bits type");
- return 0;
+ return nullptr;
}
if (Lex.Lex() != tgtok::IntVal) { // Eat '<'
TokError("expected integer in bits<n> type");
- return 0;
+ return nullptr;
}
uint64_t Val = Lex.getCurIntVal();
if (Lex.Lex() != tgtok::greater) { // Eat count.
TokError("expected '>' at end of bits<n> type");
- return 0;
+ return nullptr;
}
Lex.Lex(); // Eat '>'
return BitsRecTy::get(Val);
case tgtok::List: {
if (Lex.Lex() != tgtok::less) { // Eat 'bits'
TokError("expected '<' after list type");
- return 0;
+ return nullptr;
}
Lex.Lex(); // Eat '<'
RecTy *SubType = ParseType();
- if (SubType == 0) return 0;
+ if (!SubType) return nullptr;
if (Lex.getCode() != tgtok::greater) {
TokError("expected '>' at end of list<ty> type");
- return 0;
+ return nullptr;
}
Lex.Lex(); // Eat '>'
return ListRecTy::get(SubType);
}
}
-/// ParseIDValue - Parse an ID as a value and decode what it means.
-///
-/// IDValue ::= ID [def local value]
-/// IDValue ::= ID [def template arg]
-/// IDValue ::= ID [multiclass local value]
-/// IDValue ::= ID [multiclass template argument]
-/// IDValue ::= ID [def name]
-///
-Init *TGParser::ParseIDValue(Record *CurRec, IDParseMode Mode) {
- assert(Lex.getCode() == tgtok::Id && "Expected ID in ParseIDValue");
- std::string Name = Lex.getCurStrVal();
- SMLoc Loc = Lex.getLoc();
- Lex.Lex();
- return ParseIDValue(CurRec, Name, Loc);
-}
-
/// ParseIDValue - This is just like ParseIDValue above, but it assumes the ID
/// has already been read.
Init *TGParser::ParseIDValue(Record *CurRec,
for (LoopVector::iterator i = Loops.begin(), iend = Loops.end();
i != iend;
++i) {
- VarInit *IterVar = dynamic_cast<VarInit *>(i->IterVar);
+ VarInit *IterVar = dyn_cast<VarInit>(i->IterVar);
if (IterVar && IterVar->getName() == Name)
return IterVar;
}
if (Mode == ParseValueMode) {
Error(NameLoc, "Variable not defined: '" + Name + "'");
- return 0;
+ return nullptr;
}
return StringInit::get(Name);
///
/// Operation ::= XOperator ['<' Type '>'] '(' Args ')'
///
-Init *TGParser::ParseOperation(Record *CurRec) {
+Init *TGParser::ParseOperation(Record *CurRec, RecTy *ItemType) {
switch (Lex.getCode()) {
default:
TokError("unknown operation");
- return 0;
+ return nullptr;
case tgtok::XHead:
case tgtok::XTail:
case tgtok::XEmpty:
case tgtok::XCast: { // Value ::= !unop '(' Value ')'
UnOpInit::UnaryOp Code;
- RecTy *Type = 0;
+ RecTy *Type = nullptr;
switch (Lex.getCode()) {
default: llvm_unreachable("Unhandled code!");
Type = ParseOperatorType();
- if (Type == 0) {
+ if (!Type) {
TokError("did not get type for unary operator");
- return 0;
+ return nullptr;
}
break;
}
if (Lex.getCode() != tgtok::l_paren) {
TokError("expected '(' after unary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '('
Init *LHS = ParseValue(CurRec);
- if (LHS == 0) return 0;
+ if (!LHS) return nullptr;
if (Code == UnOpInit::HEAD
|| Code == UnOpInit::TAIL
|| Code == UnOpInit::EMPTY) {
- ListInit *LHSl = dynamic_cast<ListInit*>(LHS);
- StringInit *LHSs = dynamic_cast<StringInit*>(LHS);
- TypedInit *LHSt = dynamic_cast<TypedInit*>(LHS);
- if (LHSl == 0 && LHSs == 0 && LHSt == 0) {
+ ListInit *LHSl = dyn_cast<ListInit>(LHS);
+ StringInit *LHSs = dyn_cast<StringInit>(LHS);
+ TypedInit *LHSt = dyn_cast<TypedInit>(LHS);
+ if (!LHSl && !LHSs && !LHSt) {
TokError("expected list or string type argument in unary operator");
- return 0;
+ return nullptr;
}
if (LHSt) {
- ListRecTy *LType = dynamic_cast<ListRecTy*>(LHSt->getType());
- StringRecTy *SType = dynamic_cast<StringRecTy*>(LHSt->getType());
- if (LType == 0 && SType == 0) {
- TokError("expected list or string type argumnet in unary operator");
- return 0;
+ ListRecTy *LType = dyn_cast<ListRecTy>(LHSt->getType());
+ StringRecTy *SType = dyn_cast<StringRecTy>(LHSt->getType());
+ if (!LType && !SType) {
+ TokError("expected list or string type argument in unary operator");
+ return nullptr;
}
}
if (Code == UnOpInit::HEAD
|| Code == UnOpInit::TAIL) {
- if (LHSl == 0 && LHSt == 0) {
- TokError("expected list type argumnet in unary operator");
- return 0;
+ if (!LHSl && !LHSt) {
+ TokError("expected list type argument in unary operator");
+ return nullptr;
}
if (LHSl && LHSl->getSize() == 0) {
TokError("empty list argument in unary operator");
- return 0;
+ return nullptr;
}
if (LHSl) {
Init *Item = LHSl->getElement(0);
- TypedInit *Itemt = dynamic_cast<TypedInit*>(Item);
- if (Itemt == 0) {
+ TypedInit *Itemt = dyn_cast<TypedInit>(Item);
+ if (!Itemt) {
TokError("untyped list element in unary operator");
- return 0;
+ return nullptr;
}
if (Code == UnOpInit::HEAD) {
Type = Itemt->getType();
}
} else {
assert(LHSt && "expected list type argument in unary operator");
- ListRecTy *LType = dynamic_cast<ListRecTy*>(LHSt->getType());
- if (LType == 0) {
- TokError("expected list type argumnet in unary operator");
- return 0;
+ ListRecTy *LType = dyn_cast<ListRecTy>(LHSt->getType());
+ if (!LType) {
+ TokError("expected list type argument in unary operator");
+ return nullptr;
}
if (Code == UnOpInit::HEAD) {
Type = LType->getElementType();
if (Lex.getCode() != tgtok::r_paren) {
TokError("expected ')' in unary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ')'
return (UnOpInit::get(Code, LHS, Type))->Fold(CurRec, CurMultiClass);
}
case tgtok::XConcat:
+ case tgtok::XADD:
+ case tgtok::XAND:
case tgtok::XSRA:
case tgtok::XSRL:
case tgtok::XSHL:
case tgtok::XEq:
+ case tgtok::XListConcat:
case tgtok::XStrConcat: { // Value ::= !binop '(' Value ',' Value ')'
tgtok::TokKind OpTok = Lex.getCode();
SMLoc OpLoc = Lex.getLoc();
Lex.Lex(); // eat the operation
BinOpInit::BinaryOp Code;
- RecTy *Type = 0;
+ RecTy *Type = nullptr;
switch (OpTok) {
default: llvm_unreachable("Unhandled code!");
case tgtok::XConcat: Code = BinOpInit::CONCAT;Type = DagRecTy::get(); break;
+ case tgtok::XADD: Code = BinOpInit::ADD; Type = IntRecTy::get(); break;
+ case tgtok::XAND: Code = BinOpInit::AND; Type = IntRecTy::get(); break;
case tgtok::XSRA: Code = BinOpInit::SRA; Type = IntRecTy::get(); break;
case tgtok::XSRL: Code = BinOpInit::SRL; Type = IntRecTy::get(); break;
case tgtok::XSHL: Code = BinOpInit::SHL; Type = IntRecTy::get(); break;
case tgtok::XEq: Code = BinOpInit::EQ; Type = BitRecTy::get(); break;
+ case tgtok::XListConcat:
+ Code = BinOpInit::LISTCONCAT;
+ // We don't know the list type until we parse the first argument
+ break;
case tgtok::XStrConcat:
Code = BinOpInit::STRCONCAT;
Type = StringRecTy::get();
if (Lex.getCode() != tgtok::l_paren) {
TokError("expected '(' after binary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '('
SmallVector<Init*, 2> InitList;
InitList.push_back(ParseValue(CurRec));
- if (InitList.back() == 0) return 0;
+ if (!InitList.back()) return nullptr;
while (Lex.getCode() == tgtok::comma) {
Lex.Lex(); // eat the ','
InitList.push_back(ParseValue(CurRec));
- if (InitList.back() == 0) return 0;
+ if (!InitList.back()) return nullptr;
}
if (Lex.getCode() != tgtok::r_paren) {
TokError("expected ')' in operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ')'
+ // If we are doing !listconcat, we should know the type by now
+ if (OpTok == tgtok::XListConcat) {
+ if (VarInit *Arg0 = dyn_cast<VarInit>(InitList[0]))
+ Type = Arg0->getType();
+ else if (ListInit *Arg0 = dyn_cast<ListInit>(InitList[0]))
+ Type = Arg0->getType();
+ else {
+ InitList[0]->dump();
+ Error(OpLoc, "expected a list");
+ return nullptr;
+ }
+ }
+
// We allow multiple operands to associative operators like !strconcat as
// shorthand for nesting them.
- if (Code == BinOpInit::STRCONCAT) {
+ if (Code == BinOpInit::STRCONCAT || Code == BinOpInit::LISTCONCAT) {
while (InitList.size() > 2) {
Init *RHS = InitList.pop_back_val();
RHS = (BinOpInit::get(Code, InitList.back(), RHS, Type))
->Fold(CurRec, CurMultiClass);
Error(OpLoc, "expected two operands to operator");
- return 0;
+ return nullptr;
}
case tgtok::XIf:
case tgtok::XForEach:
case tgtok::XSubst: { // Value ::= !ternop '(' Value ',' Value ',' Value ')'
TernOpInit::TernaryOp Code;
- RecTy *Type = 0;
+ RecTy *Type = nullptr;
tgtok::TokKind LexCode = Lex.getCode();
Lex.Lex(); // eat the operation
}
if (Lex.getCode() != tgtok::l_paren) {
TokError("expected '(' after ternary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '('
Init *LHS = ParseValue(CurRec);
- if (LHS == 0) return 0;
+ if (!LHS) return nullptr;
if (Lex.getCode() != tgtok::comma) {
TokError("expected ',' in ternary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ','
- Init *MHS = ParseValue(CurRec);
- if (MHS == 0) return 0;
+ Init *MHS = ParseValue(CurRec, ItemType);
+ if (!MHS)
+ return nullptr;
if (Lex.getCode() != tgtok::comma) {
TokError("expected ',' in ternary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ','
- Init *RHS = ParseValue(CurRec);
- if (RHS == 0) return 0;
+ Init *RHS = ParseValue(CurRec, ItemType);
+ if (!RHS)
+ return nullptr;
if (Lex.getCode() != tgtok::r_paren) {
TokError("expected ')' in binary operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ')'
switch (LexCode) {
default: llvm_unreachable("Unhandled code!");
case tgtok::XIf: {
- // FIXME: The `!if' operator doesn't handle non-TypedInit well at
- // all. This can be made much more robust.
- TypedInit *MHSt = dynamic_cast<TypedInit*>(MHS);
- TypedInit *RHSt = dynamic_cast<TypedInit*>(RHS);
-
- RecTy *MHSTy = 0;
- RecTy *RHSTy = 0;
-
- if (MHSt == 0 && RHSt == 0) {
- BitsInit *MHSbits = dynamic_cast<BitsInit*>(MHS);
- BitsInit *RHSbits = dynamic_cast<BitsInit*>(RHS);
-
- if (MHSbits && RHSbits &&
- MHSbits->getNumBits() == RHSbits->getNumBits()) {
- Type = BitRecTy::get();
- break;
- } else {
- BitInit *MHSbit = dynamic_cast<BitInit*>(MHS);
- BitInit *RHSbit = dynamic_cast<BitInit*>(RHS);
+ RecTy *MHSTy = nullptr;
+ RecTy *RHSTy = nullptr;
- if (MHSbit && RHSbit) {
- Type = BitRecTy::get();
- break;
- }
- }
- } else if (MHSt != 0 && RHSt != 0) {
+ if (TypedInit *MHSt = dyn_cast<TypedInit>(MHS))
MHSTy = MHSt->getType();
+ if (BitsInit *MHSbits = dyn_cast<BitsInit>(MHS))
+ MHSTy = BitsRecTy::get(MHSbits->getNumBits());
+ if (isa<BitInit>(MHS))
+ MHSTy = BitRecTy::get();
+
+ if (TypedInit *RHSt = dyn_cast<TypedInit>(RHS))
RHSTy = RHSt->getType();
- }
+ if (BitsInit *RHSbits = dyn_cast<BitsInit>(RHS))
+ RHSTy = BitsRecTy::get(RHSbits->getNumBits());
+ if (isa<BitInit>(RHS))
+ RHSTy = BitRecTy::get();
+
+ // For UnsetInit, it's typed from the other hand.
+ if (isa<UnsetInit>(MHS))
+ MHSTy = RHSTy;
+ if (isa<UnsetInit>(RHS))
+ RHSTy = MHSTy;
if (!MHSTy || !RHSTy) {
TokError("could not get type for !if");
- return 0;
+ return nullptr;
}
if (MHSTy->typeIsConvertibleTo(RHSTy)) {
Type = MHSTy;
} else {
TokError("inconsistent types for !if");
- return 0;
+ return nullptr;
}
break;
}
case tgtok::XForEach: {
- TypedInit *MHSt = dynamic_cast<TypedInit *>(MHS);
- if (MHSt == 0) {
+ TypedInit *MHSt = dyn_cast<TypedInit>(MHS);
+ if (!MHSt) {
TokError("could not get type for !foreach");
- return 0;
+ return nullptr;
}
Type = MHSt->getType();
break;
}
case tgtok::XSubst: {
- TypedInit *RHSt = dynamic_cast<TypedInit *>(RHS);
- if (RHSt == 0) {
+ TypedInit *RHSt = dyn_cast<TypedInit>(RHS);
+ if (!RHSt) {
TokError("could not get type for !subst");
- return 0;
+ return nullptr;
}
Type = RHSt->getType();
break;
/// OperatorType ::= '<' Type '>'
///
RecTy *TGParser::ParseOperatorType() {
- RecTy *Type = 0;
+ RecTy *Type = nullptr;
if (Lex.getCode() != tgtok::less) {
TokError("expected type name for operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the <
Type = ParseType();
- if (Type == 0) {
+ if (!Type) {
TokError("expected type name for operator");
- return 0;
+ return nullptr;
}
if (Lex.getCode() != tgtok::greater) {
TokError("expected type name for operator");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the >
/// SimpleValue ::= '[' ValueList ']'
/// SimpleValue ::= '(' IDValue DagArgList ')'
/// SimpleValue ::= CONCATTOK '(' Value ',' Value ')'
+/// SimpleValue ::= ADDTOK '(' Value ',' Value ')'
/// SimpleValue ::= SHLTOK '(' Value ',' Value ')'
/// SimpleValue ::= SRATOK '(' Value ',' Value ')'
/// SimpleValue ::= SRLTOK '(' Value ',' Value ')'
+/// SimpleValue ::= LISTCONCATTOK '(' Value ',' Value ')'
/// SimpleValue ::= STRCONCATTOK '(' Value ',' Value ')'
///
Init *TGParser::ParseSimpleValue(Record *CurRec, RecTy *ItemType,
IDParseMode Mode) {
- Init *R = 0;
+ Init *R = nullptr;
switch (Lex.getCode()) {
default: TokError("Unknown token when parsing a value"); break;
case tgtok::paste:
Lex.Lex(); // Skip '#'.
return ParseSimpleValue(CurRec, ItemType, Mode);
case tgtok::IntVal: R = IntInit::get(Lex.getCurIntVal()); Lex.Lex(); break;
+ case tgtok::BinaryIntVal: {
+ auto BinaryVal = Lex.getCurBinaryIntVal();
+ SmallVector<Init*, 16> Bits(BinaryVal.second);
+ for (unsigned i = 0, e = BinaryVal.second; i != e; ++i)
+ Bits[i] = BitInit::get(BinaryVal.first & (1LL << i));
+ R = BitsInit::get(Bits);
+ Lex.Lex();
+ break;
+ }
case tgtok::StrVal: {
std::string Val = Lex.getCurStrVal();
Lex.Lex();
// Value ::= ID '<' ValueListNE '>'
if (Lex.Lex() == tgtok::greater) {
TokError("expected non-empty value list");
- return 0;
+ return nullptr;
}
// This is a CLASS<initvalslist> expression. This is supposed to synthesize
Record *Class = Records.getClass(Name);
if (!Class) {
Error(NameLoc, "Expected a class name, got '" + Name + "'");
- return 0;
+ return nullptr;
}
std::vector<Init*> ValueList = ParseValueList(CurRec, Class);
- if (ValueList.empty()) return 0;
+ if (ValueList.empty()) return nullptr;
if (Lex.getCode() != tgtok::greater) {
TokError("expected '>' at end of value list");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '>'
+ SMLoc EndLoc = Lex.getLoc();
// Create the new record, set it as CurRec temporarily.
- static unsigned AnonCounter = 0;
- Record *NewRec = new Record("anonymous.val."+utostr(AnonCounter++),
- NameLoc,
- Records);
+ auto NewRecOwner = llvm::make_unique<Record>(GetNewAnonymousName(), NameLoc,
+ Records, /*IsAnonymous=*/true);
+ Record *NewRec = NewRecOwner.get(); // Keep a copy since we may release.
SubClassReference SCRef;
- SCRef.RefLoc = NameLoc;
+ SCRef.RefRange = SMRange(NameLoc, EndLoc);
SCRef.Rec = Class;
SCRef.TemplateArgs = ValueList;
// Add info about the subclass to NewRec.
if (AddSubClass(NewRec, SCRef))
- return 0;
- NewRec->resolveReferences();
- Records.addDef(NewRec);
+ return nullptr;
+
+ if (!CurMultiClass) {
+ NewRec->resolveReferences();
+ Records.addDef(std::move(NewRecOwner));
+ } else {
+ // This needs to get resolved once the multiclass template arguments are
+ // known before any use.
+ NewRec->setResolveFirst(true);
+ // Otherwise, we're inside a multiclass, add it to the multiclass.
+ CurMultiClass->DefPrototypes.push_back(std::move(NewRecOwner));
+
+ // Copy the template arguments for the multiclass into the def.
+ const std::vector<Init *> &TArgs =
+ CurMultiClass->Rec.getTemplateArgs();
+
+ for (unsigned i = 0, e = TArgs.size(); i != e; ++i) {
+ const RecordVal *RV = CurMultiClass->Rec.getValue(TArgs[i]);
+ assert(RV && "Template arg doesn't exist?");
+ NewRec->addValue(*RV);
+ }
+
+ // We can't return the prototype def here, instead return:
+ // !cast<ItemType>(!strconcat(NAME, AnonName)).
+ const RecordVal *MCNameRV = CurMultiClass->Rec.getValue("NAME");
+ assert(MCNameRV && "multiclass record must have a NAME");
+
+ return UnOpInit::get(UnOpInit::CAST,
+ BinOpInit::get(BinOpInit::STRCONCAT,
+ VarInit::get(MCNameRV->getName(),
+ MCNameRV->getType()),
+ NewRec->getNameInit(),
+ StringRecTy::get()),
+ Class->getDefInit()->getType());
+ }
// The result of the expression is a reference to the new record.
return DefInit::get(NewRec);
if (Lex.getCode() != tgtok::r_brace) {
Vals = ParseValueList(CurRec);
- if (Vals.empty()) return 0;
+ if (Vals.empty()) return nullptr;
}
if (Lex.getCode() != tgtok::r_brace) {
TokError("expected '}' at end of bit list value");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '}'
- SmallVector<Init *, 16> NewBits(Vals.size());
+ SmallVector<Init *, 16> NewBits;
+ // As we parse { a, b, ... }, 'a' is the highest bit, but we parse it
+ // first. We'll first read everything in to a vector, then we can reverse
+ // it to get the bits in the correct order for the BitsInit value.
for (unsigned i = 0, e = Vals.size(); i != e; ++i) {
+ // FIXME: The following two loops would not be duplicated
+ // if the API was a little more orthogonal.
+
+ // bits<n> values are allowed to initialize n bits.
+ if (BitsInit *BI = dyn_cast<BitsInit>(Vals[i])) {
+ for (unsigned i = 0, e = BI->getNumBits(); i != e; ++i)
+ NewBits.push_back(BI->getBit((e - i) - 1));
+ continue;
+ }
+ // bits<n> can also come from variable initializers.
+ if (VarInit *VI = dyn_cast<VarInit>(Vals[i])) {
+ if (BitsRecTy *BitsRec = dyn_cast<BitsRecTy>(VI->getType())) {
+ for (unsigned i = 0, e = BitsRec->getNumBits(); i != e; ++i)
+ NewBits.push_back(VI->getBit((e - i) - 1));
+ continue;
+ }
+ // Fallthrough to try convert this to a bit.
+ }
+ // All other values must be convertible to just a single bit.
Init *Bit = Vals[i]->convertInitializerTo(BitRecTy::get());
- if (Bit == 0) {
+ if (!Bit) {
Error(BraceLoc, "Element #" + utostr(i) + " (" + Vals[i]->getAsString()+
") is not convertable to a bit");
- return 0;
+ return nullptr;
}
- NewBits[Vals.size()-i-1] = Bit;
+ NewBits.push_back(Bit);
}
+ std::reverse(NewBits.begin(), NewBits.end());
return BitsInit::get(NewBits);
}
case tgtok::l_square: { // Value ::= '[' ValueList ']'
Lex.Lex(); // eat the '['
std::vector<Init*> Vals;
- RecTy *DeducedEltTy = 0;
- ListRecTy *GivenListTy = 0;
-
- if (ItemType != 0) {
- ListRecTy *ListType = dynamic_cast<ListRecTy*>(ItemType);
- if (ListType == 0) {
- std::stringstream s;
- s << "Type mismatch for list, expected list type, got "
- << ItemType->getAsString();
- TokError(s.str());
- return 0;
+ RecTy *DeducedEltTy = nullptr;
+ ListRecTy *GivenListTy = nullptr;
+
+ if (ItemType) {
+ ListRecTy *ListType = dyn_cast<ListRecTy>(ItemType);
+ if (!ListType) {
+ std::string s;
+ raw_string_ostream ss(s);
+ ss << "Type mismatch for list, expected list type, got "
+ << ItemType->getAsString();
+ TokError(ss.str());
+ return nullptr;
}
GivenListTy = ListType;
}
if (Lex.getCode() != tgtok::r_square) {
- Vals = ParseValueList(CurRec, 0,
- GivenListTy ? GivenListTy->getElementType() : 0);
- if (Vals.empty()) return 0;
+ Vals = ParseValueList(CurRec, nullptr,
+ GivenListTy ? GivenListTy->getElementType() : nullptr);
+ if (Vals.empty()) return nullptr;
}
if (Lex.getCode() != tgtok::r_square) {
TokError("expected ']' at end of list value");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ']'
- RecTy *GivenEltTy = 0;
+ RecTy *GivenEltTy = nullptr;
if (Lex.getCode() == tgtok::less) {
// Optional list element type
Lex.Lex(); // eat the '<'
GivenEltTy = ParseType();
- if (GivenEltTy == 0) {
+ if (!GivenEltTy) {
// Couldn't parse element type
- return 0;
+ return nullptr;
}
if (Lex.getCode() != tgtok::greater) {
TokError("expected '>' at end of list element type");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the '>'
}
// Check elements
- RecTy *EltTy = 0;
+ RecTy *EltTy = nullptr;
for (std::vector<Init *>::iterator i = Vals.begin(), ie = Vals.end();
i != ie;
++i) {
- TypedInit *TArg = dynamic_cast<TypedInit*>(*i);
- if (TArg == 0) {
+ TypedInit *TArg = dyn_cast<TypedInit>(*i);
+ if (!TArg) {
TokError("Untyped list element");
- return 0;
+ return nullptr;
}
- if (EltTy != 0) {
+ if (EltTy) {
EltTy = resolveTypes(EltTy, TArg->getType());
- if (EltTy == 0) {
+ if (!EltTy) {
TokError("Incompatible types in list elements");
- return 0;
+ return nullptr;
}
} else {
EltTy = TArg->getType();
}
}
- if (GivenEltTy != 0) {
- if (EltTy != 0) {
+ if (GivenEltTy) {
+ if (EltTy) {
// Verify consistency
if (!EltTy->typeIsConvertibleTo(GivenEltTy)) {
TokError("Incompatible types in list elements");
- return 0;
+ return nullptr;
}
}
EltTy = GivenEltTy;
}
- if (EltTy == 0) {
- if (ItemType == 0) {
+ if (!EltTy) {
+ if (!ItemType) {
TokError("No type for list");
- return 0;
+ return nullptr;
}
DeducedEltTy = GivenListTy->getElementType();
} else {
if (GivenListTy) {
if (!EltTy->typeIsConvertibleTo(GivenListTy->getElementType())) {
TokError("Element type mismatch for list");
- return 0;
+ return nullptr;
}
}
DeducedEltTy = EltTy;
Lex.Lex(); // eat the '('
if (Lex.getCode() != tgtok::Id && Lex.getCode() != tgtok::XCast) {
TokError("expected identifier in dag init");
- return 0;
+ return nullptr;
}
Init *Operator = ParseValue(CurRec);
- if (Operator == 0) return 0;
+ if (!Operator) return nullptr;
// If the operator name is present, parse it.
std::string OperatorName;
if (Lex.getCode() == tgtok::colon) {
if (Lex.Lex() != tgtok::VarName) { // eat the ':'
TokError("expected variable name in dag operator");
- return 0;
+ return nullptr;
}
OperatorName = Lex.getCurStrVal();
Lex.Lex(); // eat the VarName.
std::vector<std::pair<llvm::Init*, std::string> > DagArgs;
if (Lex.getCode() != tgtok::r_paren) {
DagArgs = ParseDagArgList(CurRec);
- if (DagArgs.empty()) return 0;
+ if (DagArgs.empty()) return nullptr;
}
if (Lex.getCode() != tgtok::r_paren) {
TokError("expected ')' in dag init");
- return 0;
+ return nullptr;
}
Lex.Lex(); // eat the ')'
case tgtok::XEmpty:
case tgtok::XCast: // Value ::= !unop '(' Value ')'
case tgtok::XConcat:
+ case tgtok::XADD:
+ case tgtok::XAND:
case tgtok::XSRA:
case tgtok::XSRL:
case tgtok::XSHL:
case tgtok::XEq:
+ case tgtok::XListConcat:
case tgtok::XStrConcat: // Value ::= !binop '(' Value ',' Value ')'
case tgtok::XIf:
case tgtok::XForEach:
case tgtok::XSubst: { // Value ::= !ternop '(' Value ',' Value ',' Value ')'
- return ParseOperation(CurRec);
+ return ParseOperation(CurRec, ItemType);
}
}
///
Init *TGParser::ParseValue(Record *CurRec, RecTy *ItemType, IDParseMode Mode) {
Init *Result = ParseSimpleValue(CurRec, ItemType, Mode);
- if (Result == 0) return 0;
+ if (!Result) return nullptr;
// Parse the suffixes now if present.
while (1) {
SMLoc CurlyLoc = Lex.getLoc();
Lex.Lex(); // eat the '{'
std::vector<unsigned> Ranges = ParseRangeList();
- if (Ranges.empty()) return 0;
+ if (Ranges.empty()) return nullptr;
// Reverse the bitlist.
std::reverse(Ranges.begin(), Ranges.end());
Result = Result->convertInitializerBitRange(Ranges);
- if (Result == 0) {
+ if (!Result) {
Error(CurlyLoc, "Invalid bit range for value");
- return 0;
+ return nullptr;
}
// Eat the '}'.
if (Lex.getCode() != tgtok::r_brace) {
TokError("expected '}' at end of bit range list");
- return 0;
+ return nullptr;
}
Lex.Lex();
break;
SMLoc SquareLoc = Lex.getLoc();
Lex.Lex(); // eat the '['
std::vector<unsigned> Ranges = ParseRangeList();
- if (Ranges.empty()) return 0;
+ if (Ranges.empty()) return nullptr;
Result = Result->convertInitListSlice(Ranges);
- if (Result == 0) {
+ if (!Result) {
Error(SquareLoc, "Invalid range for list slice");
- return 0;
+ return nullptr;
}
// Eat the ']'.
if (Lex.getCode() != tgtok::r_square) {
TokError("expected ']' at end of list slice");
- return 0;
+ return nullptr;
}
Lex.Lex();
break;
case tgtok::period:
if (Lex.Lex() != tgtok::Id) { // eat the .
TokError("expected field identifier after '.'");
- return 0;
+ return nullptr;
}
if (!Result->getFieldType(Lex.getCurStrVal())) {
TokError("Cannot access field '" + Lex.getCurStrVal() + "' of value '" +
Result->getAsString() + "'");
- return 0;
+ return nullptr;
}
Result = FieldInit::get(Result, Lex.getCurStrVal());
Lex.Lex(); // eat field name
// Create a !strconcat() operation, first casting each operand to
// a string if necessary.
- TypedInit *LHS = dynamic_cast<TypedInit *>(Result);
+ TypedInit *LHS = dyn_cast<TypedInit>(Result);
if (!LHS) {
Error(PasteLoc, "LHS of paste is not typed!");
- return 0;
+ return nullptr;
}
if (LHS->getType() != StringRecTy::get()) {
LHS = UnOpInit::get(UnOpInit::CAST, LHS, StringRecTy::get());
}
- TypedInit *RHS = 0;
+ TypedInit *RHS = nullptr;
Lex.Lex(); // Eat the '#'.
switch (Lex.getCode()) {
default:
Init *RHSResult = ParseValue(CurRec, ItemType, ParseNameMode);
- RHS = dynamic_cast<TypedInit *>(RHSResult);
+ RHS = dyn_cast<TypedInit>(RHSResult);
if (!RHS) {
Error(PasteLoc, "RHS of paste is not typed!");
- return 0;
+ return nullptr;
}
if (RHS->getType() != StringRecTy::get()) {
/// ParseDagArgList - Parse the argument list for a dag literal expression.
///
-/// ParseDagArgList ::= Value (':' VARNAME)?
-/// ParseDagArgList ::= ParseDagArgList ',' Value (':' VARNAME)?
+/// DagArg ::= Value (':' VARNAME)?
+/// DagArg ::= VARNAME
+/// DagArgList ::= DagArg
+/// DagArgList ::= DagArgList ',' DagArg
std::vector<std::pair<llvm::Init*, std::string> >
TGParser::ParseDagArgList(Record *CurRec) {
std::vector<std::pair<llvm::Init*, std::string> > Result;
while (1) {
- Init *Val = ParseValue(CurRec);
- if (Val == 0) return std::vector<std::pair<llvm::Init*, std::string> >();
-
- // If the variable name is present, add it.
- std::string VarName;
- if (Lex.getCode() == tgtok::colon) {
- if (Lex.Lex() != tgtok::VarName) { // eat the ':'
- TokError("expected variable name in dag literal");
+ // DagArg ::= VARNAME
+ if (Lex.getCode() == tgtok::VarName) {
+ // A missing value is treated like '?'.
+ Result.push_back(std::make_pair(UnsetInit::get(), Lex.getCurStrVal()));
+ Lex.Lex();
+ } else {
+ // DagArg ::= Value (':' VARNAME)?
+ Init *Val = ParseValue(CurRec);
+ if (!Val)
return std::vector<std::pair<llvm::Init*, std::string> >();
- }
- VarName = Lex.getCurStrVal();
- Lex.Lex(); // eat the VarName.
- }
- Result.push_back(std::make_pair(Val, VarName));
+ // If the variable name is present, add it.
+ std::string VarName;
+ if (Lex.getCode() == tgtok::colon) {
+ if (Lex.Lex() != tgtok::VarName) { // eat the ':'
+ TokError("expected variable name in dag literal");
+ return std::vector<std::pair<llvm::Init*, std::string> >();
+ }
+ VarName = Lex.getCurStrVal();
+ Lex.Lex(); // eat the VarName.
+ }
+ Result.push_back(std::make_pair(Val, VarName));
+ }
if (Lex.getCode() != tgtok::comma) break;
Lex.Lex(); // eat the ','
}
std::vector<Init*> Result;
RecTy *ItemType = EltTy;
unsigned int ArgN = 0;
- if (ArgsRec != 0 && EltTy == 0) {
+ if (ArgsRec && !EltTy) {
const std::vector<Init *> &TArgs = ArgsRec->getTemplateArgs();
- if (!TArgs.size()) {
+ if (TArgs.empty()) {
TokError("template argument provided to non-template class");
return std::vector<Init*>();
}
++ArgN;
}
Result.push_back(ParseValue(CurRec, ItemType));
- if (Result.back() == 0) return std::vector<Init*>();
+ if (!Result.back()) return std::vector<Init*>();
while (Lex.getCode() == tgtok::comma) {
Lex.Lex(); // Eat the comma
- if (ArgsRec != 0 && EltTy == 0) {
+ if (ArgsRec && !EltTy) {
const std::vector<Init *> &TArgs = ArgsRec->getTemplateArgs();
if (ArgN >= TArgs.size()) {
TokError("too many template arguments");
++ArgN;
}
Result.push_back(ParseValue(CurRec, ItemType));
- if (Result.back() == 0) return std::vector<Init*>();
+ if (!Result.back()) return std::vector<Init*>();
}
return Result;
if (HasField) Lex.Lex();
RecTy *Type = ParseType();
- if (Type == 0) return 0;
+ if (!Type) return nullptr;
if (Lex.getCode() != tgtok::Id) {
TokError("Expected identifier in declaration");
- return 0;
+ return nullptr;
}
SMLoc IdLoc = Lex.getLoc();
// Add the value.
if (AddValue(CurRec, IdLoc, RecordVal(DeclName, Type, HasField)))
- return 0;
+ return nullptr;
// If a value is present, parse it.
if (Lex.getCode() == tgtok::equal) {
Lex.Lex();
SMLoc ValLoc = Lex.getLoc();
Init *Val = ParseValue(CurRec, Type);
- if (Val == 0 ||
+ if (!Val ||
SetValue(CurRec, ValLoc, DeclName, std::vector<unsigned>(), Val))
- return 0;
+ // Return the name, even if an error is thrown. This is so that we can
+ // continue to make some progress, even without the value having been
+ // initialized.
+ return DeclName;
}
return DeclName;
/// the name of the declared object or a NULL Init on error. Return
/// the name of the parsed initializer list through ForeachListName.
///
-/// ForeachDeclaration ::= ID '=' Value
+/// ForeachDeclaration ::= ID '=' '[' ValueList ']'
+/// ForeachDeclaration ::= ID '=' '{' RangeList '}'
+/// ForeachDeclaration ::= ID '=' RangePiece
///
VarInit *TGParser::ParseForeachDeclaration(ListInit *&ForeachListValue) {
if (Lex.getCode() != tgtok::Id) {
TokError("Expected identifier in foreach declaration");
- return 0;
+ return nullptr;
}
Init *DeclName = StringInit::get(Lex.getCurStrVal());
// If a value is present, parse it.
if (Lex.getCode() != tgtok::equal) {
TokError("Expected '=' in foreach declaration");
- return 0;
+ return nullptr;
}
Lex.Lex(); // Eat the '='
- // Expect a list initializer.
- Init *List = ParseSimpleValue(0, 0, ParseForeachMode);
+ RecTy *IterType = nullptr;
+ std::vector<unsigned> Ranges;
- ForeachListValue = dynamic_cast<ListInit*>(List);
- if (ForeachListValue == 0) {
- TokError("Expected a Value list");
- return 0;
+ switch (Lex.getCode()) {
+ default: TokError("Unknown token when expecting a range list"); return nullptr;
+ case tgtok::l_square: { // '[' ValueList ']'
+ Init *List = ParseSimpleValue(nullptr, nullptr, ParseForeachMode);
+ ForeachListValue = dyn_cast<ListInit>(List);
+ if (!ForeachListValue) {
+ TokError("Expected a Value list");
+ return nullptr;
+ }
+ RecTy *ValueType = ForeachListValue->getType();
+ ListRecTy *ListType = dyn_cast<ListRecTy>(ValueType);
+ if (!ListType) {
+ TokError("Value list is not of list type");
+ return nullptr;
+ }
+ IterType = ListType->getElementType();
+ break;
}
- RecTy *ValueType = ForeachListValue->getType();
- ListRecTy *ListType = dynamic_cast<ListRecTy *>(ValueType);
- if (ListType == 0) {
- TokError("Value list is not of list type");
- return 0;
+ case tgtok::IntVal: { // RangePiece.
+ if (ParseRangePiece(Ranges))
+ return nullptr;
+ break;
}
- RecTy *IterType = ListType->getElementType();
- VarInit *IterVar = VarInit::get(DeclName, IterType);
+ case tgtok::l_brace: { // '{' RangeList '}'
+ Lex.Lex(); // eat the '{'
+ Ranges = ParseRangeList();
+ if (Lex.getCode() != tgtok::r_brace) {
+ TokError("expected '}' at end of bit range list");
+ return nullptr;
+ }
+ Lex.Lex();
+ break;
+ }
+ }
+
+ if (!Ranges.empty()) {
+ assert(!IterType && "Type already initialized?");
+ IterType = IntRecTy::get();
+ std::vector<Init*> Values;
+ for (unsigned i = 0, e = Ranges.size(); i != e; ++i)
+ Values.push_back(IntInit::get(Ranges[i]));
+ ForeachListValue = ListInit::get(Values, IterType);
+ }
- return IterVar;
+ if (!IterType)
+ return nullptr;
+
+ return VarInit::get(DeclName, IterType);
}
/// ParseTemplateArgList - Read a template argument list, which is a non-empty
// Read the first declaration.
Init *TemplArg = ParseDeclaration(CurRec, true/*templateargs*/);
- if (TemplArg == 0)
+ if (!TemplArg)
return true;
TheRecToAddTo->addTemplateArg(TemplArg);
// Read the following declarations.
TemplArg = ParseDeclaration(CurRec, true/*templateargs*/);
- if (TemplArg == 0)
+ if (!TemplArg)
return true;
TheRecToAddTo->addTemplateArg(TemplArg);
}
/// BodyItem ::= LET ID OptionalBitList '=' Value ';'
bool TGParser::ParseBodyItem(Record *CurRec) {
if (Lex.getCode() != tgtok::Let) {
- if (ParseDeclaration(CurRec, false) == 0)
+ if (!ParseDeclaration(CurRec, false))
return true;
if (Lex.getCode() != tgtok::semi)
Lex.Lex(); // eat the '='.
RecordVal *Field = CurRec->getValue(FieldName);
- if (Field == 0)
+ if (!Field)
return TokError("Value '" + FieldName + "' unknown!");
RecTy *Type = Field->getType();
Init *Val = ParseValue(CurRec, Type);
- if (Val == 0) return true;
+ if (!Val) return true;
if (Lex.getCode() != tgtok::semi)
return TokError("expected ';' after let expression");
return false;
}
+/// \brief Apply the current let bindings to \a CurRec.
+/// \returns true on error, false otherwise.
+bool TGParser::ApplyLetStack(Record *CurRec) {
+ for (unsigned i = 0, e = LetStack.size(); i != e; ++i)
+ for (unsigned j = 0, e = LetStack[i].size(); j != e; ++j)
+ if (SetValue(CurRec, LetStack[i][j].Loc, LetStack[i][j].Name,
+ LetStack[i][j].Bits, LetStack[i][j].Value))
+ return true;
+ return false;
+}
+
/// ParseObjectBody - Parse the body of a def or class. This consists of an
/// optional ClassList followed by a Body. CurRec is the current def or class
/// that is being parsed.
SubClassReference SubClass = ParseSubClassReference(CurRec, false);
while (1) {
// Check for error.
- if (SubClass.Rec == 0) return true;
+ if (!SubClass.Rec) return true;
// Add it.
if (AddSubClass(CurRec, SubClass))
}
}
- // Process any variables on the let stack.
- for (unsigned i = 0, e = LetStack.size(); i != e; ++i)
- for (unsigned j = 0, e = LetStack[i].size(); j != e; ++j)
- if (SetValue(CurRec, LetStack[i][j].Loc, LetStack[i][j].Name,
- LetStack[i][j].Bits, LetStack[i][j].Value))
- return true;
+ if (ApplyLetStack(CurRec))
+ return true;
return ParseBody(CurRec);
}
Lex.Lex(); // Eat the 'def' token.
// Parse ObjectName and make a record for it.
- Record *CurRec = new Record(ParseObjectName(CurMultiClass), DefLoc, Records);
+ std::unique_ptr<Record> CurRecOwner;
+ Init *Name = ParseObjectName(CurMultiClass);
+ if (Name)
+ CurRecOwner = make_unique<Record>(Name, DefLoc, Records);
+ else
+ CurRecOwner = llvm::make_unique<Record>(GetNewAnonymousName(), DefLoc,
+ Records, /*IsAnonymous=*/true);
+ Record *CurRec = CurRecOwner.get(); // Keep a copy since we may release.
if (!CurMultiClass && Loops.empty()) {
// Top-level def definition.
// Ensure redefinition doesn't happen.
- if (Records.getDef(CurRec->getNameInitAsString())) {
- Error(DefLoc, "def '" + CurRec->getNameInitAsString()
- + "' already defined");
+ if (Records.getDef(CurRec->getNameInitAsString()))
+ return Error(DefLoc, "def '" + CurRec->getNameInitAsString()+
+ "' already defined");
+ Records.addDef(std::move(CurRecOwner));
+
+ if (ParseObjectBody(CurRec))
return true;
- }
- Records.addDef(CurRec);
} else if (CurMultiClass) {
+ // Parse the body before adding this prototype to the DefPrototypes vector.
+ // That way implicit definitions will be added to the DefPrototypes vector
+ // before this object, instantiated prior to defs derived from this object,
+ // and this available for indirect name resolution when defs derived from
+ // this object are instantiated.
+ if (ParseObjectBody(CurRec))
+ return true;
+
// Otherwise, a def inside a multiclass, add it to the multiclass.
for (unsigned i = 0, e = CurMultiClass->DefPrototypes.size(); i != e; ++i)
if (CurMultiClass->DefPrototypes[i]->getNameInit()
- == CurRec->getNameInit()) {
- Error(DefLoc, "def '" + CurRec->getNameInitAsString() +
- "' already defined in this multiclass!");
- return true;
- }
- CurMultiClass->DefPrototypes.push_back(CurRec);
- }
-
- if (ParseObjectBody(CurRec))
+ == CurRec->getNameInit())
+ return Error(DefLoc, "def '" + CurRec->getNameInitAsString() +
+ "' already defined in this multiclass!");
+ CurMultiClass->DefPrototypes.push_back(std::move(CurRecOwner));
+ } else if (ParseObjectBody(CurRec)) {
return true;
+ }
- if (CurMultiClass == 0) // Def's in multiclasses aren't really defs.
+ if (!CurMultiClass) // Def's in multiclasses aren't really defs.
// See Record::setName(). This resolve step will see any new name
// for the def that might have been created when resolving
// inheritance, values and arguments above.
}
if (ProcessForeachDefs(CurRec, DefLoc)) {
- Error(DefLoc,
- "Could not process loops for def" + CurRec->getNameInitAsString());
- return true;
+ return Error(DefLoc, "Could not process loops for def" +
+ CurRec->getNameInitAsString());
}
return false;
// Make a temporary object to record items associated with the for
// loop.
- ListInit *ListValue = 0;
+ ListInit *ListValue = nullptr;
VarInit *IterName = ParseForeachDeclaration(ListValue);
- if (IterName == 0)
+ if (!IterName)
return TokError("expected declaration in for");
if (Lex.getCode() != tgtok::In)
+ "' already defined");
} else {
// If this is the first reference to this class, create and add it.
- CurRec = new Record(Lex.getCurStrVal(), Lex.getLoc(), Records);
- Records.addClass(CurRec);
+ auto NewRec =
+ llvm::make_unique<Record>(Lex.getCurStrVal(), Lex.getLoc(), Records);
+ CurRec = NewRec.get();
+ Records.addClass(std::move(NewRec));
}
Lex.Lex(); // eat the name.
}
Lex.Lex(); // eat the '='.
- Init *Val = ParseValue(0);
- if (Val == 0) return std::vector<LetRecord>();
+ Init *Val = ParseValue(nullptr);
+ if (!Val) return std::vector<LetRecord>();
// Now that we have everything, add the record.
Result.push_back(LetRecord(Name, Bits, Val, NameLoc));
// Add this entry to the let stack.
std::vector<LetRecord> LetInfo = ParseLetList();
if (LetInfo.empty()) return true;
- LetStack.push_back(LetInfo);
+ LetStack.push_back(std::move(LetInfo));
if (Lex.getCode() != tgtok::In)
return TokError("expected 'in' at end of top-level 'let'");
/// ParseMultiClass - Parse a multiclass definition.
///
/// MultiClassInst ::= MULTICLASS ID TemplateArgList?
-/// ':' BaseMultiClassList '{' MultiClassDef+ '}'
+/// ':' BaseMultiClassList '{' MultiClassObject+ '}'
+/// MultiClassObject ::= DefInst
+/// MultiClassObject ::= MultiClassInst
+/// MultiClassObject ::= DefMInst
+/// MultiClassObject ::= LETCommand '{' ObjectList '}'
+/// MultiClassObject ::= LETCommand Object
///
bool TGParser::ParseMultiClass() {
assert(Lex.getCode() == tgtok::MultiClass && "Unexpected token");
return TokError("expected identifier after multiclass for name");
std::string Name = Lex.getCurStrVal();
- if (MultiClasses.count(Name))
+ auto Result =
+ MultiClasses.insert(std::make_pair(Name,
+ llvm::make_unique<MultiClass>(Name, Lex.getLoc(),Records)));
+
+ if (!Result.second)
return TokError("multiclass '" + Name + "' already defined");
- CurMultiClass = MultiClasses[Name] = new MultiClass(Name,
- Lex.getLoc(), Records);
+ CurMultiClass = Result.first->second.get();
Lex.Lex(); // Eat the identifier.
// If there are template args, parse them.
if (Lex.getCode() == tgtok::less)
- if (ParseTemplateArgList(0))
+ if (ParseTemplateArgList(nullptr))
return true;
bool inherits = false;
ParseSubMultiClassReference(CurMultiClass);
while (1) {
// Check for error.
- if (SubMultiClass.MC == 0) return true;
+ if (!SubMultiClass.MC) return true;
// Add it.
if (AddSubMultiClass(CurMultiClass, SubMultiClass))
if (Lex.getCode() != tgtok::l_brace) {
if (!inherits)
return TokError("expected '{' in multiclass definition");
- else if (Lex.getCode() != tgtok::semi)
+ if (Lex.getCode() != tgtok::semi)
return TokError("expected ';' in multiclass definition");
- else
- Lex.Lex(); // eat the ';'.
+ Lex.Lex(); // eat the ';'.
} else {
if (Lex.Lex() == tgtok::r_brace) // eat the '{'.
return TokError("multiclass must contain at least one def");
while (Lex.getCode() != tgtok::r_brace) {
switch (Lex.getCode()) {
- default:
- return TokError("expected 'let', 'def' or 'defm' in multiclass body");
- case tgtok::Let:
- case tgtok::Def:
- case tgtok::Defm:
- case tgtok::Foreach:
- if (ParseObject(CurMultiClass))
- return true;
- break;
+ default:
+ return TokError("expected 'let', 'def' or 'defm' in multiclass body");
+ case tgtok::Let:
+ case tgtok::Def:
+ case tgtok::Defm:
+ case tgtok::Foreach:
+ if (ParseObject(CurMultiClass))
+ return true;
+ break;
}
}
Lex.Lex(); // eat the '}'.
}
- CurMultiClass = 0;
+ CurMultiClass = nullptr;
return false;
}
Record *TGParser::
InstantiateMulticlassDef(MultiClass &MC,
Record *DefProto,
- Init *DefmPrefix,
- SMLoc DefmPrefixLoc) {
+ Init *&DefmPrefix,
+ SMRange DefmPrefixRange) {
// We need to preserve DefProto so it can be reused for later
// instantiations, so create a new Record to inherit from it.
// name, substitute the prefix for #NAME#. Otherwise, use the defm name
// as a prefix.
- if (DefmPrefix == 0)
+ bool IsAnonymous = false;
+ if (!DefmPrefix) {
DefmPrefix = StringInit::get(GetNewAnonymousName());
+ IsAnonymous = true;
+ }
Init *DefName = DefProto->getNameInit();
- StringInit *DefNameString = dynamic_cast<StringInit *>(DefName);
+ StringInit *DefNameString = dyn_cast<StringInit>(DefName);
- if (DefNameString != 0) {
+ if (DefNameString) {
// We have a fully expanded string so there are no operators to
// resolve. We should concatenate the given prefix and name.
DefName =
DefName, StringRecTy::get())->Fold(DefProto, &MC);
}
- Record *CurRec = new Record(DefName, DefmPrefixLoc, Records);
+ // Make a trail of SMLocs from the multiclass instantiations.
+ SmallVector<SMLoc, 4> Locs(1, DefmPrefixRange.Start);
+ Locs.append(DefProto->getLoc().begin(), DefProto->getLoc().end());
+ auto CurRec = make_unique<Record>(DefName, Locs, Records, IsAnonymous);
SubClassReference Ref;
- Ref.RefLoc = DefmPrefixLoc;
+ Ref.RefRange = DefmPrefixRange;
Ref.Rec = DefProto;
- AddSubClass(CurRec, Ref);
-
- if (DefNameString == 0) {
- // We must resolve references to NAME.
- if (SetValue(CurRec, Ref.RefLoc, "NAME", std::vector<unsigned>(),
- DefmPrefix)) {
- Error(DefmPrefixLoc, "Could not resolve "
- + CurRec->getNameInitAsString() + ":NAME to '"
- + DefmPrefix->getAsUnquotedString() + "'");
- return 0;
- }
-
+ AddSubClass(CurRec.get(), Ref);
+
+ // Set the value for NAME. We don't resolve references to it 'til later,
+ // though, so that uses in nested multiclass names don't get
+ // confused.
+ if (SetValue(CurRec.get(), Ref.RefRange.Start, "NAME",
+ std::vector<unsigned>(), DefmPrefix)) {
+ Error(DefmPrefixRange.Start, "Could not resolve "
+ + CurRec->getNameInitAsString() + ":NAME to '"
+ + DefmPrefix->getAsUnquotedString() + "'");
+ return nullptr;
+ }
+
+ // If the DefNameString didn't resolve, we probably have a reference to
+ // NAME and need to replace it. We need to do at least this much greedily,
+ // otherwise nested multiclasses will end up with incorrect NAME expansions.
+ if (!DefNameString) {
RecordVal *DefNameRV = CurRec->getValue("NAME");
CurRec->resolveReferencesTo(DefNameRV);
}
if (!CurMultiClass) {
- // We do this after resolving NAME because before resolution, many
- // multiclass defs will have the same name expression. If we are
+ // Now that we're at the top level, resolve all NAME references
+ // in the resultant defs that weren't in the def names themselves.
+ RecordVal *DefNameRV = CurRec->getValue("NAME");
+ CurRec->resolveReferencesTo(DefNameRV);
+
+ // Now that NAME references are resolved and we're at the top level of
+ // any multiclass expansions, add the record to the RecordKeeper. If we are
// currently in a multiclass, it means this defm appears inside a
// multiclass and its name won't be fully resolvable until we see
// the top-level defm. Therefore, we don't add this to the
// Ensure redefinition doesn't happen.
if (Records.getDef(CurRec->getNameInitAsString())) {
- Error(DefmPrefixLoc, "def '" + CurRec->getNameInitAsString() +
+ Error(DefmPrefixRange.Start, "def '" + CurRec->getNameInitAsString() +
"' already defined, instantiating defm with subdef '" +
DefProto->getNameInitAsString() + "'");
- return 0;
+ return nullptr;
}
- Records.addDef(CurRec);
+ Record *CurRecSave = CurRec.get(); // Keep a copy before we release.
+ Records.addDef(std::move(CurRec));
+ return CurRecSave;
}
- return CurRec;
+ // FIXME This is bad but the ownership transfer to caller is pretty messy.
+ // The unique_ptr in this function at least protects the exits above.
+ return CurRec.release();
}
bool TGParser::ResolveMulticlassDefArgs(MultiClass &MC,
Record *DefProto,
SMLoc DefmPrefixLoc) {
// If the mdef is inside a 'let' expression, add to each def.
- for (unsigned i = 0, e = LetStack.size(); i != e; ++i)
- for (unsigned j = 0, e = LetStack[i].size(); j != e; ++j)
- if (SetValue(CurRec, LetStack[i][j].Loc, LetStack[i][j].Name,
- LetStack[i][j].Bits, LetStack[i][j].Value))
- return Error(DefmPrefixLoc, "when instantiating this defm");
+ if (ApplyLetStack(CurRec))
+ return Error(DefmPrefixLoc, "when instantiating this defm");
// Don't create a top level definition for defm inside multiclasses,
// instead, only update the prototypes and bind the template args
// with the new created definition.
- if (CurMultiClass) {
- for (unsigned i = 0, e = CurMultiClass->DefPrototypes.size();
- i != e; ++i)
- if (CurMultiClass->DefPrototypes[i]->getNameInit()
- == CurRec->getNameInit())
- return Error(DefmPrefixLoc, "defm '" + CurRec->getNameInitAsString() +
- "' already defined in this multiclass!");
- CurMultiClass->DefPrototypes.push_back(CurRec);
+ if (!CurMultiClass)
+ return false;
+ for (unsigned i = 0, e = CurMultiClass->DefPrototypes.size();
+ i != e; ++i)
+ if (CurMultiClass->DefPrototypes[i]->getNameInit()
+ == CurRec->getNameInit())
+ return Error(DefmPrefixLoc, "defm '" + CurRec->getNameInitAsString() +
+ "' already defined in this multiclass!");
+ CurMultiClass->DefPrototypes.push_back(std::unique_ptr<Record>(CurRec));
- // Copy the template arguments for the multiclass into the new def.
- const std::vector<Init *> &TA =
- CurMultiClass->Rec.getTemplateArgs();
+ // Copy the template arguments for the multiclass into the new def.
+ const std::vector<Init *> &TA =
+ CurMultiClass->Rec.getTemplateArgs();
- for (unsigned i = 0, e = TA.size(); i != e; ++i) {
- const RecordVal *RV = CurMultiClass->Rec.getValue(TA[i]);
- assert(RV && "Template arg doesn't exist?");
- CurRec->addValue(*RV);
- }
+ for (unsigned i = 0, e = TA.size(); i != e; ++i) {
+ const RecordVal *RV = CurMultiClass->Rec.getValue(TA[i]);
+ assert(RV && "Template arg doesn't exist?");
+ CurRec->addValue(*RV);
}
return false;
///
bool TGParser::ParseDefm(MultiClass *CurMultiClass) {
assert(Lex.getCode() == tgtok::Defm && "Unexpected token!");
-
- Init *DefmPrefix = 0;
+ SMLoc DefmLoc = Lex.getLoc();
+ Init *DefmPrefix = nullptr;
if (Lex.Lex() == tgtok::Id) { // eat the defm.
DefmPrefix = ParseObjectName(CurMultiClass);
}
- SMLoc DefmPrefixLoc = Lex.getLoc();
+ SMLoc DefmPrefixEndLoc = Lex.getLoc();
if (Lex.getCode() != tgtok::colon)
return TokError("expected ':' after defm identifier");
Lex.Lex();
SMLoc SubClassLoc = Lex.getLoc();
- SubClassReference Ref = ParseSubClassReference(0, true);
+ SubClassReference Ref = ParseSubClassReference(nullptr, true);
while (1) {
- if (Ref.Rec == 0) return true;
+ if (!Ref.Rec) return true;
// To instantiate a multiclass, we need to first get the multiclass, then
// instantiate each def contained in the multiclass with the SubClassRef
// template parameters.
- MultiClass *MC = MultiClasses[Ref.Rec->getName()];
+ MultiClass *MC = MultiClasses[Ref.Rec->getName()].get();
assert(MC && "Didn't lookup multiclass correctly?");
std::vector<Init*> &TemplateVals = Ref.TemplateArgs;
// Loop over all the def's in the multiclass, instantiating each one.
for (unsigned i = 0, e = MC->DefPrototypes.size(); i != e; ++i) {
- Record *DefProto = MC->DefPrototypes[i];
+ Record *DefProto = MC->DefPrototypes[i].get();
- Record *CurRec = InstantiateMulticlassDef(*MC, DefProto, DefmPrefix, DefmPrefixLoc);
+ Record *CurRec = InstantiateMulticlassDef(*MC, DefProto, DefmPrefix,
+ SMRange(DefmLoc,
+ DefmPrefixEndLoc));
if (!CurRec)
return true;
- if (ResolveMulticlassDefArgs(*MC, CurRec, DefmPrefixLoc, SubClassLoc,
+ if (ResolveMulticlassDefArgs(*MC, CurRec, DefmLoc, SubClassLoc,
TArgs, TemplateVals, true/*Delete args*/))
return Error(SubClassLoc, "could not instantiate def");
- if (ResolveMulticlassDef(*MC, CurRec, DefProto, DefmPrefixLoc))
+ if (ResolveMulticlassDef(*MC, CurRec, DefProto, DefmLoc))
return Error(SubClassLoc, "could not instantiate def");
+ // Defs that can be used by other definitions should be fully resolved
+ // before any use.
+ if (DefProto->isResolveFirst() && !CurMultiClass) {
+ CurRec->resolveReferences();
+ CurRec->setResolveFirst(false);
+ }
NewRecDefs.push_back(CurRec);
}
if (Lex.getCode() != tgtok::comma) break;
Lex.Lex(); // eat ','.
+ if (Lex.getCode() != tgtok::Id)
+ return TokError("expected identifier");
+
SubClassLoc = Lex.getLoc();
// A defm can inherit from regular classes (non-multiclass) as
// long as they come in the end of the inheritance list.
- InheritFromClass = (Records.getClass(Lex.getCurStrVal()) != 0);
+ InheritFromClass = (Records.getClass(Lex.getCurStrVal()) != nullptr);
if (InheritFromClass)
break;
- Ref = ParseSubClassReference(0, true);
+ Ref = ParseSubClassReference(nullptr, true);
}
if (InheritFromClass) {
// Process all the classes to inherit as if they were part of a
// regular 'def' and inherit all record values.
- SubClassReference SubClass = ParseSubClassReference(0, false);
+ SubClassReference SubClass = ParseSubClassReference(nullptr, false);
while (1) {
// Check for error.
- if (SubClass.Rec == 0) return true;
+ if (!SubClass.Rec) return true;
// Get the expanded definition prototypes and teach them about
// the record values the current class to inherit has
if (AddSubClass(CurRec, SubClass))
return true;
- // Process any variables on the let stack.
- for (unsigned i = 0, e = LetStack.size(); i != e; ++i)
- for (unsigned j = 0, e = LetStack[i].size(); j != e; ++j)
- if (SetValue(CurRec, LetStack[i][j].Loc, LetStack[i][j].Name,
- LetStack[i][j].Bits, LetStack[i][j].Value))
- return true;
+ if (ApplyLetStack(CurRec))
+ return true;
}
if (Lex.getCode() != tgtok::comma) break;
Lex.Lex(); // eat ','.
- SubClass = ParseSubClassReference(0, false);
+ SubClass = ParseSubClassReference(nullptr, false);
}
}