//===----------------------------------------------------------------------===//
#include "TGParser.h"
-#include "llvm/TableGen/Record.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;
//===----------------------------------------------------------------------===//
if (CurRec == 0)
CurRec = &CurMultiClass->Rec;
- if (RecordVal *ERV = CurRec->getValue(RV.getName())) {
+ if (RecordVal *ERV = CurRec->getValue(RV.getNameInit())) {
// The value already exists in the class, treat this as a set.
if (ERV->setValue(RV.getValue()))
return Error(Loc, "New definition of '" + RV.getName() + "' of type '" +
// 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());
+ BitsInit *CurVal = dyn_cast<BitsInit>(RV->getValue());
if (CurVal == 0)
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()));
return Error(Loc, "Initializer is not compatible with bit range");
}
// We should have a BitsInit type now.
- BitsInit *BInit = dynamic_cast<BitsInit*>(BI);
+ BitsInit *BInit = dyn_cast<BitsInit>(BI);
assert(BInit != 0);
SmallVector<Init *, 16> NewBits(CurVal->getNumBits());
return false;
}
+/// ProcessForeachDefs - Given a record, apply all of the variable
+/// values in all surrounding foreach loops, creating new records for
+/// each combination of values.
+bool TGParser::ProcessForeachDefs(Record *CurRec, SMLoc Loc) {
+ if (Loops.empty())
+ return false;
+
+ // We want to instantiate a new copy of CurRec for each combination
+ // of nested loop iterator values. We don't want top instantiate
+ // any copies until we have values for each loop iterator.
+ IterSet IterVals;
+ return ProcessForeachDefs(CurRec, Loc, IterVals);
+}
+
+/// ProcessForeachDefs - Given a record, a loop and a loop iterator,
+/// apply each of the variable values in this loop and then process
+/// subloops.
+bool TGParser::ProcessForeachDefs(Record *CurRec, SMLoc Loc, IterSet &IterVals){
+ // Recursively build a tuple of iterator values.
+ if (IterVals.size() != Loops.size()) {
+ assert(IterVals.size() < Loops.size());
+ ForeachLoop &CurLoop = Loops[IterVals.size()];
+ ListInit *List = dyn_cast<ListInit>(CurLoop.ListValue);
+ if (List == 0) {
+ 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);
+ IterVals.push_back(IterRecord(CurLoop.IterVar, ItemVal));
+ if (ProcessForeachDefs(CurRec, Loc, IterVals))
+ return true;
+ IterVals.pop_back();
+ }
+ return false;
+ }
+
+ // 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);
+
+ // Set the iterator values now.
+ for (unsigned i = 0, e = IterVals.size(); i != e; ++i) {
+ VarInit *IterVar = IterVals[i].IterVar;
+ TypedInit *IVal = dyn_cast<TypedInit>(IterVals[i].IterValue);
+ if (IVal == 0) {
+ Error(Loc, "foreach iterator value is untyped");
+ return true;
+ }
+
+ 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;
+ }
+
+ // Resolve it next.
+ IterRec->resolveReferencesTo(IterRec->getValue(IterVar->getName()));
+
+ // Remove it.
+ IterRec->removeValue(IterVar->getName());
+ }
+
+ if (Records.getDef(IterRec->getNameInitAsString())) {
+ Error(Loc, "def already exists: " + IterRec->getNameInitAsString());
+ return true;
+ }
+
+ Records.addDef(IterRec);
+ IterRec->resolveReferences();
+ return false;
+}
+
//===----------------------------------------------------------------------===//
// Parser Code
//===----------------------------------------------------------------------===//
/// isObjectStart - Return true if this is a valid first token for an Object.
static bool isObjectStart(tgtok::TokKind K) {
return K == tgtok::Class || K == tgtok::Def ||
- K == tgtok::Defm || K == tgtok::Let || K == tgtok::MultiClass;
+ K == tgtok::Defm || K == tgtok::Let ||
+ K == tgtok::MultiClass || K == tgtok::Foreach;
}
static std::string GetNewAnonymousName() {
/// ParseObjectName - If an object name is specified, return it. Otherwise,
/// return an anonymous name.
-/// ObjectName ::= ID
+/// ObjectName ::= Value [ '#' Value ]*
/// ObjectName ::= /*empty*/
///
-std::string TGParser::ParseObjectName() {
- if (Lex.getCode() != tgtok::Id)
- return GetNewAnonymousName();
+Init *TGParser::ParseObjectName(MultiClass *CurMultiClass) {
+ switch (Lex.getCode()) {
+ case tgtok::colon:
+ case tgtok::semi:
+ case tgtok::l_brace:
+ // 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());
+ default:
+ break;
+ }
- std::string Ret = Lex.getCurStrVal();
- Lex.Lex();
- return Ret;
-}
+ Record *CurRec = 0;
+ if (CurMultiClass)
+ CurRec = &CurMultiClass->Rec;
+
+ RecTy *Type = 0;
+ if (CurRec) {
+ const TypedInit *CurRecName = dyn_cast<TypedInit>(CurRec->getNameInit());
+ if (!CurRecName) {
+ TokError("Record name is not typed!");
+ return 0;
+ }
+ Type = CurRecName->getType();
+ }
+ return ParseValue(CurRec, Type, ParseNameMode);
+}
/// ParseClassID - Parse and resolve a reference to a class name. This returns
/// null on error.
/// ParseType - Parse and return a tblgen type. This returns null on error.
///
/// Type ::= STRING // string type
+/// Type ::= CODE // code type
/// Type ::= BIT // bit type
/// Type ::= BITS '<' INTVAL '>' // bits<x> type
/// Type ::= INT // int type
/// Type ::= LIST '<' Type '>' // list<x> type
-/// Type ::= CODE // code type
/// Type ::= DAG // dag type
/// Type ::= ClassID // Record Type
///
switch (Lex.getCode()) {
default: TokError("Unknown token when expecting a type"); return 0;
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::Int: Lex.Lex(); return IntRecTy::get();
- case tgtok::Code: Lex.Lex(); return CodeRecTy::get();
case tgtok::Dag: Lex.Lex(); return DagRecTy::get();
case tgtok::Id:
if (Record *R = ParseClassID()) return RecordRecTy::get(R);
}
}
+ // If this is in a foreach loop, make sure it's not a loop iterator
+ for (LoopVector::iterator i = Loops.begin(), iend = Loops.end();
+ i != iend;
+ ++i) {
+ VarInit *IterVar = dyn_cast<VarInit>(i->IterVar);
+ if (IterVar && IterVar->getName() == Name)
+ return IterVar;
+ }
+
if (Mode == ParseNameMode)
return StringInit::get(Name);
default:
TokError("unknown operation");
return 0;
- break;
case tgtok::XHead:
case tgtok::XTail:
case tgtok::XEmpty:
RecTy *Type = 0;
switch (Lex.getCode()) {
- default: assert(0 && "Unhandled code!");
+ default: llvm_unreachable("Unhandled code!");
case tgtok::XCast:
Lex.Lex(); // eat the operation
Code = UnOpInit::CAST;
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);
+ ListInit *LHSl = dyn_cast<ListInit>(LHS);
+ StringInit *LHSs = dyn_cast<StringInit>(LHS);
+ TypedInit *LHSt = dyn_cast<TypedInit>(LHS);
if (LHSl == 0 && LHSs == 0 && LHSt == 0) {
TokError("expected list or string type argument in unary operator");
return 0;
}
if (LHSt) {
- ListRecTy *LType = dynamic_cast<ListRecTy*>(LHSt->getType());
- StringRecTy *SType = dynamic_cast<StringRecTy*>(LHSt->getType());
+ ListRecTy *LType = dyn_cast<ListRecTy>(LHSt->getType());
+ StringRecTy *SType = dyn_cast<StringRecTy>(LHSt->getType());
if (LType == 0 && SType == 0) {
TokError("expected list or string type argumnet in unary operator");
return 0;
}
if (LHSl) {
Init *Item = LHSl->getElement(0);
- TypedInit *Itemt = dynamic_cast<TypedInit*>(Item);
+ TypedInit *Itemt = dyn_cast<TypedInit>(Item);
if (Itemt == 0) {
TokError("untyped list element in unary operator");
return 0;
}
} else {
assert(LHSt && "expected list type argument in unary operator");
- ListRecTy *LType = dynamic_cast<ListRecTy*>(LHSt->getType());
+ ListRecTy *LType = dyn_cast<ListRecTy>(LHSt->getType());
if (LType == 0) {
TokError("expected list type argumnet in unary operator");
return 0;
RecTy *Type = 0;
switch (OpTok) {
- default: assert(0 && "Unhandled code!");
+ default: llvm_unreachable("Unhandled code!");
case tgtok::XConcat: Code = BinOpInit::CONCAT;Type = DagRecTy::get(); break;
case tgtok::XSRA: Code = BinOpInit::SRA; Type = IntRecTy::get(); break;
case tgtok::XSRL: Code = BinOpInit::SRL; Type = IntRecTy::get(); break;
tgtok::TokKind LexCode = Lex.getCode();
Lex.Lex(); // eat the operation
switch (LexCode) {
- default: assert(0 && "Unhandled code!");
+ default: llvm_unreachable("Unhandled code!");
case tgtok::XIf:
Code = TernOpInit::IF;
break;
Lex.Lex(); // eat the ')'
switch (LexCode) {
- default: assert(0 && "Unhandled code!");
+ 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);
-
- 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");
break;
}
case tgtok::XForEach: {
- TypedInit *MHSt = dynamic_cast<TypedInit *>(MHS);
+ TypedInit *MHSt = dyn_cast<TypedInit>(MHS);
if (MHSt == 0) {
TokError("could not get type for !foreach");
return 0;
break;
}
case tgtok::XSubst: {
- TypedInit *RHSt = dynamic_cast<TypedInit *>(RHS);
+ TypedInit *RHSt = dyn_cast<TypedInit>(RHS);
if (RHSt == 0) {
TokError("could not get type for !subst");
return 0;
CurMultiClass);
}
}
- TokError("could not parse operation");
- return 0;
}
/// ParseOperatorType - Parse a type for an operator. This returns
Init *R = 0;
switch (Lex.getCode()) {
default: TokError("Unknown token when parsing a value"); break;
+ case tgtok::paste:
+ // This is a leading paste operation. This is deprecated but
+ // still exists in some .td files. Ignore it.
+ Lex.Lex(); // Skip '#'.
+ return ParseSimpleValue(CurRec, ItemType, Mode);
case tgtok::IntVal: R = IntInit::get(Lex.getCurIntVal()); Lex.Lex(); break;
case tgtok::StrVal: {
std::string Val = Lex.getCurStrVal();
break;
}
case tgtok::CodeFragment:
- R = CodeInit::get(Lex.getCurStrVal());
+ R = StringInit::get(Lex.getCurStrVal());
Lex.Lex();
break;
case tgtok::question:
ListRecTy *GivenListTy = 0;
if (ItemType != 0) {
- ListRecTy *ListType = dynamic_cast<ListRecTy*>(ItemType);
+ ListRecTy *ListType = dyn_cast<ListRecTy>(ItemType);
if (ListType == 0) {
std::stringstream s;
s << "Type mismatch for list, expected list type, got "
for (std::vector<Init *>::iterator i = Vals.begin(), ie = Vals.end();
i != ie;
++i) {
- TypedInit *TArg = dynamic_cast<TypedInit*>(*i);
+ TypedInit *TArg = dyn_cast<TypedInit>(*i);
if (TArg == 0) {
TokError("Untyped list element");
return 0;
switch (Lex.getCode()) {
default: return Result;
case tgtok::l_brace: {
- if (Mode == ParseNameMode)
+ if (Mode == ParseNameMode || Mode == ParseForeachMode)
// This is the beginning of the object body.
return Result;
Result = FieldInit::get(Result, Lex.getCurStrVal());
Lex.Lex(); // eat field name
break;
+
+ case tgtok::paste:
+ SMLoc PasteLoc = Lex.getLoc();
+
+ // Create a !strconcat() operation, first casting each operand to
+ // a string if necessary.
+
+ TypedInit *LHS = dyn_cast<TypedInit>(Result);
+ if (!LHS) {
+ Error(PasteLoc, "LHS of paste is not typed!");
+ return 0;
+ }
+
+ if (LHS->getType() != StringRecTy::get()) {
+ LHS = UnOpInit::get(UnOpInit::CAST, LHS, StringRecTy::get());
+ }
+
+ TypedInit *RHS = 0;
+
+ Lex.Lex(); // Eat the '#'.
+ switch (Lex.getCode()) {
+ case tgtok::colon:
+ case tgtok::semi:
+ case tgtok::l_brace:
+ // 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.
+
+ // Trailing paste, concat with an empty string.
+ RHS = StringInit::get("");
+ break;
+
+ default:
+ Init *RHSResult = ParseValue(CurRec, ItemType, ParseNameMode);
+ RHS = dyn_cast<TypedInit>(RHSResult);
+ if (!RHS) {
+ Error(PasteLoc, "RHS of paste is not typed!");
+ return 0;
+ }
+
+ if (RHS->getType() != StringRecTy::get()) {
+ RHS = UnOpInit::get(UnOpInit::CAST, RHS, StringRecTy::get());
+ }
+
+ break;
+ }
+
+ Result = BinOpInit::get(BinOpInit::STRCONCAT, LHS, RHS,
+ StringRecTy::get())->Fold(CurRec, CurMultiClass);
+ break;
}
}
}
unsigned int ArgN = 0;
if (ArgsRec != 0 && EltTy == 0) {
const std::vector<Init *> &TArgs = ArgsRec->getTemplateArgs();
+ if (!TArgs.size()) {
+ TokError("template argument provided to non-template class");
+ return std::vector<Init*>();
+ }
const RecordVal *RV = ArgsRec->getValue(TArgs[ArgN]);
if (!RV) {
errs() << "Cannot find template arg " << ArgN << " (" << TArgs[ArgN]
return DeclName;
}
+/// ParseForeachDeclaration - Read a foreach declaration, returning
+/// the name of the declared object or a NULL Init on error. Return
+/// the name of the parsed initializer list through ForeachListName.
+///
+/// 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;
+ }
+
+ Init *DeclName = StringInit::get(Lex.getCurStrVal());
+ Lex.Lex();
+
+ // If a value is present, parse it.
+ if (Lex.getCode() != tgtok::equal) {
+ TokError("Expected '=' in foreach declaration");
+ return 0;
+ }
+ Lex.Lex(); // Eat the '='
+
+ RecTy *IterType = 0;
+ std::vector<unsigned> Ranges;
+
+ switch (Lex.getCode()) {
+ default: TokError("Unknown token when expecting a range list"); return 0;
+ case tgtok::l_square: { // '[' ValueList ']'
+ Init *List = ParseSimpleValue(0, 0, ParseForeachMode);
+ ForeachListValue = dyn_cast<ListInit>(List);
+ if (ForeachListValue == 0) {
+ TokError("Expected a Value list");
+ return 0;
+ }
+ RecTy *ValueType = ForeachListValue->getType();
+ ListRecTy *ListType = dyn_cast<ListRecTy>(ValueType);
+ if (ListType == 0) {
+ TokError("Value list is not of list type");
+ return 0;
+ }
+ IterType = ListType->getElementType();
+ break;
+ }
+
+ case tgtok::IntVal: { // RangePiece.
+ if (ParseRangePiece(Ranges))
+ return 0;
+ break;
+ }
+
+ 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 0;
+ }
+ 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);
+ }
+
+ if (!IterType)
+ return 0;
+
+ return VarInit::get(DeclName, IterType);
+}
+
/// ParseTemplateArgList - Read a template argument list, which is a non-empty
/// sequence of template-declarations in <>'s. If CurRec is non-null, these are
/// template args for a def, which may or may not be in a multiclass. If null,
Lex.Lex(); // Eat the 'def' token.
// Parse ObjectName and make a record for it.
- Record *CurRec = new Record(ParseObjectName(), DefLoc, Records);
+ Record *CurRec = new Record(ParseObjectName(CurMultiClass), DefLoc, Records);
- if (!CurMultiClass) {
+ if (!CurMultiClass && Loops.empty()) {
// Top-level def definition.
// Ensure redefinition doesn't happen.
- if (Records.getDef(CurRec->getName())) {
+ if (Records.getDef(CurRec->getNameInitAsString())) {
Error(DefLoc, "def '" + CurRec->getNameInitAsString()
+ "' already defined");
return true;
}
Records.addDef(CurRec);
- } else {
+ } else if (CurMultiClass) {
// 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()
}
}
+ if (ProcessForeachDefs(CurRec, DefLoc)) {
+ Error(DefLoc,
+ "Could not process loops for def" + CurRec->getNameInitAsString());
+ return true;
+ }
+
+ return false;
+}
+
+/// ParseForeach - Parse a for statement. Return the record corresponding
+/// to it. This returns true on error.
+///
+/// Foreach ::= FOREACH Declaration IN '{ ObjectList '}'
+/// Foreach ::= FOREACH Declaration IN Object
+///
+bool TGParser::ParseForeach(MultiClass *CurMultiClass) {
+ assert(Lex.getCode() == tgtok::Foreach && "Unknown tok");
+ Lex.Lex(); // Eat the 'for' token.
+
+ // Make a temporary object to record items associated with the for
+ // loop.
+ ListInit *ListValue = 0;
+ VarInit *IterName = ParseForeachDeclaration(ListValue);
+ if (IterName == 0)
+ return TokError("expected declaration in for");
+
+ if (Lex.getCode() != tgtok::In)
+ return TokError("Unknown tok");
+ Lex.Lex(); // Eat the in
+
+ // Create a loop object and remember it.
+ Loops.push_back(ForeachLoop(IterName, ListValue));
+
+ if (Lex.getCode() != tgtok::l_brace) {
+ // FOREACH Declaration IN Object
+ if (ParseObject(CurMultiClass))
+ return true;
+ }
+ else {
+ SMLoc BraceLoc = Lex.getLoc();
+ // Otherwise, this is a group foreach.
+ Lex.Lex(); // eat the '{'.
+
+ // Parse the object list.
+ if (ParseObjectList(CurMultiClass))
+ return true;
+
+ if (Lex.getCode() != tgtok::r_brace) {
+ TokError("expected '}' at end of foreach command");
+ return Error(BraceLoc, "to match this '{'");
+ }
+ Lex.Lex(); // Eat the }
+ }
+
+ // We've processed everything in this loop.
+ Loops.pop_back();
+
return false;
}
case tgtok::Let:
case tgtok::Def:
case tgtok::Defm:
+ case tgtok::Foreach:
if (ParseObject(CurMultiClass))
return true;
break;
Record *TGParser::
InstantiateMulticlassDef(MultiClass &MC,
Record *DefProto,
- const std::string &DefmPrefix,
+ Init *DefmPrefix,
SMLoc DefmPrefixLoc) {
+ // We need to preserve DefProto so it can be reused for later
+ // instantiations, so create a new Record to inherit from it.
+
// Add in the defm name. If the defm prefix is empty, give each
// instantiated def a unique name. Otherwise, if "#NAME#" exists in the
// name, substitute the prefix for #NAME#. Otherwise, use the defm name
// as a prefix.
- std::string DefName = DefProto->getName();
- if (DefmPrefix.empty()) {
- DefName = GetNewAnonymousName();
- } else {
- std::string::size_type idx = DefName.find("#NAME#");
- if (idx != std::string::npos) {
- DefName.replace(idx, 6, DefmPrefix);
- } else {
- // Add the suffix to the defm name to get the new name.
- DefName = DefmPrefix + DefName;
- }
+
+ if (DefmPrefix == 0)
+ DefmPrefix = StringInit::get(GetNewAnonymousName());
+
+ Init *DefName = DefProto->getNameInit();
+
+ StringInit *DefNameString = dyn_cast<StringInit>(DefName);
+
+ if (DefNameString != 0) {
+ // We have a fully expanded string so there are no operators to
+ // resolve. We should concatenate the given prefix and name.
+ DefName =
+ BinOpInit::get(BinOpInit::STRCONCAT,
+ UnOpInit::get(UnOpInit::CAST, DefmPrefix,
+ StringRecTy::get())->Fold(DefProto, &MC),
+ 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, DefmPrefixLoc);
+ Locs.append(DefProto->getLoc().begin(), DefProto->getLoc().end());
+ Record *CurRec = new Record(DefName, Locs, Records);
SubClassReference Ref;
Ref.RefLoc = DefmPrefixLoc;
Ref.Rec = DefProto;
AddSubClass(CurRec, 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, Ref.RefLoc, "NAME", std::vector<unsigned>(),
+ DefmPrefix)) {
+ Error(DefmPrefixLoc, "Could not resolve "
+ + CurRec->getNameInitAsString() + ":NAME to '"
+ + DefmPrefix->getAsUnquotedString() + "'");
+ return 0;
+ }
+
+ // 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 == 0) {
+ RecordVal *DefNameRV = CurRec->getValue("NAME");
+ CurRec->resolveReferencesTo(DefNameRV);
+ }
+
+ if (!CurMultiClass) {
+ // 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
+ // RecordKeeper at this point. If we did we could get duplicate
+ // defs as more than one probably refers to NAME or some other
+ // common internal placeholder.
+
+ // Ensure redefinition doesn't happen.
+ if (Records.getDef(CurRec->getNameInitAsString())) {
+ Error(DefmPrefixLoc, "def '" + CurRec->getNameInitAsString() +
+ "' already defined, instantiating defm with subdef '" +
+ DefProto->getNameInitAsString() + "'");
+ return 0;
+ }
+
+ Records.addDef(CurRec);
+ }
+
return CurRec;
}
LetStack[i][j].Bits, LetStack[i][j].Value))
return Error(DefmPrefixLoc, "when instantiating this defm");
- // Ensure redefinition doesn't happen.
- if (Records.getDef(CurRec->getName()))
- return Error(DefmPrefixLoc, "def '" + CurRec->getName() +
- "' already defined, instantiating defm with subdef '" +
- DefProto->getName() + "'");
-
// 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.
assert(RV && "Template arg doesn't exist?");
CurRec->addValue(*RV);
}
- } else {
- Records.addDef(CurRec);
}
return false;
bool TGParser::ParseDefm(MultiClass *CurMultiClass) {
assert(Lex.getCode() == tgtok::Defm && "Unexpected token!");
- std::string DefmPrefix;
- if (Lex.Lex() == tgtok::Id) { // eat the defm.
- DefmPrefix = Lex.getCurStrVal();
- Lex.Lex(); // Eat the defm prefix.
+ Init *DefmPrefix = 0;
+
+ Lex.Lex(); // eat the defm.
+
+ // Note that tgtok::paste is here to allow starting with #NAME.
+ if (Lex.getCode() == tgtok::Id ||
+ Lex.getCode() == tgtok::paste) {
+ DefmPrefix = ParseObjectName(CurMultiClass);
}
SMLoc DefmPrefixLoc = Lex.getLoc();
Record *DefProto = MC->DefPrototypes[i];
Record *CurRec = InstantiateMulticlassDef(*MC, DefProto, DefmPrefix, DefmPrefixLoc);
+ if (!CurRec)
+ return true;
if (ResolveMulticlassDefArgs(*MC, CurRec, DefmPrefixLoc, SubClassLoc,
TArgs, TemplateVals, true/*Delete args*/))
return TokError("Expected class, def, defm, multiclass or let definition");
case tgtok::Let: return ParseTopLevelLet(MC);
case tgtok::Def: return ParseDef(MC);
+ case tgtok::Foreach: return ParseForeach(MC);
case tgtok::Defm: return ParseDefm(MC);
case tgtok::Class: return ParseClass();
case tgtok::MultiClass: return ParseMultiClass();