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llvm-mirror/lib/AsmParser/LLParser.cpp
Saleem Abdulrasool 322826fdb1 ASMParser: use range-based for loops (NFC)
Convert the verify method to use a few more range based for loops,
converting to const iterators in the process.

llvm-svn: 290617
2016-12-27 18:35:22 +00:00

6562 lines
224 KiB
C++

//===-- LLParser.cpp - Parser Class ---------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines the parser class for .ll files.
//
//===----------------------------------------------------------------------===//
#include "LLParser.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/None.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/AsmParser/SlotMapping.h"
#include "llvm/IR/Argument.h"
#include "llvm/IR/AutoUpgrade.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/CallingConv.h"
#include "llvm/IR/Comdat.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/DebugInfoMetadata.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/GlobalIFunc.h"
#include "llvm/IR/GlobalObject.h"
#include "llvm/IR/InlineAsm.h"
#include "llvm/IR/Instruction.h"
#include "llvm/IR/Instructions.h"
#include "llvm/IR/Intrinsics.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/IR/Metadata.h"
#include "llvm/IR/Module.h"
#include "llvm/IR/Operator.h"
#include "llvm/IR/Type.h"
#include "llvm/IR/Value.h"
#include "llvm/IR/ValueSymbolTable.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/Dwarf.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/SaveAndRestore.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <cassert>
#include <cstring>
#include <iterator>
#include <vector>
using namespace llvm;
static std::string getTypeString(Type *T) {
std::string Result;
raw_string_ostream Tmp(Result);
Tmp << *T;
return Tmp.str();
}
/// Run: module ::= toplevelentity*
bool LLParser::Run() {
// Prime the lexer.
Lex.Lex();
if (Context.shouldDiscardValueNames())
return Error(
Lex.getLoc(),
"Can't read textual IR with a Context that discards named Values");
return ParseTopLevelEntities() ||
ValidateEndOfModule();
}
bool LLParser::parseStandaloneConstantValue(Constant *&C,
const SlotMapping *Slots) {
restoreParsingState(Slots);
Lex.Lex();
Type *Ty = nullptr;
if (ParseType(Ty) || parseConstantValue(Ty, C))
return true;
if (Lex.getKind() != lltok::Eof)
return Error(Lex.getLoc(), "expected end of string");
return false;
}
bool LLParser::parseTypeAtBeginning(Type *&Ty, unsigned &Read,
const SlotMapping *Slots) {
restoreParsingState(Slots);
Lex.Lex();
Read = 0;
SMLoc Start = Lex.getLoc();
Ty = nullptr;
if (ParseType(Ty))
return true;
SMLoc End = Lex.getLoc();
Read = End.getPointer() - Start.getPointer();
return false;
}
void LLParser::restoreParsingState(const SlotMapping *Slots) {
if (!Slots)
return;
NumberedVals = Slots->GlobalValues;
NumberedMetadata = Slots->MetadataNodes;
for (const auto &I : Slots->NamedTypes)
NamedTypes.insert(
std::make_pair(I.getKey(), std::make_pair(I.second, LocTy())));
for (const auto &I : Slots->Types)
NumberedTypes.insert(
std::make_pair(I.first, std::make_pair(I.second, LocTy())));
}
/// ValidateEndOfModule - Do final validity and sanity checks at the end of the
/// module.
bool LLParser::ValidateEndOfModule() {
// Handle any function attribute group forward references.
for (const auto &RAG : ForwardRefAttrGroups) {
Value *V = RAG.first;
const std::vector<unsigned> &Attrs = RAG.second;
AttrBuilder B;
for (const auto &Attr : Attrs)
B.merge(NumberedAttrBuilders[Attr]);
if (Function *Fn = dyn_cast<Function>(V)) {
AttributeSet AS = Fn->getAttributes();
AttrBuilder FnAttrs(AS.getFnAttributes(), AttributeSet::FunctionIndex);
AS = AS.removeAttributes(Context, AttributeSet::FunctionIndex,
AS.getFnAttributes());
FnAttrs.merge(B);
// If the alignment was parsed as an attribute, move to the alignment
// field.
if (FnAttrs.hasAlignmentAttr()) {
Fn->setAlignment(FnAttrs.getAlignment());
FnAttrs.removeAttribute(Attribute::Alignment);
}
AS = AS.addAttributes(Context, AttributeSet::FunctionIndex,
AttributeSet::get(Context,
AttributeSet::FunctionIndex,
FnAttrs));
Fn->setAttributes(AS);
} else if (CallInst *CI = dyn_cast<CallInst>(V)) {
AttributeSet AS = CI->getAttributes();
AttrBuilder FnAttrs(AS.getFnAttributes(), AttributeSet::FunctionIndex);
AS = AS.removeAttributes(Context, AttributeSet::FunctionIndex,
AS.getFnAttributes());
FnAttrs.merge(B);
AS = AS.addAttributes(Context, AttributeSet::FunctionIndex,
AttributeSet::get(Context,
AttributeSet::FunctionIndex,
FnAttrs));
CI->setAttributes(AS);
} else if (InvokeInst *II = dyn_cast<InvokeInst>(V)) {
AttributeSet AS = II->getAttributes();
AttrBuilder FnAttrs(AS.getFnAttributes(), AttributeSet::FunctionIndex);
AS = AS.removeAttributes(Context, AttributeSet::FunctionIndex,
AS.getFnAttributes());
FnAttrs.merge(B);
AS = AS.addAttributes(Context, AttributeSet::FunctionIndex,
AttributeSet::get(Context,
AttributeSet::FunctionIndex,
FnAttrs));
II->setAttributes(AS);
} else {
llvm_unreachable("invalid object with forward attribute group reference");
}
}
// If there are entries in ForwardRefBlockAddresses at this point, the
// function was never defined.
if (!ForwardRefBlockAddresses.empty())
return Error(ForwardRefBlockAddresses.begin()->first.Loc,
"expected function name in blockaddress");
for (const auto &NT : NumberedTypes)
if (NT.second.second.isValid())
return Error(NT.second.second,
"use of undefined type '%" + Twine(NT.first) + "'");
for (StringMap<std::pair<Type*, LocTy> >::iterator I =
NamedTypes.begin(), E = NamedTypes.end(); I != E; ++I)
if (I->second.second.isValid())
return Error(I->second.second,
"use of undefined type named '" + I->getKey() + "'");
if (!ForwardRefComdats.empty())
return Error(ForwardRefComdats.begin()->second,
"use of undefined comdat '$" +
ForwardRefComdats.begin()->first + "'");
if (!ForwardRefVals.empty())
return Error(ForwardRefVals.begin()->second.second,
"use of undefined value '@" + ForwardRefVals.begin()->first +
"'");
if (!ForwardRefValIDs.empty())
return Error(ForwardRefValIDs.begin()->second.second,
"use of undefined value '@" +
Twine(ForwardRefValIDs.begin()->first) + "'");
if (!ForwardRefMDNodes.empty())
return Error(ForwardRefMDNodes.begin()->second.second,
"use of undefined metadata '!" +
Twine(ForwardRefMDNodes.begin()->first) + "'");
// Resolve metadata cycles.
for (auto &N : NumberedMetadata) {
if (N.second && !N.second->isResolved())
N.second->resolveCycles();
}
for (auto *Inst : InstsWithTBAATag) {
MDNode *MD = Inst->getMetadata(LLVMContext::MD_tbaa);
assert(MD && "UpgradeInstWithTBAATag should have a TBAA tag");
auto *UpgradedMD = UpgradeTBAANode(*MD);
if (MD != UpgradedMD)
Inst->setMetadata(LLVMContext::MD_tbaa, UpgradedMD);
}
// Look for intrinsic functions and CallInst that need to be upgraded
for (Module::iterator FI = M->begin(), FE = M->end(); FI != FE; )
UpgradeCallsToIntrinsic(&*FI++); // must be post-increment, as we remove
// Some types could be renamed during loading if several modules are
// loaded in the same LLVMContext (LTO scenario). In this case we should
// remangle intrinsics names as well.
for (Module::iterator FI = M->begin(), FE = M->end(); FI != FE; ) {
Function *F = &*FI++;
if (auto Remangled = Intrinsic::remangleIntrinsicFunction(F)) {
F->replaceAllUsesWith(Remangled.getValue());
F->eraseFromParent();
}
}
UpgradeDebugInfo(*M);
UpgradeModuleFlags(*M);
if (!Slots)
return false;
// Initialize the slot mapping.
// Because by this point we've parsed and validated everything, we can "steal"
// the mapping from LLParser as it doesn't need it anymore.
Slots->GlobalValues = std::move(NumberedVals);
Slots->MetadataNodes = std::move(NumberedMetadata);
for (const auto &I : NamedTypes)
Slots->NamedTypes.insert(std::make_pair(I.getKey(), I.second.first));
for (const auto &I : NumberedTypes)
Slots->Types.insert(std::make_pair(I.first, I.second.first));
return false;
}
//===----------------------------------------------------------------------===//
// Top-Level Entities
//===----------------------------------------------------------------------===//
bool LLParser::ParseTopLevelEntities() {
while (true) {
switch (Lex.getKind()) {
default: return TokError("expected top-level entity");
case lltok::Eof: return false;
case lltok::kw_declare: if (ParseDeclare()) return true; break;
case lltok::kw_define: if (ParseDefine()) return true; break;
case lltok::kw_module: if (ParseModuleAsm()) return true; break;
case lltok::kw_target: if (ParseTargetDefinition()) return true; break;
case lltok::kw_source_filename:
if (ParseSourceFileName())
return true;
break;
case lltok::kw_deplibs: if (ParseDepLibs()) return true; break;
case lltok::LocalVarID: if (ParseUnnamedType()) return true; break;
case lltok::LocalVar: if (ParseNamedType()) return true; break;
case lltok::GlobalID: if (ParseUnnamedGlobal()) return true; break;
case lltok::GlobalVar: if (ParseNamedGlobal()) return true; break;
case lltok::ComdatVar: if (parseComdat()) return true; break;
case lltok::exclaim: if (ParseStandaloneMetadata()) return true; break;
case lltok::MetadataVar:if (ParseNamedMetadata()) return true; break;
case lltok::kw_attributes: if (ParseUnnamedAttrGrp()) return true; break;
case lltok::kw_uselistorder: if (ParseUseListOrder()) return true; break;
case lltok::kw_uselistorder_bb:
if (ParseUseListOrderBB())
return true;
break;
}
}
}
/// toplevelentity
/// ::= 'module' 'asm' STRINGCONSTANT
bool LLParser::ParseModuleAsm() {
assert(Lex.getKind() == lltok::kw_module);
Lex.Lex();
std::string AsmStr;
if (ParseToken(lltok::kw_asm, "expected 'module asm'") ||
ParseStringConstant(AsmStr)) return true;
M->appendModuleInlineAsm(AsmStr);
return false;
}
/// toplevelentity
/// ::= 'target' 'triple' '=' STRINGCONSTANT
/// ::= 'target' 'datalayout' '=' STRINGCONSTANT
bool LLParser::ParseTargetDefinition() {
assert(Lex.getKind() == lltok::kw_target);
std::string Str;
switch (Lex.Lex()) {
default: return TokError("unknown target property");
case lltok::kw_triple:
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after target triple") ||
ParseStringConstant(Str))
return true;
M->setTargetTriple(Str);
return false;
case lltok::kw_datalayout:
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after target datalayout") ||
ParseStringConstant(Str))
return true;
M->setDataLayout(Str);
return false;
}
}
/// toplevelentity
/// ::= 'source_filename' '=' STRINGCONSTANT
bool LLParser::ParseSourceFileName() {
assert(Lex.getKind() == lltok::kw_source_filename);
std::string Str;
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after source_filename") ||
ParseStringConstant(Str))
return true;
M->setSourceFileName(Str);
return false;
}
/// toplevelentity
/// ::= 'deplibs' '=' '[' ']'
/// ::= 'deplibs' '=' '[' STRINGCONSTANT (',' STRINGCONSTANT)* ']'
/// FIXME: Remove in 4.0. Currently parse, but ignore.
bool LLParser::ParseDepLibs() {
assert(Lex.getKind() == lltok::kw_deplibs);
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after deplibs") ||
ParseToken(lltok::lsquare, "expected '=' after deplibs"))
return true;
if (EatIfPresent(lltok::rsquare))
return false;
do {
std::string Str;
if (ParseStringConstant(Str)) return true;
} while (EatIfPresent(lltok::comma));
return ParseToken(lltok::rsquare, "expected ']' at end of list");
}
/// ParseUnnamedType:
/// ::= LocalVarID '=' 'type' type
bool LLParser::ParseUnnamedType() {
LocTy TypeLoc = Lex.getLoc();
unsigned TypeID = Lex.getUIntVal();
Lex.Lex(); // eat LocalVarID;
if (ParseToken(lltok::equal, "expected '=' after name") ||
ParseToken(lltok::kw_type, "expected 'type' after '='"))
return true;
Type *Result = nullptr;
if (ParseStructDefinition(TypeLoc, "",
NumberedTypes[TypeID], Result)) return true;
if (!isa<StructType>(Result)) {
std::pair<Type*, LocTy> &Entry = NumberedTypes[TypeID];
if (Entry.first)
return Error(TypeLoc, "non-struct types may not be recursive");
Entry.first = Result;
Entry.second = SMLoc();
}
return false;
}
/// toplevelentity
/// ::= LocalVar '=' 'type' type
bool LLParser::ParseNamedType() {
std::string Name = Lex.getStrVal();
LocTy NameLoc = Lex.getLoc();
Lex.Lex(); // eat LocalVar.
if (ParseToken(lltok::equal, "expected '=' after name") ||
ParseToken(lltok::kw_type, "expected 'type' after name"))
return true;
Type *Result = nullptr;
if (ParseStructDefinition(NameLoc, Name,
NamedTypes[Name], Result)) return true;
if (!isa<StructType>(Result)) {
std::pair<Type*, LocTy> &Entry = NamedTypes[Name];
if (Entry.first)
return Error(NameLoc, "non-struct types may not be recursive");
Entry.first = Result;
Entry.second = SMLoc();
}
return false;
}
/// toplevelentity
/// ::= 'declare' FunctionHeader
bool LLParser::ParseDeclare() {
assert(Lex.getKind() == lltok::kw_declare);
Lex.Lex();
std::vector<std::pair<unsigned, MDNode *>> MDs;
while (Lex.getKind() == lltok::MetadataVar) {
unsigned MDK;
MDNode *N;
if (ParseMetadataAttachment(MDK, N))
return true;
MDs.push_back({MDK, N});
}
Function *F;
if (ParseFunctionHeader(F, false))
return true;
for (auto &MD : MDs)
F->addMetadata(MD.first, *MD.second);
return false;
}
/// toplevelentity
/// ::= 'define' FunctionHeader (!dbg !56)* '{' ...
bool LLParser::ParseDefine() {
assert(Lex.getKind() == lltok::kw_define);
Lex.Lex();
Function *F;
return ParseFunctionHeader(F, true) ||
ParseOptionalFunctionMetadata(*F) ||
ParseFunctionBody(*F);
}
/// ParseGlobalType
/// ::= 'constant'
/// ::= 'global'
bool LLParser::ParseGlobalType(bool &IsConstant) {
if (Lex.getKind() == lltok::kw_constant)
IsConstant = true;
else if (Lex.getKind() == lltok::kw_global)
IsConstant = false;
else {
IsConstant = false;
return TokError("expected 'global' or 'constant'");
}
Lex.Lex();
return false;
}
bool LLParser::ParseOptionalUnnamedAddr(
GlobalVariable::UnnamedAddr &UnnamedAddr) {
if (EatIfPresent(lltok::kw_unnamed_addr))
UnnamedAddr = GlobalValue::UnnamedAddr::Global;
else if (EatIfPresent(lltok::kw_local_unnamed_addr))
UnnamedAddr = GlobalValue::UnnamedAddr::Local;
else
UnnamedAddr = GlobalValue::UnnamedAddr::None;
return false;
}
/// ParseUnnamedGlobal:
/// OptionalVisibility (ALIAS | IFUNC) ...
/// OptionalLinkage OptionalVisibility OptionalDLLStorageClass
/// ... -> global variable
/// GlobalID '=' OptionalVisibility (ALIAS | IFUNC) ...
/// GlobalID '=' OptionalLinkage OptionalVisibility OptionalDLLStorageClass
/// ... -> global variable
bool LLParser::ParseUnnamedGlobal() {
unsigned VarID = NumberedVals.size();
std::string Name;
LocTy NameLoc = Lex.getLoc();
// Handle the GlobalID form.
if (Lex.getKind() == lltok::GlobalID) {
if (Lex.getUIntVal() != VarID)
return Error(Lex.getLoc(), "variable expected to be numbered '%" +
Twine(VarID) + "'");
Lex.Lex(); // eat GlobalID;
if (ParseToken(lltok::equal, "expected '=' after name"))
return true;
}
bool HasLinkage;
unsigned Linkage, Visibility, DLLStorageClass;
GlobalVariable::ThreadLocalMode TLM;
GlobalVariable::UnnamedAddr UnnamedAddr;
if (ParseOptionalLinkage(Linkage, HasLinkage, Visibility, DLLStorageClass) ||
ParseOptionalThreadLocal(TLM) || ParseOptionalUnnamedAddr(UnnamedAddr))
return true;
if (Lex.getKind() != lltok::kw_alias && Lex.getKind() != lltok::kw_ifunc)
return ParseGlobal(Name, NameLoc, Linkage, HasLinkage, Visibility,
DLLStorageClass, TLM, UnnamedAddr);
return parseIndirectSymbol(Name, NameLoc, Linkage, Visibility,
DLLStorageClass, TLM, UnnamedAddr);
}
/// ParseNamedGlobal:
/// GlobalVar '=' OptionalVisibility (ALIAS | IFUNC) ...
/// GlobalVar '=' OptionalLinkage OptionalVisibility OptionalDLLStorageClass
/// ... -> global variable
bool LLParser::ParseNamedGlobal() {
assert(Lex.getKind() == lltok::GlobalVar);
LocTy NameLoc = Lex.getLoc();
std::string Name = Lex.getStrVal();
Lex.Lex();
bool HasLinkage;
unsigned Linkage, Visibility, DLLStorageClass;
GlobalVariable::ThreadLocalMode TLM;
GlobalVariable::UnnamedAddr UnnamedAddr;
if (ParseToken(lltok::equal, "expected '=' in global variable") ||
ParseOptionalLinkage(Linkage, HasLinkage, Visibility, DLLStorageClass) ||
ParseOptionalThreadLocal(TLM) || ParseOptionalUnnamedAddr(UnnamedAddr))
return true;
if (Lex.getKind() != lltok::kw_alias && Lex.getKind() != lltok::kw_ifunc)
return ParseGlobal(Name, NameLoc, Linkage, HasLinkage, Visibility,
DLLStorageClass, TLM, UnnamedAddr);
return parseIndirectSymbol(Name, NameLoc, Linkage, Visibility,
DLLStorageClass, TLM, UnnamedAddr);
}
bool LLParser::parseComdat() {
assert(Lex.getKind() == lltok::ComdatVar);
std::string Name = Lex.getStrVal();
LocTy NameLoc = Lex.getLoc();
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' here"))
return true;
if (ParseToken(lltok::kw_comdat, "expected comdat keyword"))
return TokError("expected comdat type");
Comdat::SelectionKind SK;
switch (Lex.getKind()) {
default:
return TokError("unknown selection kind");
case lltok::kw_any:
SK = Comdat::Any;
break;
case lltok::kw_exactmatch:
SK = Comdat::ExactMatch;
break;
case lltok::kw_largest:
SK = Comdat::Largest;
break;
case lltok::kw_noduplicates:
SK = Comdat::NoDuplicates;
break;
case lltok::kw_samesize:
SK = Comdat::SameSize;
break;
}
Lex.Lex();
// See if the comdat was forward referenced, if so, use the comdat.
Module::ComdatSymTabType &ComdatSymTab = M->getComdatSymbolTable();
Module::ComdatSymTabType::iterator I = ComdatSymTab.find(Name);
if (I != ComdatSymTab.end() && !ForwardRefComdats.erase(Name))
return Error(NameLoc, "redefinition of comdat '$" + Name + "'");
Comdat *C;
if (I != ComdatSymTab.end())
C = &I->second;
else
C = M->getOrInsertComdat(Name);
C->setSelectionKind(SK);
return false;
}
// MDString:
// ::= '!' STRINGCONSTANT
bool LLParser::ParseMDString(MDString *&Result) {
std::string Str;
if (ParseStringConstant(Str)) return true;
Result = MDString::get(Context, Str);
return false;
}
// MDNode:
// ::= '!' MDNodeNumber
bool LLParser::ParseMDNodeID(MDNode *&Result) {
// !{ ..., !42, ... }
LocTy IDLoc = Lex.getLoc();
unsigned MID = 0;
if (ParseUInt32(MID))
return true;
// If not a forward reference, just return it now.
if (NumberedMetadata.count(MID)) {
Result = NumberedMetadata[MID];
return false;
}
// Otherwise, create MDNode forward reference.
auto &FwdRef = ForwardRefMDNodes[MID];
FwdRef = std::make_pair(MDTuple::getTemporary(Context, None), IDLoc);
Result = FwdRef.first.get();
NumberedMetadata[MID].reset(Result);
return false;
}
/// ParseNamedMetadata:
/// !foo = !{ !1, !2 }
bool LLParser::ParseNamedMetadata() {
assert(Lex.getKind() == lltok::MetadataVar);
std::string Name = Lex.getStrVal();
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' here") ||
ParseToken(lltok::exclaim, "Expected '!' here") ||
ParseToken(lltok::lbrace, "Expected '{' here"))
return true;
NamedMDNode *NMD = M->getOrInsertNamedMetadata(Name);
if (Lex.getKind() != lltok::rbrace)
do {
if (ParseToken(lltok::exclaim, "Expected '!' here"))
return true;
MDNode *N = nullptr;
if (ParseMDNodeID(N)) return true;
NMD->addOperand(N);
} while (EatIfPresent(lltok::comma));
return ParseToken(lltok::rbrace, "expected end of metadata node");
}
/// ParseStandaloneMetadata:
/// !42 = !{...}
bool LLParser::ParseStandaloneMetadata() {
assert(Lex.getKind() == lltok::exclaim);
Lex.Lex();
unsigned MetadataID = 0;
MDNode *Init;
if (ParseUInt32(MetadataID) ||
ParseToken(lltok::equal, "expected '=' here"))
return true;
// Detect common error, from old metadata syntax.
if (Lex.getKind() == lltok::Type)
return TokError("unexpected type in metadata definition");
bool IsDistinct = EatIfPresent(lltok::kw_distinct);
if (Lex.getKind() == lltok::MetadataVar) {
if (ParseSpecializedMDNode(Init, IsDistinct))
return true;
} else if (ParseToken(lltok::exclaim, "Expected '!' here") ||
ParseMDTuple(Init, IsDistinct))
return true;
// See if this was forward referenced, if so, handle it.
auto FI = ForwardRefMDNodes.find(MetadataID);
if (FI != ForwardRefMDNodes.end()) {
FI->second.first->replaceAllUsesWith(Init);
ForwardRefMDNodes.erase(FI);
assert(NumberedMetadata[MetadataID] == Init && "Tracking VH didn't work");
} else {
if (NumberedMetadata.count(MetadataID))
return TokError("Metadata id is already used");
NumberedMetadata[MetadataID].reset(Init);
}
return false;
}
static bool isValidVisibilityForLinkage(unsigned V, unsigned L) {
return !GlobalValue::isLocalLinkage((GlobalValue::LinkageTypes)L) ||
(GlobalValue::VisibilityTypes)V == GlobalValue::DefaultVisibility;
}
/// parseIndirectSymbol:
/// ::= GlobalVar '=' OptionalLinkage OptionalVisibility
/// OptionalDLLStorageClass OptionalThreadLocal
/// OptionalUnnamedAddr 'alias|ifunc' IndirectSymbol
///
/// IndirectSymbol
/// ::= TypeAndValue
///
/// Everything through OptionalUnnamedAddr has already been parsed.
///
bool LLParser::parseIndirectSymbol(
const std::string &Name, LocTy NameLoc, unsigned L, unsigned Visibility,
unsigned DLLStorageClass, GlobalVariable::ThreadLocalMode TLM,
GlobalVariable::UnnamedAddr UnnamedAddr) {
bool IsAlias;
if (Lex.getKind() == lltok::kw_alias)
IsAlias = true;
else if (Lex.getKind() == lltok::kw_ifunc)
IsAlias = false;
else
llvm_unreachable("Not an alias or ifunc!");
Lex.Lex();
GlobalValue::LinkageTypes Linkage = (GlobalValue::LinkageTypes) L;
if(IsAlias && !GlobalAlias::isValidLinkage(Linkage))
return Error(NameLoc, "invalid linkage type for alias");
if (!isValidVisibilityForLinkage(Visibility, L))
return Error(NameLoc,
"symbol with local linkage must have default visibility");
Type *Ty;
LocTy ExplicitTypeLoc = Lex.getLoc();
if (ParseType(Ty) ||
ParseToken(lltok::comma, "expected comma after alias or ifunc's type"))
return true;
Constant *Aliasee;
LocTy AliaseeLoc = Lex.getLoc();
if (Lex.getKind() != lltok::kw_bitcast &&
Lex.getKind() != lltok::kw_getelementptr &&
Lex.getKind() != lltok::kw_addrspacecast &&
Lex.getKind() != lltok::kw_inttoptr) {
if (ParseGlobalTypeAndValue(Aliasee))
return true;
} else {
// The bitcast dest type is not present, it is implied by the dest type.
ValID ID;
if (ParseValID(ID))
return true;
if (ID.Kind != ValID::t_Constant)
return Error(AliaseeLoc, "invalid aliasee");
Aliasee = ID.ConstantVal;
}
Type *AliaseeType = Aliasee->getType();
auto *PTy = dyn_cast<PointerType>(AliaseeType);
if (!PTy)
return Error(AliaseeLoc, "An alias or ifunc must have pointer type");
unsigned AddrSpace = PTy->getAddressSpace();
if (IsAlias && Ty != PTy->getElementType())
return Error(
ExplicitTypeLoc,
"explicit pointee type doesn't match operand's pointee type");
if (!IsAlias && !PTy->getElementType()->isFunctionTy())
return Error(
ExplicitTypeLoc,
"explicit pointee type should be a function type");
GlobalValue *GVal = nullptr;
// See if the alias was forward referenced, if so, prepare to replace the
// forward reference.
if (!Name.empty()) {
GVal = M->getNamedValue(Name);
if (GVal) {
if (!ForwardRefVals.erase(Name))
return Error(NameLoc, "redefinition of global '@" + Name + "'");
}
} else {
auto I = ForwardRefValIDs.find(NumberedVals.size());
if (I != ForwardRefValIDs.end()) {
GVal = I->second.first;
ForwardRefValIDs.erase(I);
}
}
// Okay, create the alias but do not insert it into the module yet.
std::unique_ptr<GlobalIndirectSymbol> GA;
if (IsAlias)
GA.reset(GlobalAlias::create(Ty, AddrSpace,
(GlobalValue::LinkageTypes)Linkage, Name,
Aliasee, /*Parent*/ nullptr));
else
GA.reset(GlobalIFunc::create(Ty, AddrSpace,
(GlobalValue::LinkageTypes)Linkage, Name,
Aliasee, /*Parent*/ nullptr));
GA->setThreadLocalMode(TLM);
GA->setVisibility((GlobalValue::VisibilityTypes)Visibility);
GA->setDLLStorageClass((GlobalValue::DLLStorageClassTypes)DLLStorageClass);
GA->setUnnamedAddr(UnnamedAddr);
if (Name.empty())
NumberedVals.push_back(GA.get());
if (GVal) {
// Verify that types agree.
if (GVal->getType() != GA->getType())
return Error(
ExplicitTypeLoc,
"forward reference and definition of alias have different types");
// If they agree, just RAUW the old value with the alias and remove the
// forward ref info.
GVal->replaceAllUsesWith(GA.get());
GVal->eraseFromParent();
}
// Insert into the module, we know its name won't collide now.
if (IsAlias)
M->getAliasList().push_back(cast<GlobalAlias>(GA.get()));
else
M->getIFuncList().push_back(cast<GlobalIFunc>(GA.get()));
assert(GA->getName() == Name && "Should not be a name conflict!");
// The module owns this now
GA.release();
return false;
}
/// ParseGlobal
/// ::= GlobalVar '=' OptionalLinkage OptionalVisibility OptionalDLLStorageClass
/// OptionalThreadLocal OptionalUnnamedAddr OptionalAddrSpace
/// OptionalExternallyInitialized GlobalType Type Const
/// ::= OptionalLinkage OptionalVisibility OptionalDLLStorageClass
/// OptionalThreadLocal OptionalUnnamedAddr OptionalAddrSpace
/// OptionalExternallyInitialized GlobalType Type Const
///
/// Everything up to and including OptionalUnnamedAddr has been parsed
/// already.
///
bool LLParser::ParseGlobal(const std::string &Name, LocTy NameLoc,
unsigned Linkage, bool HasLinkage,
unsigned Visibility, unsigned DLLStorageClass,
GlobalVariable::ThreadLocalMode TLM,
GlobalVariable::UnnamedAddr UnnamedAddr) {
if (!isValidVisibilityForLinkage(Visibility, Linkage))
return Error(NameLoc,
"symbol with local linkage must have default visibility");
unsigned AddrSpace;
bool IsConstant, IsExternallyInitialized;
LocTy IsExternallyInitializedLoc;
LocTy TyLoc;
Type *Ty = nullptr;
if (ParseOptionalAddrSpace(AddrSpace) ||
ParseOptionalToken(lltok::kw_externally_initialized,
IsExternallyInitialized,
&IsExternallyInitializedLoc) ||
ParseGlobalType(IsConstant) ||
ParseType(Ty, TyLoc))
return true;
// If the linkage is specified and is external, then no initializer is
// present.
Constant *Init = nullptr;
if (!HasLinkage ||
!GlobalValue::isValidDeclarationLinkage(
(GlobalValue::LinkageTypes)Linkage)) {
if (ParseGlobalValue(Ty, Init))
return true;
}
if (Ty->isFunctionTy() || !PointerType::isValidElementType(Ty))
return Error(TyLoc, "invalid type for global variable");
GlobalValue *GVal = nullptr;
// See if the global was forward referenced, if so, use the global.
if (!Name.empty()) {
GVal = M->getNamedValue(Name);
if (GVal) {
if (!ForwardRefVals.erase(Name))
return Error(NameLoc, "redefinition of global '@" + Name + "'");
}
} else {
auto I = ForwardRefValIDs.find(NumberedVals.size());
if (I != ForwardRefValIDs.end()) {
GVal = I->second.first;
ForwardRefValIDs.erase(I);
}
}
GlobalVariable *GV;
if (!GVal) {
GV = new GlobalVariable(*M, Ty, false, GlobalValue::ExternalLinkage, nullptr,
Name, nullptr, GlobalVariable::NotThreadLocal,
AddrSpace);
} else {
if (GVal->getValueType() != Ty)
return Error(TyLoc,
"forward reference and definition of global have different types");
GV = cast<GlobalVariable>(GVal);
// Move the forward-reference to the correct spot in the module.
M->getGlobalList().splice(M->global_end(), M->getGlobalList(), GV);
}
if (Name.empty())
NumberedVals.push_back(GV);
// Set the parsed properties on the global.
if (Init)
GV->setInitializer(Init);
GV->setConstant(IsConstant);
GV->setLinkage((GlobalValue::LinkageTypes)Linkage);
GV->setVisibility((GlobalValue::VisibilityTypes)Visibility);
GV->setDLLStorageClass((GlobalValue::DLLStorageClassTypes)DLLStorageClass);
GV->setExternallyInitialized(IsExternallyInitialized);
GV->setThreadLocalMode(TLM);
GV->setUnnamedAddr(UnnamedAddr);
// Parse attributes on the global.
while (Lex.getKind() == lltok::comma) {
Lex.Lex();
if (Lex.getKind() == lltok::kw_section) {
Lex.Lex();
GV->setSection(Lex.getStrVal());
if (ParseToken(lltok::StringConstant, "expected global section string"))
return true;
} else if (Lex.getKind() == lltok::kw_align) {
unsigned Alignment;
if (ParseOptionalAlignment(Alignment)) return true;
GV->setAlignment(Alignment);
} else if (Lex.getKind() == lltok::MetadataVar) {
if (ParseGlobalObjectMetadataAttachment(*GV))
return true;
} else {
Comdat *C;
if (parseOptionalComdat(Name, C))
return true;
if (C)
GV->setComdat(C);
else
return TokError("unknown global variable property!");
}
}
return false;
}
/// ParseUnnamedAttrGrp
/// ::= 'attributes' AttrGrpID '=' '{' AttrValPair+ '}'
bool LLParser::ParseUnnamedAttrGrp() {
assert(Lex.getKind() == lltok::kw_attributes);
LocTy AttrGrpLoc = Lex.getLoc();
Lex.Lex();
if (Lex.getKind() != lltok::AttrGrpID)
return TokError("expected attribute group id");
unsigned VarID = Lex.getUIntVal();
std::vector<unsigned> unused;
LocTy BuiltinLoc;
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' here") ||
ParseToken(lltok::lbrace, "expected '{' here") ||
ParseFnAttributeValuePairs(NumberedAttrBuilders[VarID], unused, true,
BuiltinLoc) ||
ParseToken(lltok::rbrace, "expected end of attribute group"))
return true;
if (!NumberedAttrBuilders[VarID].hasAttributes())
return Error(AttrGrpLoc, "attribute group has no attributes");
return false;
}
/// ParseFnAttributeValuePairs
/// ::= <attr> | <attr> '=' <value>
bool LLParser::ParseFnAttributeValuePairs(AttrBuilder &B,
std::vector<unsigned> &FwdRefAttrGrps,
bool inAttrGrp, LocTy &BuiltinLoc) {
bool HaveError = false;
B.clear();
while (true) {
lltok::Kind Token = Lex.getKind();
if (Token == lltok::kw_builtin)
BuiltinLoc = Lex.getLoc();
switch (Token) {
default:
if (!inAttrGrp) return HaveError;
return Error(Lex.getLoc(), "unterminated attribute group");
case lltok::rbrace:
// Finished.
return false;
case lltok::AttrGrpID: {
// Allow a function to reference an attribute group:
//
// define void @foo() #1 { ... }
if (inAttrGrp)
HaveError |=
Error(Lex.getLoc(),
"cannot have an attribute group reference in an attribute group");
unsigned AttrGrpNum = Lex.getUIntVal();
if (inAttrGrp) break;
// Save the reference to the attribute group. We'll fill it in later.
FwdRefAttrGrps.push_back(AttrGrpNum);
break;
}
// Target-dependent attributes:
case lltok::StringConstant: {
if (ParseStringAttribute(B))
return true;
continue;
}
// Target-independent attributes:
case lltok::kw_align: {
// As a hack, we allow function alignment to be initially parsed as an
// attribute on a function declaration/definition or added to an attribute
// group and later moved to the alignment field.
unsigned Alignment;
if (inAttrGrp) {
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' here") ||
ParseUInt32(Alignment))
return true;
} else {
if (ParseOptionalAlignment(Alignment))
return true;
}
B.addAlignmentAttr(Alignment);
continue;
}
case lltok::kw_alignstack: {
unsigned Alignment;
if (inAttrGrp) {
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' here") ||
ParseUInt32(Alignment))
return true;
} else {
if (ParseOptionalStackAlignment(Alignment))
return true;
}
B.addStackAlignmentAttr(Alignment);
continue;
}
case lltok::kw_allocsize: {
unsigned ElemSizeArg;
Optional<unsigned> NumElemsArg;
// inAttrGrp doesn't matter; we only support allocsize(a[, b])
if (parseAllocSizeArguments(ElemSizeArg, NumElemsArg))
return true;
B.addAllocSizeAttr(ElemSizeArg, NumElemsArg);
continue;
}
case lltok::kw_alwaysinline: B.addAttribute(Attribute::AlwaysInline); break;
case lltok::kw_argmemonly: B.addAttribute(Attribute::ArgMemOnly); break;
case lltok::kw_builtin: B.addAttribute(Attribute::Builtin); break;
case lltok::kw_cold: B.addAttribute(Attribute::Cold); break;
case lltok::kw_convergent: B.addAttribute(Attribute::Convergent); break;
case lltok::kw_inaccessiblememonly:
B.addAttribute(Attribute::InaccessibleMemOnly); break;
case lltok::kw_inaccessiblemem_or_argmemonly:
B.addAttribute(Attribute::InaccessibleMemOrArgMemOnly); break;
case lltok::kw_inlinehint: B.addAttribute(Attribute::InlineHint); break;
case lltok::kw_jumptable: B.addAttribute(Attribute::JumpTable); break;
case lltok::kw_minsize: B.addAttribute(Attribute::MinSize); break;
case lltok::kw_naked: B.addAttribute(Attribute::Naked); break;
case lltok::kw_nobuiltin: B.addAttribute(Attribute::NoBuiltin); break;
case lltok::kw_noduplicate: B.addAttribute(Attribute::NoDuplicate); break;
case lltok::kw_noimplicitfloat:
B.addAttribute(Attribute::NoImplicitFloat); break;
case lltok::kw_noinline: B.addAttribute(Attribute::NoInline); break;
case lltok::kw_nonlazybind: B.addAttribute(Attribute::NonLazyBind); break;
case lltok::kw_noredzone: B.addAttribute(Attribute::NoRedZone); break;
case lltok::kw_noreturn: B.addAttribute(Attribute::NoReturn); break;
case lltok::kw_norecurse: B.addAttribute(Attribute::NoRecurse); break;
case lltok::kw_nounwind: B.addAttribute(Attribute::NoUnwind); break;
case lltok::kw_optnone: B.addAttribute(Attribute::OptimizeNone); break;
case lltok::kw_optsize: B.addAttribute(Attribute::OptimizeForSize); break;
case lltok::kw_readnone: B.addAttribute(Attribute::ReadNone); break;
case lltok::kw_readonly: B.addAttribute(Attribute::ReadOnly); break;
case lltok::kw_returns_twice:
B.addAttribute(Attribute::ReturnsTwice); break;
case lltok::kw_ssp: B.addAttribute(Attribute::StackProtect); break;
case lltok::kw_sspreq: B.addAttribute(Attribute::StackProtectReq); break;
case lltok::kw_sspstrong:
B.addAttribute(Attribute::StackProtectStrong); break;
case lltok::kw_safestack: B.addAttribute(Attribute::SafeStack); break;
case lltok::kw_sanitize_address:
B.addAttribute(Attribute::SanitizeAddress); break;
case lltok::kw_sanitize_thread:
B.addAttribute(Attribute::SanitizeThread); break;
case lltok::kw_sanitize_memory:
B.addAttribute(Attribute::SanitizeMemory); break;
case lltok::kw_uwtable: B.addAttribute(Attribute::UWTable); break;
case lltok::kw_writeonly: B.addAttribute(Attribute::WriteOnly); break;
// Error handling.
case lltok::kw_inreg:
case lltok::kw_signext:
case lltok::kw_zeroext:
HaveError |=
Error(Lex.getLoc(),
"invalid use of attribute on a function");
break;
case lltok::kw_byval:
case lltok::kw_dereferenceable:
case lltok::kw_dereferenceable_or_null:
case lltok::kw_inalloca:
case lltok::kw_nest:
case lltok::kw_noalias:
case lltok::kw_nocapture:
case lltok::kw_nonnull:
case lltok::kw_returned:
case lltok::kw_sret:
case lltok::kw_swifterror:
case lltok::kw_swiftself:
HaveError |=
Error(Lex.getLoc(),
"invalid use of parameter-only attribute on a function");
break;
}
Lex.Lex();
}
}
//===----------------------------------------------------------------------===//
// GlobalValue Reference/Resolution Routines.
//===----------------------------------------------------------------------===//
static inline GlobalValue *createGlobalFwdRef(Module *M, PointerType *PTy,
const std::string &Name) {
if (auto *FT = dyn_cast<FunctionType>(PTy->getElementType()))
return Function::Create(FT, GlobalValue::ExternalWeakLinkage, Name, M);
else
return new GlobalVariable(*M, PTy->getElementType(), false,
GlobalValue::ExternalWeakLinkage, nullptr, Name,
nullptr, GlobalVariable::NotThreadLocal,
PTy->getAddressSpace());
}
/// GetGlobalVal - Get a value with the specified name or ID, creating a
/// forward reference record if needed. This can return null if the value
/// exists but does not have the right type.
GlobalValue *LLParser::GetGlobalVal(const std::string &Name, Type *Ty,
LocTy Loc) {
PointerType *PTy = dyn_cast<PointerType>(Ty);
if (!PTy) {
Error(Loc, "global variable reference must have pointer type");
return nullptr;
}
// Look this name up in the normal function symbol table.
GlobalValue *Val =
cast_or_null<GlobalValue>(M->getValueSymbolTable().lookup(Name));
// If this is a forward reference for the value, see if we already created a
// forward ref record.
if (!Val) {
auto I = ForwardRefVals.find(Name);
if (I != ForwardRefVals.end())
Val = I->second.first;
}
// If we have the value in the symbol table or fwd-ref table, return it.
if (Val) {
if (Val->getType() == Ty) return Val;
Error(Loc, "'@" + Name + "' defined with type '" +
getTypeString(Val->getType()) + "'");
return nullptr;
}
// Otherwise, create a new forward reference for this value and remember it.
GlobalValue *FwdVal = createGlobalFwdRef(M, PTy, Name);
ForwardRefVals[Name] = std::make_pair(FwdVal, Loc);
return FwdVal;
}
GlobalValue *LLParser::GetGlobalVal(unsigned ID, Type *Ty, LocTy Loc) {
PointerType *PTy = dyn_cast<PointerType>(Ty);
if (!PTy) {
Error(Loc, "global variable reference must have pointer type");
return nullptr;
}
GlobalValue *Val = ID < NumberedVals.size() ? NumberedVals[ID] : nullptr;
// If this is a forward reference for the value, see if we already created a
// forward ref record.
if (!Val) {
auto I = ForwardRefValIDs.find(ID);
if (I != ForwardRefValIDs.end())
Val = I->second.first;
}
// If we have the value in the symbol table or fwd-ref table, return it.
if (Val) {
if (Val->getType() == Ty) return Val;
Error(Loc, "'@" + Twine(ID) + "' defined with type '" +
getTypeString(Val->getType()) + "'");
return nullptr;
}
// Otherwise, create a new forward reference for this value and remember it.
GlobalValue *FwdVal = createGlobalFwdRef(M, PTy, "");
ForwardRefValIDs[ID] = std::make_pair(FwdVal, Loc);
return FwdVal;
}
//===----------------------------------------------------------------------===//
// Comdat Reference/Resolution Routines.
//===----------------------------------------------------------------------===//
Comdat *LLParser::getComdat(const std::string &Name, LocTy Loc) {
// Look this name up in the comdat symbol table.
Module::ComdatSymTabType &ComdatSymTab = M->getComdatSymbolTable();
Module::ComdatSymTabType::iterator I = ComdatSymTab.find(Name);
if (I != ComdatSymTab.end())
return &I->second;
// Otherwise, create a new forward reference for this value and remember it.
Comdat *C = M->getOrInsertComdat(Name);
ForwardRefComdats[Name] = Loc;
return C;
}
//===----------------------------------------------------------------------===//
// Helper Routines.
//===----------------------------------------------------------------------===//
/// ParseToken - If the current token has the specified kind, eat it and return
/// success. Otherwise, emit the specified error and return failure.
bool LLParser::ParseToken(lltok::Kind T, const char *ErrMsg) {
if (Lex.getKind() != T)
return TokError(ErrMsg);
Lex.Lex();
return false;
}
/// ParseStringConstant
/// ::= StringConstant
bool LLParser::ParseStringConstant(std::string &Result) {
if (Lex.getKind() != lltok::StringConstant)
return TokError("expected string constant");
Result = Lex.getStrVal();
Lex.Lex();
return false;
}
/// ParseUInt32
/// ::= uint32
bool LLParser::ParseUInt32(uint32_t &Val) {
if (Lex.getKind() != lltok::APSInt || Lex.getAPSIntVal().isSigned())
return TokError("expected integer");
uint64_t Val64 = Lex.getAPSIntVal().getLimitedValue(0xFFFFFFFFULL+1);
if (Val64 != unsigned(Val64))
return TokError("expected 32-bit integer (too large)");
Val = Val64;
Lex.Lex();
return false;
}
/// ParseUInt64
/// ::= uint64
bool LLParser::ParseUInt64(uint64_t &Val) {
if (Lex.getKind() != lltok::APSInt || Lex.getAPSIntVal().isSigned())
return TokError("expected integer");
Val = Lex.getAPSIntVal().getLimitedValue();
Lex.Lex();
return false;
}
/// ParseTLSModel
/// := 'localdynamic'
/// := 'initialexec'
/// := 'localexec'
bool LLParser::ParseTLSModel(GlobalVariable::ThreadLocalMode &TLM) {
switch (Lex.getKind()) {
default:
return TokError("expected localdynamic, initialexec or localexec");
case lltok::kw_localdynamic:
TLM = GlobalVariable::LocalDynamicTLSModel;
break;
case lltok::kw_initialexec:
TLM = GlobalVariable::InitialExecTLSModel;
break;
case lltok::kw_localexec:
TLM = GlobalVariable::LocalExecTLSModel;
break;
}
Lex.Lex();
return false;
}
/// ParseOptionalThreadLocal
/// := /*empty*/
/// := 'thread_local'
/// := 'thread_local' '(' tlsmodel ')'
bool LLParser::ParseOptionalThreadLocal(GlobalVariable::ThreadLocalMode &TLM) {
TLM = GlobalVariable::NotThreadLocal;
if (!EatIfPresent(lltok::kw_thread_local))
return false;
TLM = GlobalVariable::GeneralDynamicTLSModel;
if (Lex.getKind() == lltok::lparen) {
Lex.Lex();
return ParseTLSModel(TLM) ||
ParseToken(lltok::rparen, "expected ')' after thread local model");
}
return false;
}
/// ParseOptionalAddrSpace
/// := /*empty*/
/// := 'addrspace' '(' uint32 ')'
bool LLParser::ParseOptionalAddrSpace(unsigned &AddrSpace) {
AddrSpace = 0;
if (!EatIfPresent(lltok::kw_addrspace))
return false;
return ParseToken(lltok::lparen, "expected '(' in address space") ||
ParseUInt32(AddrSpace) ||
ParseToken(lltok::rparen, "expected ')' in address space");
}
/// ParseStringAttribute
/// := StringConstant
/// := StringConstant '=' StringConstant
bool LLParser::ParseStringAttribute(AttrBuilder &B) {
std::string Attr = Lex.getStrVal();
Lex.Lex();
std::string Val;
if (EatIfPresent(lltok::equal) && ParseStringConstant(Val))
return true;
B.addAttribute(Attr, Val);
return false;
}
/// ParseOptionalParamAttrs - Parse a potentially empty list of parameter attributes.
bool LLParser::ParseOptionalParamAttrs(AttrBuilder &B) {
bool HaveError = false;
B.clear();
while (true) {
lltok::Kind Token = Lex.getKind();
switch (Token) {
default: // End of attributes.
return HaveError;
case lltok::StringConstant: {
if (ParseStringAttribute(B))
return true;
continue;
}
case lltok::kw_align: {
unsigned Alignment;
if (ParseOptionalAlignment(Alignment))
return true;
B.addAlignmentAttr(Alignment);
continue;
}
case lltok::kw_byval: B.addAttribute(Attribute::ByVal); break;
case lltok::kw_dereferenceable: {
uint64_t Bytes;
if (ParseOptionalDerefAttrBytes(lltok::kw_dereferenceable, Bytes))
return true;
B.addDereferenceableAttr(Bytes);
continue;
}
case lltok::kw_dereferenceable_or_null: {
uint64_t Bytes;
if (ParseOptionalDerefAttrBytes(lltok::kw_dereferenceable_or_null, Bytes))
return true;
B.addDereferenceableOrNullAttr(Bytes);
continue;
}
case lltok::kw_inalloca: B.addAttribute(Attribute::InAlloca); break;
case lltok::kw_inreg: B.addAttribute(Attribute::InReg); break;
case lltok::kw_nest: B.addAttribute(Attribute::Nest); break;
case lltok::kw_noalias: B.addAttribute(Attribute::NoAlias); break;
case lltok::kw_nocapture: B.addAttribute(Attribute::NoCapture); break;
case lltok::kw_nonnull: B.addAttribute(Attribute::NonNull); break;
case lltok::kw_readnone: B.addAttribute(Attribute::ReadNone); break;
case lltok::kw_readonly: B.addAttribute(Attribute::ReadOnly); break;
case lltok::kw_returned: B.addAttribute(Attribute::Returned); break;
case lltok::kw_signext: B.addAttribute(Attribute::SExt); break;
case lltok::kw_sret: B.addAttribute(Attribute::StructRet); break;
case lltok::kw_swifterror: B.addAttribute(Attribute::SwiftError); break;
case lltok::kw_swiftself: B.addAttribute(Attribute::SwiftSelf); break;
case lltok::kw_writeonly: B.addAttribute(Attribute::WriteOnly); break;
case lltok::kw_zeroext: B.addAttribute(Attribute::ZExt); break;
case lltok::kw_alignstack:
case lltok::kw_alwaysinline:
case lltok::kw_argmemonly:
case lltok::kw_builtin:
case lltok::kw_inlinehint:
case lltok::kw_jumptable:
case lltok::kw_minsize:
case lltok::kw_naked:
case lltok::kw_nobuiltin:
case lltok::kw_noduplicate:
case lltok::kw_noimplicitfloat:
case lltok::kw_noinline:
case lltok::kw_nonlazybind:
case lltok::kw_noredzone:
case lltok::kw_noreturn:
case lltok::kw_nounwind:
case lltok::kw_optnone:
case lltok::kw_optsize:
case lltok::kw_returns_twice:
case lltok::kw_sanitize_address:
case lltok::kw_sanitize_memory:
case lltok::kw_sanitize_thread:
case lltok::kw_ssp:
case lltok::kw_sspreq:
case lltok::kw_sspstrong:
case lltok::kw_safestack:
case lltok::kw_uwtable:
HaveError |= Error(Lex.getLoc(), "invalid use of function-only attribute");
break;
}
Lex.Lex();
}
}
/// ParseOptionalReturnAttrs - Parse a potentially empty list of return attributes.
bool LLParser::ParseOptionalReturnAttrs(AttrBuilder &B) {
bool HaveError = false;
B.clear();
while (true) {
lltok::Kind Token = Lex.getKind();
switch (Token) {
default: // End of attributes.
return HaveError;
case lltok::StringConstant: {
if (ParseStringAttribute(B))
return true;
continue;
}
case lltok::kw_dereferenceable: {
uint64_t Bytes;
if (ParseOptionalDerefAttrBytes(lltok::kw_dereferenceable, Bytes))
return true;
B.addDereferenceableAttr(Bytes);
continue;
}
case lltok::kw_dereferenceable_or_null: {
uint64_t Bytes;
if (ParseOptionalDerefAttrBytes(lltok::kw_dereferenceable_or_null, Bytes))
return true;
B.addDereferenceableOrNullAttr(Bytes);
continue;
}
case lltok::kw_align: {
unsigned Alignment;
if (ParseOptionalAlignment(Alignment))
return true;
B.addAlignmentAttr(Alignment);
continue;
}
case lltok::kw_inreg: B.addAttribute(Attribute::InReg); break;
case lltok::kw_noalias: B.addAttribute(Attribute::NoAlias); break;
case lltok::kw_nonnull: B.addAttribute(Attribute::NonNull); break;
case lltok::kw_signext: B.addAttribute(Attribute::SExt); break;
case lltok::kw_zeroext: B.addAttribute(Attribute::ZExt); break;
// Error handling.
case lltok::kw_byval:
case lltok::kw_inalloca:
case lltok::kw_nest:
case lltok::kw_nocapture:
case lltok::kw_returned:
case lltok::kw_sret:
case lltok::kw_swifterror:
case lltok::kw_swiftself:
HaveError |= Error(Lex.getLoc(), "invalid use of parameter-only attribute");
break;
case lltok::kw_alignstack:
case lltok::kw_alwaysinline:
case lltok::kw_argmemonly:
case lltok::kw_builtin:
case lltok::kw_cold:
case lltok::kw_inlinehint:
case lltok::kw_jumptable:
case lltok::kw_minsize:
case lltok::kw_naked:
case lltok::kw_nobuiltin:
case lltok::kw_noduplicate:
case lltok::kw_noimplicitfloat:
case lltok::kw_noinline:
case lltok::kw_nonlazybind:
case lltok::kw_noredzone:
case lltok::kw_noreturn:
case lltok::kw_nounwind:
case lltok::kw_optnone:
case lltok::kw_optsize:
case lltok::kw_returns_twice:
case lltok::kw_sanitize_address:
case lltok::kw_sanitize_memory:
case lltok::kw_sanitize_thread:
case lltok::kw_ssp:
case lltok::kw_sspreq:
case lltok::kw_sspstrong:
case lltok::kw_safestack:
case lltok::kw_uwtable:
HaveError |= Error(Lex.getLoc(), "invalid use of function-only attribute");
break;
case lltok::kw_readnone:
case lltok::kw_readonly:
HaveError |= Error(Lex.getLoc(), "invalid use of attribute on return type");
}
Lex.Lex();
}
}
static unsigned parseOptionalLinkageAux(lltok::Kind Kind, bool &HasLinkage) {
HasLinkage = true;
switch (Kind) {
default:
HasLinkage = false;
return GlobalValue::ExternalLinkage;
case lltok::kw_private:
return GlobalValue::PrivateLinkage;
case lltok::kw_internal:
return GlobalValue::InternalLinkage;
case lltok::kw_weak:
return GlobalValue::WeakAnyLinkage;
case lltok::kw_weak_odr:
return GlobalValue::WeakODRLinkage;
case lltok::kw_linkonce:
return GlobalValue::LinkOnceAnyLinkage;
case lltok::kw_linkonce_odr:
return GlobalValue::LinkOnceODRLinkage;
case lltok::kw_available_externally:
return GlobalValue::AvailableExternallyLinkage;
case lltok::kw_appending:
return GlobalValue::AppendingLinkage;
case lltok::kw_common:
return GlobalValue::CommonLinkage;
case lltok::kw_extern_weak:
return GlobalValue::ExternalWeakLinkage;
case lltok::kw_external:
return GlobalValue::ExternalLinkage;
}
}
/// ParseOptionalLinkage
/// ::= /*empty*/
/// ::= 'private'
/// ::= 'internal'
/// ::= 'weak'
/// ::= 'weak_odr'
/// ::= 'linkonce'
/// ::= 'linkonce_odr'
/// ::= 'available_externally'
/// ::= 'appending'
/// ::= 'common'
/// ::= 'extern_weak'
/// ::= 'external'
bool LLParser::ParseOptionalLinkage(unsigned &Res, bool &HasLinkage,
unsigned &Visibility,
unsigned &DLLStorageClass) {
Res = parseOptionalLinkageAux(Lex.getKind(), HasLinkage);
if (HasLinkage)
Lex.Lex();
ParseOptionalVisibility(Visibility);
ParseOptionalDLLStorageClass(DLLStorageClass);
return false;
}
/// ParseOptionalVisibility
/// ::= /*empty*/
/// ::= 'default'
/// ::= 'hidden'
/// ::= 'protected'
///
void LLParser::ParseOptionalVisibility(unsigned &Res) {
switch (Lex.getKind()) {
default:
Res = GlobalValue::DefaultVisibility;
return;
case lltok::kw_default:
Res = GlobalValue::DefaultVisibility;
break;
case lltok::kw_hidden:
Res = GlobalValue::HiddenVisibility;
break;
case lltok::kw_protected:
Res = GlobalValue::ProtectedVisibility;
break;
}
Lex.Lex();
}
/// ParseOptionalDLLStorageClass
/// ::= /*empty*/
/// ::= 'dllimport'
/// ::= 'dllexport'
///
void LLParser::ParseOptionalDLLStorageClass(unsigned &Res) {
switch (Lex.getKind()) {
default:
Res = GlobalValue::DefaultStorageClass;
return;
case lltok::kw_dllimport:
Res = GlobalValue::DLLImportStorageClass;
break;
case lltok::kw_dllexport:
Res = GlobalValue::DLLExportStorageClass;
break;
}
Lex.Lex();
}
/// ParseOptionalCallingConv
/// ::= /*empty*/
/// ::= 'ccc'
/// ::= 'fastcc'
/// ::= 'intel_ocl_bicc'
/// ::= 'coldcc'
/// ::= 'x86_stdcallcc'
/// ::= 'x86_fastcallcc'
/// ::= 'x86_thiscallcc'
/// ::= 'x86_vectorcallcc'
/// ::= 'arm_apcscc'
/// ::= 'arm_aapcscc'
/// ::= 'arm_aapcs_vfpcc'
/// ::= 'msp430_intrcc'
/// ::= 'avr_intrcc'
/// ::= 'avr_signalcc'
/// ::= 'ptx_kernel'
/// ::= 'ptx_device'
/// ::= 'spir_func'
/// ::= 'spir_kernel'
/// ::= 'x86_64_sysvcc'
/// ::= 'x86_64_win64cc'
/// ::= 'webkit_jscc'
/// ::= 'anyregcc'
/// ::= 'preserve_mostcc'
/// ::= 'preserve_allcc'
/// ::= 'ghccc'
/// ::= 'swiftcc'
/// ::= 'x86_intrcc'
/// ::= 'hhvmcc'
/// ::= 'hhvm_ccc'
/// ::= 'cxx_fast_tlscc'
/// ::= 'amdgpu_vs'
/// ::= 'amdgpu_tcs'
/// ::= 'amdgpu_tes'
/// ::= 'amdgpu_gs'
/// ::= 'amdgpu_ps'
/// ::= 'amdgpu_cs'
/// ::= 'amdgpu_kernel'
/// ::= 'cc' UINT
///
bool LLParser::ParseOptionalCallingConv(unsigned &CC) {
switch (Lex.getKind()) {
default: CC = CallingConv::C; return false;
case lltok::kw_ccc: CC = CallingConv::C; break;
case lltok::kw_fastcc: CC = CallingConv::Fast; break;
case lltok::kw_coldcc: CC = CallingConv::Cold; break;
case lltok::kw_x86_stdcallcc: CC = CallingConv::X86_StdCall; break;
case lltok::kw_x86_fastcallcc: CC = CallingConv::X86_FastCall; break;
case lltok::kw_x86_regcallcc: CC = CallingConv::X86_RegCall; break;
case lltok::kw_x86_thiscallcc: CC = CallingConv::X86_ThisCall; break;
case lltok::kw_x86_vectorcallcc:CC = CallingConv::X86_VectorCall; break;
case lltok::kw_arm_apcscc: CC = CallingConv::ARM_APCS; break;
case lltok::kw_arm_aapcscc: CC = CallingConv::ARM_AAPCS; break;
case lltok::kw_arm_aapcs_vfpcc:CC = CallingConv::ARM_AAPCS_VFP; break;
case lltok::kw_msp430_intrcc: CC = CallingConv::MSP430_INTR; break;
case lltok::kw_avr_intrcc: CC = CallingConv::AVR_INTR; break;
case lltok::kw_avr_signalcc: CC = CallingConv::AVR_SIGNAL; break;
case lltok::kw_ptx_kernel: CC = CallingConv::PTX_Kernel; break;
case lltok::kw_ptx_device: CC = CallingConv::PTX_Device; break;
case lltok::kw_spir_kernel: CC = CallingConv::SPIR_KERNEL; break;
case lltok::kw_spir_func: CC = CallingConv::SPIR_FUNC; break;
case lltok::kw_intel_ocl_bicc: CC = CallingConv::Intel_OCL_BI; break;
case lltok::kw_x86_64_sysvcc: CC = CallingConv::X86_64_SysV; break;
case lltok::kw_x86_64_win64cc: CC = CallingConv::X86_64_Win64; break;
case lltok::kw_webkit_jscc: CC = CallingConv::WebKit_JS; break;
case lltok::kw_anyregcc: CC = CallingConv::AnyReg; break;
case lltok::kw_preserve_mostcc:CC = CallingConv::PreserveMost; break;
case lltok::kw_preserve_allcc: CC = CallingConv::PreserveAll; break;
case lltok::kw_ghccc: CC = CallingConv::GHC; break;
case lltok::kw_swiftcc: CC = CallingConv::Swift; break;
case lltok::kw_x86_intrcc: CC = CallingConv::X86_INTR; break;
case lltok::kw_hhvmcc: CC = CallingConv::HHVM; break;
case lltok::kw_hhvm_ccc: CC = CallingConv::HHVM_C; break;
case lltok::kw_cxx_fast_tlscc: CC = CallingConv::CXX_FAST_TLS; break;
case lltok::kw_amdgpu_vs: CC = CallingConv::AMDGPU_VS; break;
case lltok::kw_amdgpu_gs: CC = CallingConv::AMDGPU_GS; break;
case lltok::kw_amdgpu_ps: CC = CallingConv::AMDGPU_PS; break;
case lltok::kw_amdgpu_cs: CC = CallingConv::AMDGPU_CS; break;
case lltok::kw_amdgpu_kernel: CC = CallingConv::AMDGPU_KERNEL; break;
case lltok::kw_cc: {
Lex.Lex();
return ParseUInt32(CC);
}
}
Lex.Lex();
return false;
}
/// ParseMetadataAttachment
/// ::= !dbg !42
bool LLParser::ParseMetadataAttachment(unsigned &Kind, MDNode *&MD) {
assert(Lex.getKind() == lltok::MetadataVar && "Expected metadata attachment");
std::string Name = Lex.getStrVal();
Kind = M->getMDKindID(Name);
Lex.Lex();
return ParseMDNode(MD);
}
/// ParseInstructionMetadata
/// ::= !dbg !42 (',' !dbg !57)*
bool LLParser::ParseInstructionMetadata(Instruction &Inst) {
do {
if (Lex.getKind() != lltok::MetadataVar)
return TokError("expected metadata after comma");
unsigned MDK;
MDNode *N;
if (ParseMetadataAttachment(MDK, N))
return true;
Inst.setMetadata(MDK, N);
if (MDK == LLVMContext::MD_tbaa)
InstsWithTBAATag.push_back(&Inst);
// If this is the end of the list, we're done.
} while (EatIfPresent(lltok::comma));
return false;
}
/// ParseGlobalObjectMetadataAttachment
/// ::= !dbg !57
bool LLParser::ParseGlobalObjectMetadataAttachment(GlobalObject &GO) {
unsigned MDK;
MDNode *N;
if (ParseMetadataAttachment(MDK, N))
return true;
GO.addMetadata(MDK, *N);
return false;
}
/// ParseOptionalFunctionMetadata
/// ::= (!dbg !57)*
bool LLParser::ParseOptionalFunctionMetadata(Function &F) {
while (Lex.getKind() == lltok::MetadataVar)
if (ParseGlobalObjectMetadataAttachment(F))
return true;
return false;
}
/// ParseOptionalAlignment
/// ::= /* empty */
/// ::= 'align' 4
bool LLParser::ParseOptionalAlignment(unsigned &Alignment) {
Alignment = 0;
if (!EatIfPresent(lltok::kw_align))
return false;
LocTy AlignLoc = Lex.getLoc();
if (ParseUInt32(Alignment)) return true;
if (!isPowerOf2_32(Alignment))
return Error(AlignLoc, "alignment is not a power of two");
if (Alignment > Value::MaximumAlignment)
return Error(AlignLoc, "huge alignments are not supported yet");
return false;
}
/// ParseOptionalDerefAttrBytes
/// ::= /* empty */
/// ::= AttrKind '(' 4 ')'
///
/// where AttrKind is either 'dereferenceable' or 'dereferenceable_or_null'.
bool LLParser::ParseOptionalDerefAttrBytes(lltok::Kind AttrKind,
uint64_t &Bytes) {
assert((AttrKind == lltok::kw_dereferenceable ||
AttrKind == lltok::kw_dereferenceable_or_null) &&
"contract!");
Bytes = 0;
if (!EatIfPresent(AttrKind))
return false;
LocTy ParenLoc = Lex.getLoc();
if (!EatIfPresent(lltok::lparen))
return Error(ParenLoc, "expected '('");
LocTy DerefLoc = Lex.getLoc();
if (ParseUInt64(Bytes)) return true;
ParenLoc = Lex.getLoc();
if (!EatIfPresent(lltok::rparen))
return Error(ParenLoc, "expected ')'");
if (!Bytes)
return Error(DerefLoc, "dereferenceable bytes must be non-zero");
return false;
}
/// ParseOptionalCommaAlign
/// ::=
/// ::= ',' align 4
///
/// This returns with AteExtraComma set to true if it ate an excess comma at the
/// end.
bool LLParser::ParseOptionalCommaAlign(unsigned &Alignment,
bool &AteExtraComma) {
AteExtraComma = false;
while (EatIfPresent(lltok::comma)) {
// Metadata at the end is an early exit.
if (Lex.getKind() == lltok::MetadataVar) {
AteExtraComma = true;
return false;
}
if (Lex.getKind() != lltok::kw_align)
return Error(Lex.getLoc(), "expected metadata or 'align'");
if (ParseOptionalAlignment(Alignment)) return true;
}
return false;
}
bool LLParser::parseAllocSizeArguments(unsigned &BaseSizeArg,
Optional<unsigned> &HowManyArg) {
Lex.Lex();
auto StartParen = Lex.getLoc();
if (!EatIfPresent(lltok::lparen))
return Error(StartParen, "expected '('");
if (ParseUInt32(BaseSizeArg))
return true;
if (EatIfPresent(lltok::comma)) {
auto HowManyAt = Lex.getLoc();
unsigned HowMany;
if (ParseUInt32(HowMany))
return true;
if (HowMany == BaseSizeArg)
return Error(HowManyAt,
"'allocsize' indices can't refer to the same parameter");
HowManyArg = HowMany;
} else
HowManyArg = None;
auto EndParen = Lex.getLoc();
if (!EatIfPresent(lltok::rparen))
return Error(EndParen, "expected ')'");
return false;
}
/// ParseScopeAndOrdering
/// if isAtomic: ::= 'singlethread'? AtomicOrdering
/// else: ::=
///
/// This sets Scope and Ordering to the parsed values.
bool LLParser::ParseScopeAndOrdering(bool isAtomic, SynchronizationScope &Scope,
AtomicOrdering &Ordering) {
if (!isAtomic)
return false;
Scope = CrossThread;
if (EatIfPresent(lltok::kw_singlethread))
Scope = SingleThread;
return ParseOrdering(Ordering);
}
/// ParseOrdering
/// ::= AtomicOrdering
///
/// This sets Ordering to the parsed value.
bool LLParser::ParseOrdering(AtomicOrdering &Ordering) {
switch (Lex.getKind()) {
default: return TokError("Expected ordering on atomic instruction");
case lltok::kw_unordered: Ordering = AtomicOrdering::Unordered; break;
case lltok::kw_monotonic: Ordering = AtomicOrdering::Monotonic; break;
// Not specified yet:
// case lltok::kw_consume: Ordering = AtomicOrdering::Consume; break;
case lltok::kw_acquire: Ordering = AtomicOrdering::Acquire; break;
case lltok::kw_release: Ordering = AtomicOrdering::Release; break;
case lltok::kw_acq_rel: Ordering = AtomicOrdering::AcquireRelease; break;
case lltok::kw_seq_cst:
Ordering = AtomicOrdering::SequentiallyConsistent;
break;
}
Lex.Lex();
return false;
}
/// ParseOptionalStackAlignment
/// ::= /* empty */
/// ::= 'alignstack' '(' 4 ')'
bool LLParser::ParseOptionalStackAlignment(unsigned &Alignment) {
Alignment = 0;
if (!EatIfPresent(lltok::kw_alignstack))
return false;
LocTy ParenLoc = Lex.getLoc();
if (!EatIfPresent(lltok::lparen))
return Error(ParenLoc, "expected '('");
LocTy AlignLoc = Lex.getLoc();
if (ParseUInt32(Alignment)) return true;
ParenLoc = Lex.getLoc();
if (!EatIfPresent(lltok::rparen))
return Error(ParenLoc, "expected ')'");
if (!isPowerOf2_32(Alignment))
return Error(AlignLoc, "stack alignment is not a power of two");
return false;
}
/// ParseIndexList - This parses the index list for an insert/extractvalue
/// instruction. This sets AteExtraComma in the case where we eat an extra
/// comma at the end of the line and find that it is followed by metadata.
/// Clients that don't allow metadata can call the version of this function that
/// only takes one argument.
///
/// ParseIndexList
/// ::= (',' uint32)+
///
bool LLParser::ParseIndexList(SmallVectorImpl<unsigned> &Indices,
bool &AteExtraComma) {
AteExtraComma = false;
if (Lex.getKind() != lltok::comma)
return TokError("expected ',' as start of index list");
while (EatIfPresent(lltok::comma)) {
if (Lex.getKind() == lltok::MetadataVar) {
if (Indices.empty()) return TokError("expected index");
AteExtraComma = true;
return false;
}
unsigned Idx = 0;
if (ParseUInt32(Idx)) return true;
Indices.push_back(Idx);
}
return false;
}
//===----------------------------------------------------------------------===//
// Type Parsing.
//===----------------------------------------------------------------------===//
/// ParseType - Parse a type.
bool LLParser::ParseType(Type *&Result, const Twine &Msg, bool AllowVoid) {
SMLoc TypeLoc = Lex.getLoc();
switch (Lex.getKind()) {
default:
return TokError(Msg);
case lltok::Type:
// Type ::= 'float' | 'void' (etc)
Result = Lex.getTyVal();
Lex.Lex();
break;
case lltok::lbrace:
// Type ::= StructType
if (ParseAnonStructType(Result, false))
return true;
break;
case lltok::lsquare:
// Type ::= '[' ... ']'
Lex.Lex(); // eat the lsquare.
if (ParseArrayVectorType(Result, false))
return true;
break;
case lltok::less: // Either vector or packed struct.
// Type ::= '<' ... '>'
Lex.Lex();
if (Lex.getKind() == lltok::lbrace) {
if (ParseAnonStructType(Result, true) ||
ParseToken(lltok::greater, "expected '>' at end of packed struct"))
return true;
} else if (ParseArrayVectorType(Result, true))
return true;
break;
case lltok::LocalVar: {
// Type ::= %foo
std::pair<Type*, LocTy> &Entry = NamedTypes[Lex.getStrVal()];
// If the type hasn't been defined yet, create a forward definition and
// remember where that forward def'n was seen (in case it never is defined).
if (!Entry.first) {
Entry.first = StructType::create(Context, Lex.getStrVal());
Entry.second = Lex.getLoc();
}
Result = Entry.first;
Lex.Lex();
break;
}
case lltok::LocalVarID: {
// Type ::= %4
std::pair<Type*, LocTy> &Entry = NumberedTypes[Lex.getUIntVal()];
// If the type hasn't been defined yet, create a forward definition and
// remember where that forward def'n was seen (in case it never is defined).
if (!Entry.first) {
Entry.first = StructType::create(Context);
Entry.second = Lex.getLoc();
}
Result = Entry.first;
Lex.Lex();
break;
}
}
// Parse the type suffixes.
while (true) {
switch (Lex.getKind()) {
// End of type.
default:
if (!AllowVoid && Result->isVoidTy())
return Error(TypeLoc, "void type only allowed for function results");
return false;
// Type ::= Type '*'
case lltok::star:
if (Result->isLabelTy())
return TokError("basic block pointers are invalid");
if (Result->isVoidTy())
return TokError("pointers to void are invalid - use i8* instead");
if (!PointerType::isValidElementType(Result))
return TokError("pointer to this type is invalid");
Result = PointerType::getUnqual(Result);
Lex.Lex();
break;
// Type ::= Type 'addrspace' '(' uint32 ')' '*'
case lltok::kw_addrspace: {
if (Result->isLabelTy())
return TokError("basic block pointers are invalid");
if (Result->isVoidTy())
return TokError("pointers to void are invalid; use i8* instead");
if (!PointerType::isValidElementType(Result))
return TokError("pointer to this type is invalid");
unsigned AddrSpace;
if (ParseOptionalAddrSpace(AddrSpace) ||
ParseToken(lltok::star, "expected '*' in address space"))
return true;
Result = PointerType::get(Result, AddrSpace);
break;
}
/// Types '(' ArgTypeListI ')' OptFuncAttrs
case lltok::lparen:
if (ParseFunctionType(Result))
return true;
break;
}
}
}
/// ParseParameterList
/// ::= '(' ')'
/// ::= '(' Arg (',' Arg)* ')'
/// Arg
/// ::= Type OptionalAttributes Value OptionalAttributes
bool LLParser::ParseParameterList(SmallVectorImpl<ParamInfo> &ArgList,
PerFunctionState &PFS, bool IsMustTailCall,
bool InVarArgsFunc) {
if (ParseToken(lltok::lparen, "expected '(' in call"))
return true;
unsigned AttrIndex = 1;
while (Lex.getKind() != lltok::rparen) {
// If this isn't the first argument, we need a comma.
if (!ArgList.empty() &&
ParseToken(lltok::comma, "expected ',' in argument list"))
return true;
// Parse an ellipsis if this is a musttail call in a variadic function.
if (Lex.getKind() == lltok::dotdotdot) {
const char *Msg = "unexpected ellipsis in argument list for ";
if (!IsMustTailCall)
return TokError(Twine(Msg) + "non-musttail call");
if (!InVarArgsFunc)
return TokError(Twine(Msg) + "musttail call in non-varargs function");
Lex.Lex(); // Lex the '...', it is purely for readability.
return ParseToken(lltok::rparen, "expected ')' at end of argument list");
}
// Parse the argument.
LocTy ArgLoc;
Type *ArgTy = nullptr;
AttrBuilder ArgAttrs;
Value *V;
if (ParseType(ArgTy, ArgLoc))
return true;
if (ArgTy->isMetadataTy()) {
if (ParseMetadataAsValue(V, PFS))
return true;
} else {
// Otherwise, handle normal operands.
if (ParseOptionalParamAttrs(ArgAttrs) || ParseValue(ArgTy, V, PFS))
return true;
}
ArgList.push_back(ParamInfo(ArgLoc, V, AttributeSet::get(V->getContext(),
AttrIndex++,
ArgAttrs)));
}
if (IsMustTailCall && InVarArgsFunc)
return TokError("expected '...' at end of argument list for musttail call "
"in varargs function");
Lex.Lex(); // Lex the ')'.
return false;
}
/// ParseOptionalOperandBundles
/// ::= /*empty*/
/// ::= '[' OperandBundle [, OperandBundle ]* ']'
///
/// OperandBundle
/// ::= bundle-tag '(' ')'
/// ::= bundle-tag '(' Type Value [, Type Value ]* ')'
///
/// bundle-tag ::= String Constant
bool LLParser::ParseOptionalOperandBundles(
SmallVectorImpl<OperandBundleDef> &BundleList, PerFunctionState &PFS) {
LocTy BeginLoc = Lex.getLoc();
if (!EatIfPresent(lltok::lsquare))
return false;
while (Lex.getKind() != lltok::rsquare) {
// If this isn't the first operand bundle, we need a comma.
if (!BundleList.empty() &&
ParseToken(lltok::comma, "expected ',' in input list"))
return true;
std::string Tag;
if (ParseStringConstant(Tag))
return true;
if (ParseToken(lltok::lparen, "expected '(' in operand bundle"))
return true;
std::vector<Value *> Inputs;
while (Lex.getKind() != lltok::rparen) {
// If this isn't the first input, we need a comma.
if (!Inputs.empty() &&
ParseToken(lltok::comma, "expected ',' in input list"))
return true;
Type *Ty = nullptr;
Value *Input = nullptr;
if (ParseType(Ty) || ParseValue(Ty, Input, PFS))
return true;
Inputs.push_back(Input);
}
BundleList.emplace_back(std::move(Tag), std::move(Inputs));
Lex.Lex(); // Lex the ')'.
}
if (BundleList.empty())
return Error(BeginLoc, "operand bundle set must not be empty");
Lex.Lex(); // Lex the ']'.
return false;
}
/// ParseArgumentList - Parse the argument list for a function type or function
/// prototype.
/// ::= '(' ArgTypeListI ')'
/// ArgTypeListI
/// ::= /*empty*/
/// ::= '...'
/// ::= ArgTypeList ',' '...'
/// ::= ArgType (',' ArgType)*
///
bool LLParser::ParseArgumentList(SmallVectorImpl<ArgInfo> &ArgList,
bool &isVarArg){
isVarArg = false;
assert(Lex.getKind() == lltok::lparen);
Lex.Lex(); // eat the (.
if (Lex.getKind() == lltok::rparen) {
// empty
} else if (Lex.getKind() == lltok::dotdotdot) {
isVarArg = true;
Lex.Lex();
} else {
LocTy TypeLoc = Lex.getLoc();
Type *ArgTy = nullptr;
AttrBuilder Attrs;
std::string Name;
if (ParseType(ArgTy) ||
ParseOptionalParamAttrs(Attrs)) return true;
if (ArgTy->isVoidTy())
return Error(TypeLoc, "argument can not have void type");
if (Lex.getKind() == lltok::LocalVar) {
Name = Lex.getStrVal();
Lex.Lex();
}
if (!FunctionType::isValidArgumentType(ArgTy))
return Error(TypeLoc, "invalid type for function argument");
unsigned AttrIndex = 1;
ArgList.emplace_back(TypeLoc, ArgTy, AttributeSet::get(ArgTy->getContext(),
AttrIndex++, Attrs),
std::move(Name));
while (EatIfPresent(lltok::comma)) {
// Handle ... at end of arg list.
if (EatIfPresent(lltok::dotdotdot)) {
isVarArg = true;
break;
}
// Otherwise must be an argument type.
TypeLoc = Lex.getLoc();
if (ParseType(ArgTy) || ParseOptionalParamAttrs(Attrs)) return true;
if (ArgTy->isVoidTy())
return Error(TypeLoc, "argument can not have void type");
if (Lex.getKind() == lltok::LocalVar) {
Name = Lex.getStrVal();
Lex.Lex();
} else {
Name = "";
}
if (!ArgTy->isFirstClassType())
return Error(TypeLoc, "invalid type for function argument");
ArgList.emplace_back(
TypeLoc, ArgTy,
AttributeSet::get(ArgTy->getContext(), AttrIndex++, Attrs),
std::move(Name));
}
}
return ParseToken(lltok::rparen, "expected ')' at end of argument list");
}
/// ParseFunctionType
/// ::= Type ArgumentList OptionalAttrs
bool LLParser::ParseFunctionType(Type *&Result) {
assert(Lex.getKind() == lltok::lparen);
if (!FunctionType::isValidReturnType(Result))
return TokError("invalid function return type");
SmallVector<ArgInfo, 8> ArgList;
bool isVarArg;
if (ParseArgumentList(ArgList, isVarArg))
return true;
// Reject names on the arguments lists.
for (unsigned i = 0, e = ArgList.size(); i != e; ++i) {
if (!ArgList[i].Name.empty())
return Error(ArgList[i].Loc, "argument name invalid in function type");
if (ArgList[i].Attrs.hasAttributes(i + 1))
return Error(ArgList[i].Loc,
"argument attributes invalid in function type");
}
SmallVector<Type*, 16> ArgListTy;
for (unsigned i = 0, e = ArgList.size(); i != e; ++i)
ArgListTy.push_back(ArgList[i].Ty);
Result = FunctionType::get(Result, ArgListTy, isVarArg);
return false;
}
/// ParseAnonStructType - Parse an anonymous struct type, which is inlined into
/// other structs.
bool LLParser::ParseAnonStructType(Type *&Result, bool Packed) {
SmallVector<Type*, 8> Elts;
if (ParseStructBody(Elts)) return true;
Result = StructType::get(Context, Elts, Packed);
return false;
}
/// ParseStructDefinition - Parse a struct in a 'type' definition.
bool LLParser::ParseStructDefinition(SMLoc TypeLoc, StringRef Name,
std::pair<Type*, LocTy> &Entry,
Type *&ResultTy) {
// If the type was already defined, diagnose the redefinition.
if (Entry.first && !Entry.second.isValid())
return Error(TypeLoc, "redefinition of type");
// If we have opaque, just return without filling in the definition for the
// struct. This counts as a definition as far as the .ll file goes.
if (EatIfPresent(lltok::kw_opaque)) {
// This type is being defined, so clear the location to indicate this.
Entry.second = SMLoc();
// If this type number has never been uttered, create it.
if (!Entry.first)
Entry.first = StructType::create(Context, Name);
ResultTy = Entry.first;
return false;
}
// If the type starts with '<', then it is either a packed struct or a vector.
bool isPacked = EatIfPresent(lltok::less);
// If we don't have a struct, then we have a random type alias, which we
// accept for compatibility with old files. These types are not allowed to be
// forward referenced and not allowed to be recursive.
if (Lex.getKind() != lltok::lbrace) {
if (Entry.first)
return Error(TypeLoc, "forward references to non-struct type");
ResultTy = nullptr;
if (isPacked)
return ParseArrayVectorType(ResultTy, true);
return ParseType(ResultTy);
}
// This type is being defined, so clear the location to indicate this.
Entry.second = SMLoc();
// If this type number has never been uttered, create it.
if (!Entry.first)
Entry.first = StructType::create(Context, Name);
StructType *STy = cast<StructType>(Entry.first);
SmallVector<Type*, 8> Body;
if (ParseStructBody(Body) ||
(isPacked && ParseToken(lltok::greater, "expected '>' in packed struct")))
return true;
STy->setBody(Body, isPacked);
ResultTy = STy;
return false;
}
/// ParseStructType: Handles packed and unpacked types. </> parsed elsewhere.
/// StructType
/// ::= '{' '}'
/// ::= '{' Type (',' Type)* '}'
/// ::= '<' '{' '}' '>'
/// ::= '<' '{' Type (',' Type)* '}' '>'
bool LLParser::ParseStructBody(SmallVectorImpl<Type*> &Body) {
assert(Lex.getKind() == lltok::lbrace);
Lex.Lex(); // Consume the '{'
// Handle the empty struct.
if (EatIfPresent(lltok::rbrace))
return false;
LocTy EltTyLoc = Lex.getLoc();
Type *Ty = nullptr;
if (ParseType(Ty)) return true;
Body.push_back(Ty);
if (!StructType::isValidElementType(Ty))
return Error(EltTyLoc, "invalid element type for struct");
while (EatIfPresent(lltok::comma)) {
EltTyLoc = Lex.getLoc();
if (ParseType(Ty)) return true;
if (!StructType::isValidElementType(Ty))
return Error(EltTyLoc, "invalid element type for struct");
Body.push_back(Ty);
}
return ParseToken(lltok::rbrace, "expected '}' at end of struct");
}
/// ParseArrayVectorType - Parse an array or vector type, assuming the first
/// token has already been consumed.
/// Type
/// ::= '[' APSINTVAL 'x' Types ']'
/// ::= '<' APSINTVAL 'x' Types '>'
bool LLParser::ParseArrayVectorType(Type *&Result, bool isVector) {
if (Lex.getKind() != lltok::APSInt || Lex.getAPSIntVal().isSigned() ||
Lex.getAPSIntVal().getBitWidth() > 64)
return TokError("expected number in address space");
LocTy SizeLoc = Lex.getLoc();
uint64_t Size = Lex.getAPSIntVal().getZExtValue();
Lex.Lex();
if (ParseToken(lltok::kw_x, "expected 'x' after element count"))
return true;
LocTy TypeLoc = Lex.getLoc();
Type *EltTy = nullptr;
if (ParseType(EltTy)) return true;
if (ParseToken(isVector ? lltok::greater : lltok::rsquare,
"expected end of sequential type"))
return true;
if (isVector) {
if (Size == 0)
return Error(SizeLoc, "zero element vector is illegal");
if ((unsigned)Size != Size)
return Error(SizeLoc, "size too large for vector");
if (!VectorType::isValidElementType(EltTy))
return Error(TypeLoc, "invalid vector element type");
Result = VectorType::get(EltTy, unsigned(Size));
} else {
if (!ArrayType::isValidElementType(EltTy))
return Error(TypeLoc, "invalid array element type");
Result = ArrayType::get(EltTy, Size);
}
return false;
}
//===----------------------------------------------------------------------===//
// Function Semantic Analysis.
//===----------------------------------------------------------------------===//
LLParser::PerFunctionState::PerFunctionState(LLParser &p, Function &f,
int functionNumber)
: P(p), F(f), FunctionNumber(functionNumber) {
// Insert unnamed arguments into the NumberedVals list.
for (Argument &A : F.args())
if (!A.hasName())
NumberedVals.push_back(&A);
}
LLParser::PerFunctionState::~PerFunctionState() {
// If there were any forward referenced non-basicblock values, delete them.
for (const auto &P : ForwardRefVals) {
if (isa<BasicBlock>(P.second.first))
continue;
P.second.first->replaceAllUsesWith(
UndefValue::get(P.second.first->getType()));
delete P.second.first;
}
for (const auto &P : ForwardRefValIDs) {
if (isa<BasicBlock>(P.second.first))
continue;
P.second.first->replaceAllUsesWith(
UndefValue::get(P.second.first->getType()));
delete P.second.first;
}
}
bool LLParser::PerFunctionState::FinishFunction() {
if (!ForwardRefVals.empty())
return P.Error(ForwardRefVals.begin()->second.second,
"use of undefined value '%" + ForwardRefVals.begin()->first +
"'");
if (!ForwardRefValIDs.empty())
return P.Error(ForwardRefValIDs.begin()->second.second,
"use of undefined value '%" +
Twine(ForwardRefValIDs.begin()->first) + "'");
return false;
}
/// GetVal - Get a value with the specified name or ID, creating a
/// forward reference record if needed. This can return null if the value
/// exists but does not have the right type.
Value *LLParser::PerFunctionState::GetVal(const std::string &Name, Type *Ty,
LocTy Loc) {
// Look this name up in the normal function symbol table.
Value *Val = F.getValueSymbolTable()->lookup(Name);
// If this is a forward reference for the value, see if we already created a
// forward ref record.
if (!Val) {
auto I = ForwardRefVals.find(Name);
if (I != ForwardRefVals.end())
Val = I->second.first;
}
// If we have the value in the symbol table or fwd-ref table, return it.
if (Val) {
if (Val->getType() == Ty) return Val;
if (Ty->isLabelTy())
P.Error(Loc, "'%" + Name + "' is not a basic block");
else
P.Error(Loc, "'%" + Name + "' defined with type '" +
getTypeString(Val->getType()) + "'");
return nullptr;
}
// Don't make placeholders with invalid type.
if (!Ty->isFirstClassType()) {
P.Error(Loc, "invalid use of a non-first-class type");
return nullptr;
}
// Otherwise, create a new forward reference for this value and remember it.
Value *FwdVal;
if (Ty->isLabelTy()) {
FwdVal = BasicBlock::Create(F.getContext(), Name, &F);
} else {
FwdVal = new Argument(Ty, Name);
}
ForwardRefVals[Name] = std::make_pair(FwdVal, Loc);
return FwdVal;
}
Value *LLParser::PerFunctionState::GetVal(unsigned ID, Type *Ty, LocTy Loc) {
// Look this name up in the normal function symbol table.
Value *Val = ID < NumberedVals.size() ? NumberedVals[ID] : nullptr;
// If this is a forward reference for the value, see if we already created a
// forward ref record.
if (!Val) {
auto I = ForwardRefValIDs.find(ID);
if (I != ForwardRefValIDs.end())
Val = I->second.first;
}
// If we have the value in the symbol table or fwd-ref table, return it.
if (Val) {
if (Val->getType() == Ty) return Val;
if (Ty->isLabelTy())
P.Error(Loc, "'%" + Twine(ID) + "' is not a basic block");
else
P.Error(Loc, "'%" + Twine(ID) + "' defined with type '" +
getTypeString(Val->getType()) + "'");
return nullptr;
}
if (!Ty->isFirstClassType()) {
P.Error(Loc, "invalid use of a non-first-class type");
return nullptr;
}
// Otherwise, create a new forward reference for this value and remember it.
Value *FwdVal;
if (Ty->isLabelTy()) {
FwdVal = BasicBlock::Create(F.getContext(), "", &F);
} else {
FwdVal = new Argument(Ty);
}
ForwardRefValIDs[ID] = std::make_pair(FwdVal, Loc);
return FwdVal;
}
/// SetInstName - After an instruction is parsed and inserted into its
/// basic block, this installs its name.
bool LLParser::PerFunctionState::SetInstName(int NameID,
const std::string &NameStr,
LocTy NameLoc, Instruction *Inst) {
// If this instruction has void type, it cannot have a name or ID specified.
if (Inst->getType()->isVoidTy()) {
if (NameID != -1 || !NameStr.empty())
return P.Error(NameLoc, "instructions returning void cannot have a name");
return false;
}
// If this was a numbered instruction, verify that the instruction is the
// expected value and resolve any forward references.
if (NameStr.empty()) {
// If neither a name nor an ID was specified, just use the next ID.
if (NameID == -1)
NameID = NumberedVals.size();
if (unsigned(NameID) != NumberedVals.size())
return P.Error(NameLoc, "instruction expected to be numbered '%" +
Twine(NumberedVals.size()) + "'");
auto FI = ForwardRefValIDs.find(NameID);
if (FI != ForwardRefValIDs.end()) {
Value *Sentinel = FI->second.first;
if (Sentinel->getType() != Inst->getType())
return P.Error(NameLoc, "instruction forward referenced with type '" +
getTypeString(FI->second.first->getType()) + "'");
Sentinel->replaceAllUsesWith(Inst);
delete Sentinel;
ForwardRefValIDs.erase(FI);
}
NumberedVals.push_back(Inst);
return false;
}
// Otherwise, the instruction had a name. Resolve forward refs and set it.
auto FI = ForwardRefVals.find(NameStr);
if (FI != ForwardRefVals.end()) {
Value *Sentinel = FI->second.first;
if (Sentinel->getType() != Inst->getType())
return P.Error(NameLoc, "instruction forward referenced with type '" +
getTypeString(FI->second.first->getType()) + "'");
Sentinel->replaceAllUsesWith(Inst);
delete Sentinel;
ForwardRefVals.erase(FI);
}
// Set the name on the instruction.
Inst->setName(NameStr);
if (Inst->getName() != NameStr)
return P.Error(NameLoc, "multiple definition of local value named '" +
NameStr + "'");
return false;
}
/// GetBB - Get a basic block with the specified name or ID, creating a
/// forward reference record if needed.
BasicBlock *LLParser::PerFunctionState::GetBB(const std::string &Name,
LocTy Loc) {
return dyn_cast_or_null<BasicBlock>(GetVal(Name,
Type::getLabelTy(F.getContext()), Loc));
}
BasicBlock *LLParser::PerFunctionState::GetBB(unsigned ID, LocTy Loc) {
return dyn_cast_or_null<BasicBlock>(GetVal(ID,
Type::getLabelTy(F.getContext()), Loc));
}
/// DefineBB - Define the specified basic block, which is either named or
/// unnamed. If there is an error, this returns null otherwise it returns
/// the block being defined.
BasicBlock *LLParser::PerFunctionState::DefineBB(const std::string &Name,
LocTy Loc) {
BasicBlock *BB;
if (Name.empty())
BB = GetBB(NumberedVals.size(), Loc);
else
BB = GetBB(Name, Loc);
if (!BB) return nullptr; // Already diagnosed error.
// Move the block to the end of the function. Forward ref'd blocks are
// inserted wherever they happen to be referenced.
F.getBasicBlockList().splice(F.end(), F.getBasicBlockList(), BB);
// Remove the block from forward ref sets.
if (Name.empty()) {
ForwardRefValIDs.erase(NumberedVals.size());
NumberedVals.push_back(BB);
} else {
// BB forward references are already in the function symbol table.
ForwardRefVals.erase(Name);
}
return BB;
}
//===----------------------------------------------------------------------===//
// Constants.
//===----------------------------------------------------------------------===//
/// ParseValID - Parse an abstract value that doesn't necessarily have a
/// type implied. For example, if we parse "4" we don't know what integer type
/// it has. The value will later be combined with its type and checked for
/// sanity. PFS is used to convert function-local operands of metadata (since
/// metadata operands are not just parsed here but also converted to values).
/// PFS can be null when we are not parsing metadata values inside a function.
bool LLParser::ParseValID(ValID &ID, PerFunctionState *PFS) {
ID.Loc = Lex.getLoc();
switch (Lex.getKind()) {
default: return TokError("expected value token");
case lltok::GlobalID: // @42
ID.UIntVal = Lex.getUIntVal();
ID.Kind = ValID::t_GlobalID;
break;
case lltok::GlobalVar: // @foo
ID.StrVal = Lex.getStrVal();
ID.Kind = ValID::t_GlobalName;
break;
case lltok::LocalVarID: // %42
ID.UIntVal = Lex.getUIntVal();
ID.Kind = ValID::t_LocalID;
break;
case lltok::LocalVar: // %foo
ID.StrVal = Lex.getStrVal();
ID.Kind = ValID::t_LocalName;
break;
case lltok::APSInt:
ID.APSIntVal = Lex.getAPSIntVal();
ID.Kind = ValID::t_APSInt;
break;
case lltok::APFloat:
ID.APFloatVal = Lex.getAPFloatVal();
ID.Kind = ValID::t_APFloat;
break;
case lltok::kw_true:
ID.ConstantVal = ConstantInt::getTrue(Context);
ID.Kind = ValID::t_Constant;
break;
case lltok::kw_false:
ID.ConstantVal = ConstantInt::getFalse(Context);
ID.Kind = ValID::t_Constant;
break;
case lltok::kw_null: ID.Kind = ValID::t_Null; break;
case lltok::kw_undef: ID.Kind = ValID::t_Undef; break;
case lltok::kw_zeroinitializer: ID.Kind = ValID::t_Zero; break;
case lltok::kw_none: ID.Kind = ValID::t_None; break;
case lltok::lbrace: {
// ValID ::= '{' ConstVector '}'
Lex.Lex();
SmallVector<Constant*, 16> Elts;
if (ParseGlobalValueVector(Elts) ||
ParseToken(lltok::rbrace, "expected end of struct constant"))
return true;
ID.ConstantStructElts = make_unique<Constant *[]>(Elts.size());
ID.UIntVal = Elts.size();
memcpy(ID.ConstantStructElts.get(), Elts.data(),
Elts.size() * sizeof(Elts[0]));
ID.Kind = ValID::t_ConstantStruct;
return false;
}
case lltok::less: {
// ValID ::= '<' ConstVector '>' --> Vector.
// ValID ::= '<' '{' ConstVector '}' '>' --> Packed Struct.
Lex.Lex();
bool isPackedStruct = EatIfPresent(lltok::lbrace);
SmallVector<Constant*, 16> Elts;
LocTy FirstEltLoc = Lex.getLoc();
if (ParseGlobalValueVector(Elts) ||
(isPackedStruct &&
ParseToken(lltok::rbrace, "expected end of packed struct")) ||
ParseToken(lltok::greater, "expected end of constant"))
return true;
if (isPackedStruct) {
ID.ConstantStructElts = make_unique<Constant *[]>(Elts.size());
memcpy(ID.ConstantStructElts.get(), Elts.data(),
Elts.size() * sizeof(Elts[0]));
ID.UIntVal = Elts.size();
ID.Kind = ValID::t_PackedConstantStruct;
return false;
}
if (Elts.empty())
return Error(ID.Loc, "constant vector must not be empty");
if (!Elts[0]->getType()->isIntegerTy() &&
!Elts[0]->getType()->isFloatingPointTy() &&
!Elts[0]->getType()->isPointerTy())
return Error(FirstEltLoc,
"vector elements must have integer, pointer or floating point type");
// Verify that all the vector elements have the same type.
for (unsigned i = 1, e = Elts.size(); i != e; ++i)
if (Elts[i]->getType() != Elts[0]->getType())
return Error(FirstEltLoc,
"vector element #" + Twine(i) +
" is not of type '" + getTypeString(Elts[0]->getType()));
ID.ConstantVal = ConstantVector::get(Elts);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::lsquare: { // Array Constant
Lex.Lex();
SmallVector<Constant*, 16> Elts;
LocTy FirstEltLoc = Lex.getLoc();
if (ParseGlobalValueVector(Elts) ||
ParseToken(lltok::rsquare, "expected end of array constant"))
return true;
// Handle empty element.
if (Elts.empty()) {
// Use undef instead of an array because it's inconvenient to determine
// the element type at this point, there being no elements to examine.
ID.Kind = ValID::t_EmptyArray;
return false;
}
if (!Elts[0]->getType()->isFirstClassType())
return Error(FirstEltLoc, "invalid array element type: " +
getTypeString(Elts[0]->getType()));
ArrayType *ATy = ArrayType::get(Elts[0]->getType(), Elts.size());
// Verify all elements are correct type!
for (unsigned i = 0, e = Elts.size(); i != e; ++i) {
if (Elts[i]->getType() != Elts[0]->getType())
return Error(FirstEltLoc,
"array element #" + Twine(i) +
" is not of type '" + getTypeString(Elts[0]->getType()));
}
ID.ConstantVal = ConstantArray::get(ATy, Elts);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_c: // c "foo"
Lex.Lex();
ID.ConstantVal = ConstantDataArray::getString(Context, Lex.getStrVal(),
false);
if (ParseToken(lltok::StringConstant, "expected string")) return true;
ID.Kind = ValID::t_Constant;
return false;
case lltok::kw_asm: {
// ValID ::= 'asm' SideEffect? AlignStack? IntelDialect? STRINGCONSTANT ','
// STRINGCONSTANT
bool HasSideEffect, AlignStack, AsmDialect;
Lex.Lex();
if (ParseOptionalToken(lltok::kw_sideeffect, HasSideEffect) ||
ParseOptionalToken(lltok::kw_alignstack, AlignStack) ||
ParseOptionalToken(lltok::kw_inteldialect, AsmDialect) ||
ParseStringConstant(ID.StrVal) ||
ParseToken(lltok::comma, "expected comma in inline asm expression") ||
ParseToken(lltok::StringConstant, "expected constraint string"))
return true;
ID.StrVal2 = Lex.getStrVal();
ID.UIntVal = unsigned(HasSideEffect) | (unsigned(AlignStack)<<1) |
(unsigned(AsmDialect)<<2);
ID.Kind = ValID::t_InlineAsm;
return false;
}
case lltok::kw_blockaddress: {
// ValID ::= 'blockaddress' '(' @foo ',' %bar ')'
Lex.Lex();
ValID Fn, Label;
if (ParseToken(lltok::lparen, "expected '(' in block address expression") ||
ParseValID(Fn) ||
ParseToken(lltok::comma, "expected comma in block address expression")||
ParseValID(Label) ||
ParseToken(lltok::rparen, "expected ')' in block address expression"))
return true;
if (Fn.Kind != ValID::t_GlobalID && Fn.Kind != ValID::t_GlobalName)
return Error(Fn.Loc, "expected function name in blockaddress");
if (Label.Kind != ValID::t_LocalID && Label.Kind != ValID::t_LocalName)
return Error(Label.Loc, "expected basic block name in blockaddress");
// Try to find the function (but skip it if it's forward-referenced).
GlobalValue *GV = nullptr;
if (Fn.Kind == ValID::t_GlobalID) {
if (Fn.UIntVal < NumberedVals.size())
GV = NumberedVals[Fn.UIntVal];
} else if (!ForwardRefVals.count(Fn.StrVal)) {
GV = M->getNamedValue(Fn.StrVal);
}
Function *F = nullptr;
if (GV) {
// Confirm that it's actually a function with a definition.
if (!isa<Function>(GV))
return Error(Fn.Loc, "expected function name in blockaddress");
F = cast<Function>(GV);
if (F->isDeclaration())
return Error(Fn.Loc, "cannot take blockaddress inside a declaration");
}
if (!F) {
// Make a global variable as a placeholder for this reference.
GlobalValue *&FwdRef =
ForwardRefBlockAddresses.insert(std::make_pair(
std::move(Fn),
std::map<ValID, GlobalValue *>()))
.first->second.insert(std::make_pair(std::move(Label), nullptr))
.first->second;
if (!FwdRef)
FwdRef = new GlobalVariable(*M, Type::getInt8Ty(Context), false,
GlobalValue::InternalLinkage, nullptr, "");
ID.ConstantVal = FwdRef;
ID.Kind = ValID::t_Constant;
return false;
}
// We found the function; now find the basic block. Don't use PFS, since we
// might be inside a constant expression.
BasicBlock *BB;
if (BlockAddressPFS && F == &BlockAddressPFS->getFunction()) {
if (Label.Kind == ValID::t_LocalID)
BB = BlockAddressPFS->GetBB(Label.UIntVal, Label.Loc);
else
BB = BlockAddressPFS->GetBB(Label.StrVal, Label.Loc);
if (!BB)
return Error(Label.Loc, "referenced value is not a basic block");
} else {
if (Label.Kind == ValID::t_LocalID)
return Error(Label.Loc, "cannot take address of numeric label after "
"the function is defined");
BB = dyn_cast_or_null<BasicBlock>(
F->getValueSymbolTable()->lookup(Label.StrVal));
if (!BB)
return Error(Label.Loc, "referenced value is not a basic block");
}
ID.ConstantVal = BlockAddress::get(F, BB);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_trunc:
case lltok::kw_zext:
case lltok::kw_sext:
case lltok::kw_fptrunc:
case lltok::kw_fpext:
case lltok::kw_bitcast:
case lltok::kw_addrspacecast:
case lltok::kw_uitofp:
case lltok::kw_sitofp:
case lltok::kw_fptoui:
case lltok::kw_fptosi:
case lltok::kw_inttoptr:
case lltok::kw_ptrtoint: {
unsigned Opc = Lex.getUIntVal();
Type *DestTy = nullptr;
Constant *SrcVal;
Lex.Lex();
if (ParseToken(lltok::lparen, "expected '(' after constantexpr cast") ||
ParseGlobalTypeAndValue(SrcVal) ||
ParseToken(lltok::kw_to, "expected 'to' in constantexpr cast") ||
ParseType(DestTy) ||
ParseToken(lltok::rparen, "expected ')' at end of constantexpr cast"))
return true;
if (!CastInst::castIsValid((Instruction::CastOps)Opc, SrcVal, DestTy))
return Error(ID.Loc, "invalid cast opcode for cast from '" +
getTypeString(SrcVal->getType()) + "' to '" +
getTypeString(DestTy) + "'");
ID.ConstantVal = ConstantExpr::getCast((Instruction::CastOps)Opc,
SrcVal, DestTy);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_extractvalue: {
Lex.Lex();
Constant *Val;
SmallVector<unsigned, 4> Indices;
if (ParseToken(lltok::lparen, "expected '(' in extractvalue constantexpr")||
ParseGlobalTypeAndValue(Val) ||
ParseIndexList(Indices) ||
ParseToken(lltok::rparen, "expected ')' in extractvalue constantexpr"))
return true;
if (!Val->getType()->isAggregateType())
return Error(ID.Loc, "extractvalue operand must be aggregate type");
if (!ExtractValueInst::getIndexedType(Val->getType(), Indices))
return Error(ID.Loc, "invalid indices for extractvalue");
ID.ConstantVal = ConstantExpr::getExtractValue(Val, Indices);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_insertvalue: {
Lex.Lex();
Constant *Val0, *Val1;
SmallVector<unsigned, 4> Indices;
if (ParseToken(lltok::lparen, "expected '(' in insertvalue constantexpr")||
ParseGlobalTypeAndValue(Val0) ||
ParseToken(lltok::comma, "expected comma in insertvalue constantexpr")||
ParseGlobalTypeAndValue(Val1) ||
ParseIndexList(Indices) ||
ParseToken(lltok::rparen, "expected ')' in insertvalue constantexpr"))
return true;
if (!Val0->getType()->isAggregateType())
return Error(ID.Loc, "insertvalue operand must be aggregate type");
Type *IndexedType =
ExtractValueInst::getIndexedType(Val0->getType(), Indices);
if (!IndexedType)
return Error(ID.Loc, "invalid indices for insertvalue");
if (IndexedType != Val1->getType())
return Error(ID.Loc, "insertvalue operand and field disagree in type: '" +
getTypeString(Val1->getType()) +
"' instead of '" + getTypeString(IndexedType) +
"'");
ID.ConstantVal = ConstantExpr::getInsertValue(Val0, Val1, Indices);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_icmp:
case lltok::kw_fcmp: {
unsigned PredVal, Opc = Lex.getUIntVal();
Constant *Val0, *Val1;
Lex.Lex();
if (ParseCmpPredicate(PredVal, Opc) ||
ParseToken(lltok::lparen, "expected '(' in compare constantexpr") ||
ParseGlobalTypeAndValue(Val0) ||
ParseToken(lltok::comma, "expected comma in compare constantexpr") ||
ParseGlobalTypeAndValue(Val1) ||
ParseToken(lltok::rparen, "expected ')' in compare constantexpr"))
return true;
if (Val0->getType() != Val1->getType())
return Error(ID.Loc, "compare operands must have the same type");
CmpInst::Predicate Pred = (CmpInst::Predicate)PredVal;
if (Opc == Instruction::FCmp) {
if (!Val0->getType()->isFPOrFPVectorTy())
return Error(ID.Loc, "fcmp requires floating point operands");
ID.ConstantVal = ConstantExpr::getFCmp(Pred, Val0, Val1);
} else {
assert(Opc == Instruction::ICmp && "Unexpected opcode for CmpInst!");
if (!Val0->getType()->isIntOrIntVectorTy() &&
!Val0->getType()->getScalarType()->isPointerTy())
return Error(ID.Loc, "icmp requires pointer or integer operands");
ID.ConstantVal = ConstantExpr::getICmp(Pred, Val0, Val1);
}
ID.Kind = ValID::t_Constant;
return false;
}
// Binary Operators.
case lltok::kw_add:
case lltok::kw_fadd:
case lltok::kw_sub:
case lltok::kw_fsub:
case lltok::kw_mul:
case lltok::kw_fmul:
case lltok::kw_udiv:
case lltok::kw_sdiv:
case lltok::kw_fdiv:
case lltok::kw_urem:
case lltok::kw_srem:
case lltok::kw_frem:
case lltok::kw_shl:
case lltok::kw_lshr:
case lltok::kw_ashr: {
bool NUW = false;
bool NSW = false;
bool Exact = false;
unsigned Opc = Lex.getUIntVal();
Constant *Val0, *Val1;
Lex.Lex();
LocTy ModifierLoc = Lex.getLoc();
if (Opc == Instruction::Add || Opc == Instruction::Sub ||
Opc == Instruction::Mul || Opc == Instruction::Shl) {
if (EatIfPresent(lltok::kw_nuw))
NUW = true;
if (EatIfPresent(lltok::kw_nsw)) {
NSW = true;
if (EatIfPresent(lltok::kw_nuw))
NUW = true;
}
} else if (Opc == Instruction::SDiv || Opc == Instruction::UDiv ||
Opc == Instruction::LShr || Opc == Instruction::AShr) {
if (EatIfPresent(lltok::kw_exact))
Exact = true;
}
if (ParseToken(lltok::lparen, "expected '(' in binary constantexpr") ||
ParseGlobalTypeAndValue(Val0) ||
ParseToken(lltok::comma, "expected comma in binary constantexpr") ||
ParseGlobalTypeAndValue(Val1) ||
ParseToken(lltok::rparen, "expected ')' in binary constantexpr"))
return true;
if (Val0->getType() != Val1->getType())
return Error(ID.Loc, "operands of constexpr must have same type");
if (!Val0->getType()->isIntOrIntVectorTy()) {
if (NUW)
return Error(ModifierLoc, "nuw only applies to integer operations");
if (NSW)
return Error(ModifierLoc, "nsw only applies to integer operations");
}
// Check that the type is valid for the operator.
switch (Opc) {
case Instruction::Add:
case Instruction::Sub:
case Instruction::Mul:
case Instruction::UDiv:
case Instruction::SDiv:
case Instruction::URem:
case Instruction::SRem:
case Instruction::Shl:
case Instruction::AShr:
case Instruction::LShr:
if (!Val0->getType()->isIntOrIntVectorTy())
return Error(ID.Loc, "constexpr requires integer operands");
break;
case Instruction::FAdd:
case Instruction::FSub:
case Instruction::FMul:
case Instruction::FDiv:
case Instruction::FRem:
if (!Val0->getType()->isFPOrFPVectorTy())
return Error(ID.Loc, "constexpr requires fp operands");
break;
default: llvm_unreachable("Unknown binary operator!");
}
unsigned Flags = 0;
if (NUW) Flags |= OverflowingBinaryOperator::NoUnsignedWrap;
if (NSW) Flags |= OverflowingBinaryOperator::NoSignedWrap;
if (Exact) Flags |= PossiblyExactOperator::IsExact;
Constant *C = ConstantExpr::get(Opc, Val0, Val1, Flags);
ID.ConstantVal = C;
ID.Kind = ValID::t_Constant;
return false;
}
// Logical Operations
case lltok::kw_and:
case lltok::kw_or:
case lltok::kw_xor: {
unsigned Opc = Lex.getUIntVal();
Constant *Val0, *Val1;
Lex.Lex();
if (ParseToken(lltok::lparen, "expected '(' in logical constantexpr") ||
ParseGlobalTypeAndValue(Val0) ||
ParseToken(lltok::comma, "expected comma in logical constantexpr") ||
ParseGlobalTypeAndValue(Val1) ||
ParseToken(lltok::rparen, "expected ')' in logical constantexpr"))
return true;
if (Val0->getType() != Val1->getType())
return Error(ID.Loc, "operands of constexpr must have same type");
if (!Val0->getType()->isIntOrIntVectorTy())
return Error(ID.Loc,
"constexpr requires integer or integer vector operands");
ID.ConstantVal = ConstantExpr::get(Opc, Val0, Val1);
ID.Kind = ValID::t_Constant;
return false;
}
case lltok::kw_getelementptr:
case lltok::kw_shufflevector:
case lltok::kw_insertelement:
case lltok::kw_extractelement:
case lltok::kw_select: {
unsigned Opc = Lex.getUIntVal();
SmallVector<Constant*, 16> Elts;
bool InBounds = false;
Type *Ty;
Lex.Lex();
if (Opc == Instruction::GetElementPtr)
InBounds = EatIfPresent(lltok::kw_inbounds);
if (ParseToken(lltok::lparen, "expected '(' in constantexpr"))
return true;
LocTy ExplicitTypeLoc = Lex.getLoc();
if (Opc == Instruction::GetElementPtr) {
if (ParseType(Ty) ||
ParseToken(lltok::comma, "expected comma after getelementptr's type"))
return true;
}
Optional<unsigned> InRangeOp;
if (ParseGlobalValueVector(
Elts, Opc == Instruction::GetElementPtr ? &InRangeOp : nullptr) ||
ParseToken(lltok::rparen, "expected ')' in constantexpr"))
return true;
if (Opc == Instruction::GetElementPtr) {
if (Elts.size() == 0 ||
!Elts[0]->getType()->getScalarType()->isPointerTy())
return Error(ID.Loc, "base of getelementptr must be a pointer");
Type *BaseType = Elts[0]->getType();
auto *BasePointerType = cast<PointerType>(BaseType->getScalarType());
if (Ty != BasePointerType->getElementType())
return Error(
ExplicitTypeLoc,
"explicit pointee type doesn't match operand's pointee type");
unsigned GEPWidth =
BaseType->isVectorTy() ? BaseType->getVectorNumElements() : 0;
ArrayRef<Constant *> Indices(Elts.begin() + 1, Elts.end());
for (Constant *Val : Indices) {
Type *ValTy = Val->getType();
if (!ValTy->getScalarType()->isIntegerTy())
return Error(ID.Loc, "getelementptr index must be an integer");
if (ValTy->isVectorTy()) {
unsigned ValNumEl = ValTy->getVectorNumElements();
if (GEPWidth && (ValNumEl != GEPWidth))
return Error(
ID.Loc,
"getelementptr vector index has a wrong number of elements");
// GEPWidth may have been unknown because the base is a scalar,
// but it is known now.
GEPWidth = ValNumEl;
}
}
SmallPtrSet<Type*, 4> Visited;
if (!Indices.empty() && !Ty->isSized(&Visited))
return Error(ID.Loc, "base element of getelementptr must be sized");
if (!GetElementPtrInst::getIndexedType(Ty, Indices))
return Error(ID.Loc, "invalid getelementptr indices");
if (InRangeOp) {
if (*InRangeOp == 0)
return Error(ID.Loc,
"inrange keyword may not appear on pointer operand");
--*InRangeOp;
}
ID.ConstantVal = ConstantExpr::getGetElementPtr(Ty, Elts[0], Indices,
InBounds, InRangeOp);
} else if (Opc == Instruction::Select) {
if (Elts.size() != 3)
return Error(ID.Loc, "expected three operands to select");
if (const char *Reason = SelectInst::areInvalidOperands(Elts[0], Elts[1],
Elts[2]))
return Error(ID.Loc, Reason);
ID.ConstantVal = ConstantExpr::getSelect(Elts[0], Elts[1], Elts[2]);
} else if (Opc == Instruction::ShuffleVector) {
if (Elts.size() != 3)
return Error(ID.Loc, "expected three operands to shufflevector");
if (!ShuffleVectorInst::isValidOperands(Elts[0], Elts[1], Elts[2]))
return Error(ID.Loc, "invalid operands to shufflevector");
ID.ConstantVal =
ConstantExpr::getShuffleVector(Elts[0], Elts[1],Elts[2]);
} else if (Opc == Instruction::ExtractElement) {
if (Elts.size() != 2)
return Error(ID.Loc, "expected two operands to extractelement");
if (!ExtractElementInst::isValidOperands(Elts[0], Elts[1]))
return Error(ID.Loc, "invalid extractelement operands");
ID.ConstantVal = ConstantExpr::getExtractElement(Elts[0], Elts[1]);
} else {
assert(Opc == Instruction::InsertElement && "Unknown opcode");
if (Elts.size() != 3)
return Error(ID.Loc, "expected three operands to insertelement");
if (!InsertElementInst::isValidOperands(Elts[0], Elts[1], Elts[2]))
return Error(ID.Loc, "invalid insertelement operands");
ID.ConstantVal =
ConstantExpr::getInsertElement(Elts[0], Elts[1],Elts[2]);
}
ID.Kind = ValID::t_Constant;
return false;
}
}
Lex.Lex();
return false;
}
/// ParseGlobalValue - Parse a global value with the specified type.
bool LLParser::ParseGlobalValue(Type *Ty, Constant *&C) {
C = nullptr;
ValID ID;
Value *V = nullptr;
bool Parsed = ParseValID(ID) ||
ConvertValIDToValue(Ty, ID, V, nullptr);
if (V && !(C = dyn_cast<Constant>(V)))
return Error(ID.Loc, "global values must be constants");
return Parsed;
}
bool LLParser::ParseGlobalTypeAndValue(Constant *&V) {
Type *Ty = nullptr;
return ParseType(Ty) ||
ParseGlobalValue(Ty, V);
}
bool LLParser::parseOptionalComdat(StringRef GlobalName, Comdat *&C) {
C = nullptr;
LocTy KwLoc = Lex.getLoc();
if (!EatIfPresent(lltok::kw_comdat))
return false;
if (EatIfPresent(lltok::lparen)) {
if (Lex.getKind() != lltok::ComdatVar)
return TokError("expected comdat variable");
C = getComdat(Lex.getStrVal(), Lex.getLoc());
Lex.Lex();
if (ParseToken(lltok::rparen, "expected ')' after comdat var"))
return true;
} else {
if (GlobalName.empty())
return TokError("comdat cannot be unnamed");
C = getComdat(GlobalName, KwLoc);
}
return false;
}
/// ParseGlobalValueVector
/// ::= /*empty*/
/// ::= [inrange] TypeAndValue (',' [inrange] TypeAndValue)*
bool LLParser::ParseGlobalValueVector(SmallVectorImpl<Constant *> &Elts,
Optional<unsigned> *InRangeOp) {
// Empty list.
if (Lex.getKind() == lltok::rbrace ||
Lex.getKind() == lltok::rsquare ||
Lex.getKind() == lltok::greater ||
Lex.getKind() == lltok::rparen)
return false;
do {
if (InRangeOp && !*InRangeOp && EatIfPresent(lltok::kw_inrange))
*InRangeOp = Elts.size();
Constant *C;
if (ParseGlobalTypeAndValue(C)) return true;
Elts.push_back(C);
} while (EatIfPresent(lltok::comma));
return false;
}
bool LLParser::ParseMDTuple(MDNode *&MD, bool IsDistinct) {
SmallVector<Metadata *, 16> Elts;
if (ParseMDNodeVector(Elts))
return true;
MD = (IsDistinct ? MDTuple::getDistinct : MDTuple::get)(Context, Elts);
return false;
}
/// MDNode:
/// ::= !{ ... }
/// ::= !7
/// ::= !DILocation(...)
bool LLParser::ParseMDNode(MDNode *&N) {
if (Lex.getKind() == lltok::MetadataVar)
return ParseSpecializedMDNode(N);
return ParseToken(lltok::exclaim, "expected '!' here") ||
ParseMDNodeTail(N);
}
bool LLParser::ParseMDNodeTail(MDNode *&N) {
// !{ ... }
if (Lex.getKind() == lltok::lbrace)
return ParseMDTuple(N);
// !42
return ParseMDNodeID(N);
}
namespace {
/// Structure to represent an optional metadata field.
template <class FieldTy> struct MDFieldImpl {
typedef MDFieldImpl ImplTy;
FieldTy Val;
bool Seen;
void assign(FieldTy Val) {
Seen = true;
this->Val = std::move(Val);
}
explicit MDFieldImpl(FieldTy Default)
: Val(std::move(Default)), Seen(false) {}
};
struct MDUnsignedField : public MDFieldImpl<uint64_t> {
uint64_t Max;
MDUnsignedField(uint64_t Default = 0, uint64_t Max = UINT64_MAX)
: ImplTy(Default), Max(Max) {}
};
struct LineField : public MDUnsignedField {
LineField() : MDUnsignedField(0, UINT32_MAX) {}
};
struct ColumnField : public MDUnsignedField {
ColumnField() : MDUnsignedField(0, UINT16_MAX) {}
};
struct DwarfTagField : public MDUnsignedField {
DwarfTagField() : MDUnsignedField(0, dwarf::DW_TAG_hi_user) {}
DwarfTagField(dwarf::Tag DefaultTag)
: MDUnsignedField(DefaultTag, dwarf::DW_TAG_hi_user) {}
};
struct DwarfMacinfoTypeField : public MDUnsignedField {
DwarfMacinfoTypeField() : MDUnsignedField(0, dwarf::DW_MACINFO_vendor_ext) {}
DwarfMacinfoTypeField(dwarf::MacinfoRecordType DefaultType)
: MDUnsignedField(DefaultType, dwarf::DW_MACINFO_vendor_ext) {}
};
struct DwarfAttEncodingField : public MDUnsignedField {
DwarfAttEncodingField() : MDUnsignedField(0, dwarf::DW_ATE_hi_user) {}
};
struct DwarfVirtualityField : public MDUnsignedField {
DwarfVirtualityField() : MDUnsignedField(0, dwarf::DW_VIRTUALITY_max) {}
};
struct DwarfLangField : public MDUnsignedField {
DwarfLangField() : MDUnsignedField(0, dwarf::DW_LANG_hi_user) {}
};
struct DwarfCCField : public MDUnsignedField {
DwarfCCField() : MDUnsignedField(0, dwarf::DW_CC_hi_user) {}
};
struct EmissionKindField : public MDUnsignedField {
EmissionKindField() : MDUnsignedField(0, DICompileUnit::LastEmissionKind) {}
};
struct DIFlagField : public MDFieldImpl<DINode::DIFlags> {
DIFlagField() : MDFieldImpl(DINode::FlagZero) {}
};
struct MDSignedField : public MDFieldImpl<int64_t> {
int64_t Min;
int64_t Max;
MDSignedField(int64_t Default = 0)
: ImplTy(Default), Min(INT64_MIN), Max(INT64_MAX) {}
MDSignedField(int64_t Default, int64_t Min, int64_t Max)
: ImplTy(Default), Min(Min), Max(Max) {}
};
struct MDBoolField : public MDFieldImpl<bool> {
MDBoolField(bool Default = false) : ImplTy(Default) {}
};
struct MDField : public MDFieldImpl<Metadata *> {
bool AllowNull;
MDField(bool AllowNull = true) : ImplTy(nullptr), AllowNull(AllowNull) {}
};
struct MDConstant : public MDFieldImpl<ConstantAsMetadata *> {
MDConstant() : ImplTy(nullptr) {}
};
struct MDStringField : public MDFieldImpl<MDString *> {
bool AllowEmpty;
MDStringField(bool AllowEmpty = true)
: ImplTy(nullptr), AllowEmpty(AllowEmpty) {}
};
struct MDFieldList : public MDFieldImpl<SmallVector<Metadata *, 4>> {
MDFieldList() : ImplTy(SmallVector<Metadata *, 4>()) {}
};
struct ChecksumKindField : public MDFieldImpl<DIFile::ChecksumKind> {
ChecksumKindField() : ImplTy(DIFile::CSK_None) {}
ChecksumKindField(DIFile::ChecksumKind CSKind) : ImplTy(CSKind) {}
};
} // end anonymous namespace
namespace llvm {
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
MDUnsignedField &Result) {
if (Lex.getKind() != lltok::APSInt || Lex.getAPSIntVal().isSigned())
return TokError("expected unsigned integer");
auto &U = Lex.getAPSIntVal();
if (U.ugt(Result.Max))
return TokError("value for '" + Name + "' too large, limit is " +
Twine(Result.Max));
Result.assign(U.getZExtValue());
assert(Result.Val <= Result.Max && "Expected value in range");
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, LineField &Result) {
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, ColumnField &Result) {
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, DwarfTagField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfTag)
return TokError("expected DWARF tag");
unsigned Tag = dwarf::getTag(Lex.getStrVal());
if (Tag == dwarf::DW_TAG_invalid)
return TokError("invalid DWARF tag" + Twine(" '") + Lex.getStrVal() + "'");
assert(Tag <= Result.Max && "Expected valid DWARF tag");
Result.assign(Tag);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
DwarfMacinfoTypeField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfMacinfo)
return TokError("expected DWARF macinfo type");
unsigned Macinfo = dwarf::getMacinfo(Lex.getStrVal());
if (Macinfo == dwarf::DW_MACINFO_invalid)
return TokError(
"invalid DWARF macinfo type" + Twine(" '") + Lex.getStrVal() + "'");
assert(Macinfo <= Result.Max && "Expected valid DWARF macinfo type");
Result.assign(Macinfo);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
DwarfVirtualityField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfVirtuality)
return TokError("expected DWARF virtuality code");
unsigned Virtuality = dwarf::getVirtuality(Lex.getStrVal());
if (Virtuality == dwarf::DW_VIRTUALITY_invalid)
return TokError("invalid DWARF virtuality code" + Twine(" '") +
Lex.getStrVal() + "'");
assert(Virtuality <= Result.Max && "Expected valid DWARF virtuality code");
Result.assign(Virtuality);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, DwarfLangField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfLang)
return TokError("expected DWARF language");
unsigned Lang = dwarf::getLanguage(Lex.getStrVal());
if (!Lang)
return TokError("invalid DWARF language" + Twine(" '") + Lex.getStrVal() +
"'");
assert(Lang <= Result.Max && "Expected valid DWARF language");
Result.assign(Lang);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, DwarfCCField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfCC)
return TokError("expected DWARF calling convention");
unsigned CC = dwarf::getCallingConvention(Lex.getStrVal());
if (!CC)
return TokError("invalid DWARF calling convention" + Twine(" '") + Lex.getStrVal() +
"'");
assert(CC <= Result.Max && "Expected valid DWARF calling convention");
Result.assign(CC);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, EmissionKindField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::EmissionKind)
return TokError("expected emission kind");
auto Kind = DICompileUnit::getEmissionKind(Lex.getStrVal());
if (!Kind)
return TokError("invalid emission kind" + Twine(" '") + Lex.getStrVal() +
"'");
assert(*Kind <= Result.Max && "Expected valid emission kind");
Result.assign(*Kind);
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
DwarfAttEncodingField &Result) {
if (Lex.getKind() == lltok::APSInt)
return ParseMDField(Loc, Name, static_cast<MDUnsignedField &>(Result));
if (Lex.getKind() != lltok::DwarfAttEncoding)
return TokError("expected DWARF type attribute encoding");
unsigned Encoding = dwarf::getAttributeEncoding(Lex.getStrVal());
if (!Encoding)
return TokError("invalid DWARF type attribute encoding" + Twine(" '") +
Lex.getStrVal() + "'");
assert(Encoding <= Result.Max && "Expected valid DWARF language");
Result.assign(Encoding);
Lex.Lex();
return false;
}
/// DIFlagField
/// ::= uint32
/// ::= DIFlagVector
/// ::= DIFlagVector '|' DIFlagFwdDecl '|' uint32 '|' DIFlagPublic
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, DIFlagField &Result) {
// Parser for a single flag.
auto parseFlag = [&](DINode::DIFlags &Val) {
if (Lex.getKind() == lltok::APSInt && !Lex.getAPSIntVal().isSigned()) {
uint32_t TempVal = static_cast<uint32_t>(Val);
bool Res = ParseUInt32(TempVal);
Val = static_cast<DINode::DIFlags>(TempVal);
return Res;
}
if (Lex.getKind() != lltok::DIFlag)
return TokError("expected debug info flag");
Val = DINode::getFlag(Lex.getStrVal());
if (!Val)
return TokError(Twine("invalid debug info flag flag '") +
Lex.getStrVal() + "'");
Lex.Lex();
return false;
};
// Parse the flags and combine them together.
DINode::DIFlags Combined = DINode::FlagZero;
do {
DINode::DIFlags Val;
if (parseFlag(Val))
return true;
Combined |= Val;
} while (EatIfPresent(lltok::bar));
Result.assign(Combined);
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
MDSignedField &Result) {
if (Lex.getKind() != lltok::APSInt)
return TokError("expected signed integer");
auto &S = Lex.getAPSIntVal();
if (S < Result.Min)
return TokError("value for '" + Name + "' too small, limit is " +
Twine(Result.Min));
if (S > Result.Max)
return TokError("value for '" + Name + "' too large, limit is " +
Twine(Result.Max));
Result.assign(S.getExtValue());
assert(Result.Val >= Result.Min && "Expected value in range");
assert(Result.Val <= Result.Max && "Expected value in range");
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, MDBoolField &Result) {
switch (Lex.getKind()) {
default:
return TokError("expected 'true' or 'false'");
case lltok::kw_true:
Result.assign(true);
break;
case lltok::kw_false:
Result.assign(false);
break;
}
Lex.Lex();
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, MDField &Result) {
if (Lex.getKind() == lltok::kw_null) {
if (!Result.AllowNull)
return TokError("'" + Name + "' cannot be null");
Lex.Lex();
Result.assign(nullptr);
return false;
}
Metadata *MD;
if (ParseMetadata(MD, nullptr))
return true;
Result.assign(MD);
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, MDStringField &Result) {
LocTy ValueLoc = Lex.getLoc();
std::string S;
if (ParseStringConstant(S))
return true;
if (!Result.AllowEmpty && S.empty())
return Error(ValueLoc, "'" + Name + "' cannot be empty");
Result.assign(S.empty() ? nullptr : MDString::get(Context, S));
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name, MDFieldList &Result) {
SmallVector<Metadata *, 4> MDs;
if (ParseMDNodeVector(MDs))
return true;
Result.assign(std::move(MDs));
return false;
}
template <>
bool LLParser::ParseMDField(LocTy Loc, StringRef Name,
ChecksumKindField &Result) {
if (Lex.getKind() != lltok::ChecksumKind)
return TokError(
"invalid checksum kind" + Twine(" '") + Lex.getStrVal() + "'");
DIFile::ChecksumKind CSKind = DIFile::getChecksumKind(Lex.getStrVal());
Result.assign(CSKind);
Lex.Lex();
return false;
}
} // end namespace llvm
template <class ParserTy>
bool LLParser::ParseMDFieldsImplBody(ParserTy parseField) {
do {
if (Lex.getKind() != lltok::LabelStr)
return TokError("expected field label here");
if (parseField())
return true;
} while (EatIfPresent(lltok::comma));
return false;
}
template <class ParserTy>
bool LLParser::ParseMDFieldsImpl(ParserTy parseField, LocTy &ClosingLoc) {
assert(Lex.getKind() == lltok::MetadataVar && "Expected metadata type name");
Lex.Lex();
if (ParseToken(lltok::lparen, "expected '(' here"))
return true;
if (Lex.getKind() != lltok::rparen)
if (ParseMDFieldsImplBody(parseField))
return true;
ClosingLoc = Lex.getLoc();
return ParseToken(lltok::rparen, "expected ')' here");
}
template <class FieldTy>
bool LLParser::ParseMDField(StringRef Name, FieldTy &Result) {
if (Result.Seen)
return TokError("field '" + Name + "' cannot be specified more than once");
LocTy Loc = Lex.getLoc();
Lex.Lex();
return ParseMDField(Loc, Name, Result);
}
bool LLParser::ParseSpecializedMDNode(MDNode *&N, bool IsDistinct) {
assert(Lex.getKind() == lltok::MetadataVar && "Expected metadata type name");
#define HANDLE_SPECIALIZED_MDNODE_LEAF(CLASS) \
if (Lex.getStrVal() == #CLASS) \
return Parse##CLASS(N, IsDistinct);
#include "llvm/IR/Metadata.def"
return TokError("expected metadata type");
}
#define DECLARE_FIELD(NAME, TYPE, INIT) TYPE NAME INIT
#define NOP_FIELD(NAME, TYPE, INIT)
#define REQUIRE_FIELD(NAME, TYPE, INIT) \
if (!NAME.Seen) \
return Error(ClosingLoc, "missing required field '" #NAME "'");
#define PARSE_MD_FIELD(NAME, TYPE, DEFAULT) \
if (Lex.getStrVal() == #NAME) \
return ParseMDField(#NAME, NAME);
#define PARSE_MD_FIELDS() \
VISIT_MD_FIELDS(DECLARE_FIELD, DECLARE_FIELD) \
do { \
LocTy ClosingLoc; \
if (ParseMDFieldsImpl([&]() -> bool { \
VISIT_MD_FIELDS(PARSE_MD_FIELD, PARSE_MD_FIELD) \
return TokError(Twine("invalid field '") + Lex.getStrVal() + "'"); \
}, ClosingLoc)) \
return true; \
VISIT_MD_FIELDS(NOP_FIELD, REQUIRE_FIELD) \
} while (false)
#define GET_OR_DISTINCT(CLASS, ARGS) \
(IsDistinct ? CLASS::getDistinct ARGS : CLASS::get ARGS)
/// ParseDILocationFields:
/// ::= !DILocation(line: 43, column: 8, scope: !5, inlinedAt: !6)
bool LLParser::ParseDILocation(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(line, LineField, ); \
OPTIONAL(column, ColumnField, ); \
REQUIRED(scope, MDField, (/* AllowNull */ false)); \
OPTIONAL(inlinedAt, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(
DILocation, (Context, line.Val, column.Val, scope.Val, inlinedAt.Val));
return false;
}
/// ParseGenericDINode:
/// ::= !GenericDINode(tag: 15, header: "...", operands: {...})
bool LLParser::ParseGenericDINode(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(tag, DwarfTagField, ); \
OPTIONAL(header, MDStringField, ); \
OPTIONAL(operands, MDFieldList, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(GenericDINode,
(Context, tag.Val, header.Val, operands.Val));
return false;
}
/// ParseDISubrange:
/// ::= !DISubrange(count: 30, lowerBound: 2)
bool LLParser::ParseDISubrange(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(count, MDSignedField, (-1, -1, INT64_MAX)); \
OPTIONAL(lowerBound, MDSignedField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DISubrange, (Context, count.Val, lowerBound.Val));
return false;
}
/// ParseDIEnumerator:
/// ::= !DIEnumerator(value: 30, name: "SomeKind")
bool LLParser::ParseDIEnumerator(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(name, MDStringField, ); \
REQUIRED(value, MDSignedField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIEnumerator, (Context, value.Val, name.Val));
return false;
}
/// ParseDIBasicType:
/// ::= !DIBasicType(tag: DW_TAG_base_type, name: "int", size: 32, align: 32)
bool LLParser::ParseDIBasicType(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(tag, DwarfTagField, (dwarf::DW_TAG_base_type)); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(size, MDUnsignedField, (0, UINT64_MAX)); \
OPTIONAL(align, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(encoding, DwarfAttEncodingField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIBasicType, (Context, tag.Val, name.Val, size.Val,
align.Val, encoding.Val));
return false;
}
/// ParseDIDerivedType:
/// ::= !DIDerivedType(tag: DW_TAG_pointer_type, name: "int", file: !0,
/// line: 7, scope: !1, baseType: !2, size: 32,
/// align: 32, offset: 0, flags: 0, extraData: !3)
bool LLParser::ParseDIDerivedType(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(tag, DwarfTagField, ); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(scope, MDField, ); \
REQUIRED(baseType, MDField, ); \
OPTIONAL(size, MDUnsignedField, (0, UINT64_MAX)); \
OPTIONAL(align, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(offset, MDUnsignedField, (0, UINT64_MAX)); \
OPTIONAL(flags, DIFlagField, ); \
OPTIONAL(extraData, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIDerivedType,
(Context, tag.Val, name.Val, file.Val, line.Val,
scope.Val, baseType.Val, size.Val, align.Val,
offset.Val, flags.Val, extraData.Val));
return false;
}
bool LLParser::ParseDICompositeType(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(tag, DwarfTagField, ); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(scope, MDField, ); \
OPTIONAL(baseType, MDField, ); \
OPTIONAL(size, MDUnsignedField, (0, UINT64_MAX)); \
OPTIONAL(align, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(offset, MDUnsignedField, (0, UINT64_MAX)); \
OPTIONAL(flags, DIFlagField, ); \
OPTIONAL(elements, MDField, ); \
OPTIONAL(runtimeLang, DwarfLangField, ); \
OPTIONAL(vtableHolder, MDField, ); \
OPTIONAL(templateParams, MDField, ); \
OPTIONAL(identifier, MDStringField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
// If this has an identifier try to build an ODR type.
if (identifier.Val)
if (auto *CT = DICompositeType::buildODRType(
Context, *identifier.Val, tag.Val, name.Val, file.Val, line.Val,
scope.Val, baseType.Val, size.Val, align.Val, offset.Val, flags.Val,
elements.Val, runtimeLang.Val, vtableHolder.Val,
templateParams.Val)) {
Result = CT;
return false;
}
// Create a new node, and save it in the context if it belongs in the type
// map.
Result = GET_OR_DISTINCT(
DICompositeType,
(Context, tag.Val, name.Val, file.Val, line.Val, scope.Val, baseType.Val,
size.Val, align.Val, offset.Val, flags.Val, elements.Val,
runtimeLang.Val, vtableHolder.Val, templateParams.Val, identifier.Val));
return false;
}
bool LLParser::ParseDISubroutineType(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(flags, DIFlagField, ); \
OPTIONAL(cc, DwarfCCField, ); \
REQUIRED(types, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DISubroutineType,
(Context, flags.Val, cc.Val, types.Val));
return false;
}
/// ParseDIFileType:
/// ::= !DIFileType(filename: "path/to/file", directory: "/path/to/dir"
/// checksumkind: CSK_MD5,
/// checksum: "000102030405060708090a0b0c0d0e0f")
bool LLParser::ParseDIFile(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(filename, MDStringField, ); \
REQUIRED(directory, MDStringField, ); \
OPTIONAL(checksumkind, ChecksumKindField, ); \
OPTIONAL(checksum, MDStringField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIFile, (Context, filename.Val, directory.Val,
checksumkind.Val, checksum.Val));
return false;
}
/// ParseDICompileUnit:
/// ::= !DICompileUnit(language: DW_LANG_C99, file: !0, producer: "clang",
/// isOptimized: true, flags: "-O2", runtimeVersion: 1,
/// splitDebugFilename: "abc.debug",
/// emissionKind: FullDebug, enums: !1, retainedTypes: !2,
/// globals: !4, imports: !5, macros: !6, dwoId: 0x0abcd)
bool LLParser::ParseDICompileUnit(MDNode *&Result, bool IsDistinct) {
if (!IsDistinct)
return Lex.Error("missing 'distinct', required for !DICompileUnit");
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(language, DwarfLangField, ); \
REQUIRED(file, MDField, (/* AllowNull */ false)); \
OPTIONAL(producer, MDStringField, ); \
OPTIONAL(isOptimized, MDBoolField, ); \
OPTIONAL(flags, MDStringField, ); \
OPTIONAL(runtimeVersion, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(splitDebugFilename, MDStringField, ); \
OPTIONAL(emissionKind, EmissionKindField, ); \
OPTIONAL(enums, MDField, ); \
OPTIONAL(retainedTypes, MDField, ); \
OPTIONAL(globals, MDField, ); \
OPTIONAL(imports, MDField, ); \
OPTIONAL(macros, MDField, ); \
OPTIONAL(dwoId, MDUnsignedField, ); \
OPTIONAL(splitDebugInlining, MDBoolField, = true);
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = DICompileUnit::getDistinct(
Context, language.Val, file.Val, producer.Val, isOptimized.Val, flags.Val,
runtimeVersion.Val, splitDebugFilename.Val, emissionKind.Val, enums.Val,
retainedTypes.Val, globals.Val, imports.Val, macros.Val, dwoId.Val,
splitDebugInlining.Val);
return false;
}
/// ParseDISubprogram:
/// ::= !DISubprogram(scope: !0, name: "foo", linkageName: "_Zfoo",
/// file: !1, line: 7, type: !2, isLocal: false,
/// isDefinition: true, scopeLine: 8, containingType: !3,
/// virtuality: DW_VIRTUALTIY_pure_virtual,
/// virtualIndex: 10, thisAdjustment: 4, flags: 11,
/// isOptimized: false, templateParams: !4, declaration: !5,
/// variables: !6)
bool LLParser::ParseDISubprogram(MDNode *&Result, bool IsDistinct) {
auto Loc = Lex.getLoc();
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(scope, MDField, ); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(linkageName, MDStringField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(type, MDField, ); \
OPTIONAL(isLocal, MDBoolField, ); \
OPTIONAL(isDefinition, MDBoolField, (true)); \
OPTIONAL(scopeLine, LineField, ); \
OPTIONAL(containingType, MDField, ); \
OPTIONAL(virtuality, DwarfVirtualityField, ); \
OPTIONAL(virtualIndex, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(thisAdjustment, MDSignedField, (0, INT32_MIN, INT32_MAX)); \
OPTIONAL(flags, DIFlagField, ); \
OPTIONAL(isOptimized, MDBoolField, ); \
OPTIONAL(unit, MDField, ); \
OPTIONAL(templateParams, MDField, ); \
OPTIONAL(declaration, MDField, ); \
OPTIONAL(variables, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
if (isDefinition.Val && !IsDistinct)
return Lex.Error(
Loc,
"missing 'distinct', required for !DISubprogram when 'isDefinition'");
Result = GET_OR_DISTINCT(
DISubprogram, (Context, scope.Val, name.Val, linkageName.Val, file.Val,
line.Val, type.Val, isLocal.Val, isDefinition.Val,
scopeLine.Val, containingType.Val, virtuality.Val,
virtualIndex.Val, thisAdjustment.Val, flags.Val,
isOptimized.Val, unit.Val, templateParams.Val,
declaration.Val, variables.Val));
return false;
}
/// ParseDILexicalBlock:
/// ::= !DILexicalBlock(scope: !0, file: !2, line: 7, column: 9)
bool LLParser::ParseDILexicalBlock(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(scope, MDField, (/* AllowNull */ false)); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(column, ColumnField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(
DILexicalBlock, (Context, scope.Val, file.Val, line.Val, column.Val));
return false;
}
/// ParseDILexicalBlockFile:
/// ::= !DILexicalBlockFile(scope: !0, file: !2, discriminator: 9)
bool LLParser::ParseDILexicalBlockFile(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(scope, MDField, (/* AllowNull */ false)); \
OPTIONAL(file, MDField, ); \
REQUIRED(discriminator, MDUnsignedField, (0, UINT32_MAX));
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DILexicalBlockFile,
(Context, scope.Val, file.Val, discriminator.Val));
return false;
}
/// ParseDINamespace:
/// ::= !DINamespace(scope: !0, file: !2, name: "SomeNamespace", line: 9)
bool LLParser::ParseDINamespace(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(scope, MDField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(exportSymbols, MDBoolField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DINamespace,
(Context, scope.Val, file.Val, name.Val, line.Val, exportSymbols.Val));
return false;
}
/// ParseDIMacro:
/// ::= !DIMacro(macinfo: type, line: 9, name: "SomeMacro", value: "SomeValue")
bool LLParser::ParseDIMacro(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(type, DwarfMacinfoTypeField, ); \
OPTIONAL(line, LineField, ); \
REQUIRED(name, MDStringField, ); \
OPTIONAL(value, MDStringField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIMacro,
(Context, type.Val, line.Val, name.Val, value.Val));
return false;
}
/// ParseDIMacroFile:
/// ::= !DIMacroFile(line: 9, file: !2, nodes: !3)
bool LLParser::ParseDIMacroFile(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(type, DwarfMacinfoTypeField, (dwarf::DW_MACINFO_start_file)); \
OPTIONAL(line, LineField, ); \
REQUIRED(file, MDField, ); \
OPTIONAL(nodes, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIMacroFile,
(Context, type.Val, line.Val, file.Val, nodes.Val));
return false;
}
/// ParseDIModule:
/// ::= !DIModule(scope: !0, name: "SomeModule", configMacros: "-DNDEBUG",
/// includePath: "/usr/include", isysroot: "/")
bool LLParser::ParseDIModule(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(scope, MDField, ); \
REQUIRED(name, MDStringField, ); \
OPTIONAL(configMacros, MDStringField, ); \
OPTIONAL(includePath, MDStringField, ); \
OPTIONAL(isysroot, MDStringField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIModule, (Context, scope.Val, name.Val,
configMacros.Val, includePath.Val, isysroot.Val));
return false;
}
/// ParseDITemplateTypeParameter:
/// ::= !DITemplateTypeParameter(name: "Ty", type: !1)
bool LLParser::ParseDITemplateTypeParameter(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(name, MDStringField, ); \
REQUIRED(type, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result =
GET_OR_DISTINCT(DITemplateTypeParameter, (Context, name.Val, type.Val));
return false;
}
/// ParseDITemplateValueParameter:
/// ::= !DITemplateValueParameter(tag: DW_TAG_template_value_parameter,
/// name: "V", type: !1, value: i32 7)
bool LLParser::ParseDITemplateValueParameter(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(tag, DwarfTagField, (dwarf::DW_TAG_template_value_parameter)); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(type, MDField, ); \
REQUIRED(value, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DITemplateValueParameter,
(Context, tag.Val, name.Val, type.Val, value.Val));
return false;
}
/// ParseDIGlobalVariable:
/// ::= !DIGlobalVariable(scope: !0, name: "foo", linkageName: "foo",
/// file: !1, line: 7, type: !2, isLocal: false,
/// isDefinition: true, declaration: !3, align: 8)
bool LLParser::ParseDIGlobalVariable(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(name, MDStringField, (/* AllowEmpty */ false)); \
OPTIONAL(scope, MDField, ); \
OPTIONAL(linkageName, MDStringField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(type, MDField, ); \
OPTIONAL(isLocal, MDBoolField, ); \
OPTIONAL(isDefinition, MDBoolField, (true)); \
OPTIONAL(declaration, MDField, ); \
OPTIONAL(align, MDUnsignedField, (0, UINT32_MAX));
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIGlobalVariable,
(Context, scope.Val, name.Val, linkageName.Val,
file.Val, line.Val, type.Val, isLocal.Val,
isDefinition.Val, declaration.Val, align.Val));
return false;
}
/// ParseDILocalVariable:
/// ::= !DILocalVariable(arg: 7, scope: !0, name: "foo",
/// file: !1, line: 7, type: !2, arg: 2, flags: 7,
/// align: 8)
/// ::= !DILocalVariable(scope: !0, name: "foo",
/// file: !1, line: 7, type: !2, arg: 2, flags: 7,
/// align: 8)
bool LLParser::ParseDILocalVariable(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(scope, MDField, (/* AllowNull */ false)); \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(arg, MDUnsignedField, (0, UINT16_MAX)); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(type, MDField, ); \
OPTIONAL(flags, DIFlagField, ); \
OPTIONAL(align, MDUnsignedField, (0, UINT32_MAX));
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DILocalVariable,
(Context, scope.Val, name.Val, file.Val, line.Val,
type.Val, arg.Val, flags.Val, align.Val));
return false;
}
/// ParseDIExpression:
/// ::= !DIExpression(0, 7, -1)
bool LLParser::ParseDIExpression(MDNode *&Result, bool IsDistinct) {
assert(Lex.getKind() == lltok::MetadataVar && "Expected metadata type name");
Lex.Lex();
if (ParseToken(lltok::lparen, "expected '(' here"))
return true;
SmallVector<uint64_t, 8> Elements;
if (Lex.getKind() != lltok::rparen)
do {
if (Lex.getKind() == lltok::DwarfOp) {
if (unsigned Op = dwarf::getOperationEncoding(Lex.getStrVal())) {
Lex.Lex();
Elements.push_back(Op);
continue;
}
return TokError(Twine("invalid DWARF op '") + Lex.getStrVal() + "'");
}
if (Lex.getKind() != lltok::APSInt || Lex.getAPSIntVal().isSigned())
return TokError("expected unsigned integer");
auto &U = Lex.getAPSIntVal();
if (U.ugt(UINT64_MAX))
return TokError("element too large, limit is " + Twine(UINT64_MAX));
Elements.push_back(U.getZExtValue());
Lex.Lex();
} while (EatIfPresent(lltok::comma));
if (ParseToken(lltok::rparen, "expected ')' here"))
return true;
Result = GET_OR_DISTINCT(DIExpression, (Context, Elements));
return false;
}
/// ParseDIGlobalVariableExpression:
/// ::= !DIGlobalVariableExpression(var: !0, expr: !1)
bool LLParser::ParseDIGlobalVariableExpression(MDNode *&Result,
bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(var, MDField, ); \
OPTIONAL(expr, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result =
GET_OR_DISTINCT(DIGlobalVariableExpression, (Context, var.Val, expr.Val));
return false;
}
/// ParseDIObjCProperty:
/// ::= !DIObjCProperty(name: "foo", file: !1, line: 7, setter: "setFoo",
/// getter: "getFoo", attributes: 7, type: !2)
bool LLParser::ParseDIObjCProperty(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
OPTIONAL(name, MDStringField, ); \
OPTIONAL(file, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(setter, MDStringField, ); \
OPTIONAL(getter, MDStringField, ); \
OPTIONAL(attributes, MDUnsignedField, (0, UINT32_MAX)); \
OPTIONAL(type, MDField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIObjCProperty,
(Context, name.Val, file.Val, line.Val, setter.Val,
getter.Val, attributes.Val, type.Val));
return false;
}
/// ParseDIImportedEntity:
/// ::= !DIImportedEntity(tag: DW_TAG_imported_module, scope: !0, entity: !1,
/// line: 7, name: "foo")
bool LLParser::ParseDIImportedEntity(MDNode *&Result, bool IsDistinct) {
#define VISIT_MD_FIELDS(OPTIONAL, REQUIRED) \
REQUIRED(tag, DwarfTagField, ); \
REQUIRED(scope, MDField, ); \
OPTIONAL(entity, MDField, ); \
OPTIONAL(line, LineField, ); \
OPTIONAL(name, MDStringField, );
PARSE_MD_FIELDS();
#undef VISIT_MD_FIELDS
Result = GET_OR_DISTINCT(DIImportedEntity, (Context, tag.Val, scope.Val,
entity.Val, line.Val, name.Val));
return false;
}
#undef PARSE_MD_FIELD
#undef NOP_FIELD
#undef REQUIRE_FIELD
#undef DECLARE_FIELD
/// ParseMetadataAsValue
/// ::= metadata i32 %local
/// ::= metadata i32 @global
/// ::= metadata i32 7
/// ::= metadata !0
/// ::= metadata !{...}
/// ::= metadata !"string"
bool LLParser::ParseMetadataAsValue(Value *&V, PerFunctionState &PFS) {
// Note: the type 'metadata' has already been parsed.
Metadata *MD;
if (ParseMetadata(MD, &PFS))
return true;
V = MetadataAsValue::get(Context, MD);
return false;
}
/// ParseValueAsMetadata
/// ::= i32 %local
/// ::= i32 @global
/// ::= i32 7
bool LLParser::ParseValueAsMetadata(Metadata *&MD, const Twine &TypeMsg,
PerFunctionState *PFS) {
Type *Ty;
LocTy Loc;
if (ParseType(Ty, TypeMsg, Loc))
return true;
if (Ty->isMetadataTy())
return Error(Loc, "invalid metadata-value-metadata roundtrip");
Value *V;
if (ParseValue(Ty, V, PFS))
return true;
MD = ValueAsMetadata::get(V);
return false;
}
/// ParseMetadata
/// ::= i32 %local
/// ::= i32 @global
/// ::= i32 7
/// ::= !42
/// ::= !{...}
/// ::= !"string"
/// ::= !DILocation(...)
bool LLParser::ParseMetadata(Metadata *&MD, PerFunctionState *PFS) {
if (Lex.getKind() == lltok::MetadataVar) {
MDNode *N;
if (ParseSpecializedMDNode(N))
return true;
MD = N;
return false;
}
// ValueAsMetadata:
// <type> <value>
if (Lex.getKind() != lltok::exclaim)
return ParseValueAsMetadata(MD, "expected metadata operand", PFS);
// '!'.
assert(Lex.getKind() == lltok::exclaim && "Expected '!' here");
Lex.Lex();
// MDString:
// ::= '!' STRINGCONSTANT
if (Lex.getKind() == lltok::StringConstant) {
MDString *S;
if (ParseMDString(S))
return true;
MD = S;
return false;
}
// MDNode:
// !{ ... }
// !7
MDNode *N;
if (ParseMDNodeTail(N))
return true;
MD = N;
return false;
}
//===----------------------------------------------------------------------===//
// Function Parsing.
//===----------------------------------------------------------------------===//
bool LLParser::ConvertValIDToValue(Type *Ty, ValID &ID, Value *&V,
PerFunctionState *PFS) {
if (Ty->isFunctionTy())
return Error(ID.Loc, "functions are not values, refer to them as pointers");
switch (ID.Kind) {
case ValID::t_LocalID:
if (!PFS) return Error(ID.Loc, "invalid use of function-local name");
V = PFS->GetVal(ID.UIntVal, Ty, ID.Loc);
return V == nullptr;
case ValID::t_LocalName:
if (!PFS) return Error(ID.Loc, "invalid use of function-local name");
V = PFS->GetVal(ID.StrVal, Ty, ID.Loc);
return V == nullptr;
case ValID::t_InlineAsm: {
if (!ID.FTy || !InlineAsm::Verify(ID.FTy, ID.StrVal2))
return Error(ID.Loc, "invalid type for inline asm constraint string");
V = InlineAsm::get(ID.FTy, ID.StrVal, ID.StrVal2, ID.UIntVal & 1,
(ID.UIntVal >> 1) & 1,
(InlineAsm::AsmDialect(ID.UIntVal >> 2)));
return false;
}
case ValID::t_GlobalName:
V = GetGlobalVal(ID.StrVal, Ty, ID.Loc);
return V == nullptr;
case ValID::t_GlobalID:
V = GetGlobalVal(ID.UIntVal, Ty, ID.Loc);
return V == nullptr;
case ValID::t_APSInt:
if (!Ty->isIntegerTy())
return Error(ID.Loc, "integer constant must have integer type");
ID.APSIntVal = ID.APSIntVal.extOrTrunc(Ty->getPrimitiveSizeInBits());
V = ConstantInt::get(Context, ID.APSIntVal);
return false;
case ValID::t_APFloat:
if (!Ty->isFloatingPointTy() ||
!ConstantFP::isValueValidForType(Ty, ID.APFloatVal))
return Error(ID.Loc, "floating point constant invalid for type");
// The lexer has no type info, so builds all half, float, and double FP
// constants as double. Fix this here. Long double does not need this.
if (&ID.APFloatVal.getSemantics() == &APFloat::IEEEdouble()) {
bool Ignored;
if (Ty->isHalfTy())
ID.APFloatVal.convert(APFloat::IEEEhalf(), APFloat::rmNearestTiesToEven,
&Ignored);
else if (Ty->isFloatTy())
ID.APFloatVal.convert(APFloat::IEEEsingle(), APFloat::rmNearestTiesToEven,
&Ignored);
}
V = ConstantFP::get(Context, ID.APFloatVal);
if (V->getType() != Ty)
return Error(ID.Loc, "floating point constant does not have type '" +
getTypeString(Ty) + "'");
return false;
case ValID::t_Null:
if (!Ty->isPointerTy())
return Error(ID.Loc, "null must be a pointer type");
V = ConstantPointerNull::get(cast<PointerType>(Ty));
return false;
case ValID::t_Undef:
// FIXME: LabelTy should not be a first-class type.
if (!Ty->isFirstClassType() || Ty->isLabelTy())
return Error(ID.Loc, "invalid type for undef constant");
V = UndefValue::get(Ty);
return false;
case ValID::t_EmptyArray:
if (!Ty->isArrayTy() || cast<ArrayType>(Ty)->getNumElements() != 0)
return Error(ID.Loc, "invalid empty array initializer");
V = UndefValue::get(Ty);
return false;
case ValID::t_Zero:
// FIXME: LabelTy should not be a first-class type.
if (!Ty->isFirstClassType() || Ty->isLabelTy())
return Error(ID.Loc, "invalid type for null constant");
V = Constant::getNullValue(Ty);
return false;
case ValID::t_None:
if (!Ty->isTokenTy())
return Error(ID.Loc, "invalid type for none constant");
V = Constant::getNullValue(Ty);
return false;
case ValID::t_Constant:
if (ID.ConstantVal->getType() != Ty)
return Error(ID.Loc, "constant expression type mismatch");
V = ID.ConstantVal;
return false;
case ValID::t_ConstantStruct:
case ValID::t_PackedConstantStruct:
if (StructType *ST = dyn_cast<StructType>(Ty)) {
if (ST->getNumElements() != ID.UIntVal)
return Error(ID.Loc,
"initializer with struct type has wrong # elements");
if (ST->isPacked() != (ID.Kind == ValID::t_PackedConstantStruct))
return Error(ID.Loc, "packed'ness of initializer and type don't match");
// Verify that the elements are compatible with the structtype.
for (unsigned i = 0, e = ID.UIntVal; i != e; ++i)
if (ID.ConstantStructElts[i]->getType() != ST->getElementType(i))
return Error(ID.Loc, "element " + Twine(i) +
" of struct initializer doesn't match struct element type");
V = ConstantStruct::get(
ST, makeArrayRef(ID.ConstantStructElts.get(), ID.UIntVal));
} else
return Error(ID.Loc, "constant expression type mismatch");
return false;
}
llvm_unreachable("Invalid ValID");
}
bool LLParser::parseConstantValue(Type *Ty, Constant *&C) {
C = nullptr;
ValID ID;
auto Loc = Lex.getLoc();
if (ParseValID(ID, /*PFS=*/nullptr))
return true;
switch (ID.Kind) {
case ValID::t_APSInt:
case ValID::t_APFloat:
case ValID::t_Undef:
case ValID::t_Constant:
case ValID::t_ConstantStruct:
case ValID::t_PackedConstantStruct: {
Value *V;
if (ConvertValIDToValue(Ty, ID, V, /*PFS=*/nullptr))
return true;
assert(isa<Constant>(V) && "Expected a constant value");
C = cast<Constant>(V);
return false;
}
default:
return Error(Loc, "expected a constant value");
}
}
bool LLParser::ParseValue(Type *Ty, Value *&V, PerFunctionState *PFS) {
V = nullptr;
ValID ID;
return ParseValID(ID, PFS) || ConvertValIDToValue(Ty, ID, V, PFS);
}
bool LLParser::ParseTypeAndValue(Value *&V, PerFunctionState *PFS) {
Type *Ty = nullptr;
return ParseType(Ty) ||
ParseValue(Ty, V, PFS);
}
bool LLParser::ParseTypeAndBasicBlock(BasicBlock *&BB, LocTy &Loc,
PerFunctionState &PFS) {
Value *V;
Loc = Lex.getLoc();
if (ParseTypeAndValue(V, PFS)) return true;
if (!isa<BasicBlock>(V))
return Error(Loc, "expected a basic block");
BB = cast<BasicBlock>(V);
return false;
}
/// FunctionHeader
/// ::= OptionalLinkage OptionalVisibility OptionalCallingConv OptRetAttrs
/// OptUnnamedAddr Type GlobalName '(' ArgList ')' OptFuncAttrs OptSection
/// OptionalAlign OptGC OptionalPrefix OptionalPrologue OptPersonalityFn
bool LLParser::ParseFunctionHeader(Function *&Fn, bool isDefine) {
// Parse the linkage.
LocTy LinkageLoc = Lex.getLoc();
unsigned Linkage;
unsigned Visibility;
unsigned DLLStorageClass;
AttrBuilder RetAttrs;
unsigned CC;
bool HasLinkage;
Type *RetType = nullptr;
LocTy RetTypeLoc = Lex.getLoc();
if (ParseOptionalLinkage(Linkage, HasLinkage, Visibility, DLLStorageClass) ||
ParseOptionalCallingConv(CC) || ParseOptionalReturnAttrs(RetAttrs) ||
ParseType(RetType, RetTypeLoc, true /*void allowed*/))
return true;
// Verify that the linkage is ok.
switch ((GlobalValue::LinkageTypes)Linkage) {
case GlobalValue::ExternalLinkage:
break; // always ok.
case GlobalValue::ExternalWeakLinkage:
if (isDefine)
return Error(LinkageLoc, "invalid linkage for function definition");
break;
case GlobalValue::PrivateLinkage:
case GlobalValue::InternalLinkage:
case GlobalValue::AvailableExternallyLinkage:
case GlobalValue::LinkOnceAnyLinkage:
case GlobalValue::LinkOnceODRLinkage:
case GlobalValue::WeakAnyLinkage:
case GlobalValue::WeakODRLinkage:
if (!isDefine)
return Error(LinkageLoc, "invalid linkage for function declaration");
break;
case GlobalValue::AppendingLinkage:
case GlobalValue::CommonLinkage:
return Error(LinkageLoc, "invalid function linkage type");
}
if (!isValidVisibilityForLinkage(Visibility, Linkage))
return Error(LinkageLoc,
"symbol with local linkage must have default visibility");
if (!FunctionType::isValidReturnType(RetType))
return Error(RetTypeLoc, "invalid function return type");
LocTy NameLoc = Lex.getLoc();
std::string FunctionName;
if (Lex.getKind() == lltok::GlobalVar) {
FunctionName = Lex.getStrVal();
} else if (Lex.getKind() == lltok::GlobalID) { // @42 is ok.
unsigned NameID = Lex.getUIntVal();
if (NameID != NumberedVals.size())
return TokError("function expected to be numbered '%" +
Twine(NumberedVals.size()) + "'");
} else {
return TokError("expected function name");
}
Lex.Lex();
if (Lex.getKind() != lltok::lparen)
return TokError("expected '(' in function argument list");
SmallVector<ArgInfo, 8> ArgList;
bool isVarArg;
AttrBuilder FuncAttrs;
std::vector<unsigned> FwdRefAttrGrps;
LocTy BuiltinLoc;
std::string Section;
unsigned Alignment;
std::string GC;
GlobalValue::UnnamedAddr UnnamedAddr = GlobalValue::UnnamedAddr::None;
LocTy UnnamedAddrLoc;
Constant *Prefix = nullptr;
Constant *Prologue = nullptr;
Constant *PersonalityFn = nullptr;
Comdat *C;
if (ParseArgumentList(ArgList, isVarArg) ||
ParseOptionalUnnamedAddr(UnnamedAddr) ||
ParseFnAttributeValuePairs(FuncAttrs, FwdRefAttrGrps, false,
BuiltinLoc) ||
(EatIfPresent(lltok::kw_section) &&
ParseStringConstant(Section)) ||
parseOptionalComdat(FunctionName, C) ||
ParseOptionalAlignment(Alignment) ||
(EatIfPresent(lltok::kw_gc) &&
ParseStringConstant(GC)) ||
(EatIfPresent(lltok::kw_prefix) &&
ParseGlobalTypeAndValue(Prefix)) ||
(EatIfPresent(lltok::kw_prologue) &&
ParseGlobalTypeAndValue(Prologue)) ||
(EatIfPresent(lltok::kw_personality) &&
ParseGlobalTypeAndValue(PersonalityFn)))
return true;
if (FuncAttrs.contains(Attribute::Builtin))
return Error(BuiltinLoc, "'builtin' attribute not valid on function");
// If the alignment was parsed as an attribute, move to the alignment field.
if (FuncAttrs.hasAlignmentAttr()) {
Alignment = FuncAttrs.getAlignment();
FuncAttrs.removeAttribute(Attribute::Alignment);
}
// Okay, if we got here, the function is syntactically valid. Convert types
// and do semantic checks.
std::vector<Type*> ParamTypeList;
SmallVector<AttributeSet, 8> Attrs;
if (RetAttrs.hasAttributes())
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::ReturnIndex,
RetAttrs));
for (unsigned i = 0, e = ArgList.size(); i != e; ++i) {
ParamTypeList.push_back(ArgList[i].Ty);
if (ArgList[i].Attrs.hasAttributes(i + 1)) {
AttrBuilder B(ArgList[i].Attrs, i + 1);
Attrs.push_back(AttributeSet::get(RetType->getContext(), i + 1, B));
}
}
if (FuncAttrs.hasAttributes())
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::FunctionIndex,
FuncAttrs));
AttributeSet PAL = AttributeSet::get(Context, Attrs);
if (PAL.hasAttribute(1, Attribute::StructRet) && !RetType->isVoidTy())
return Error(RetTypeLoc, "functions with 'sret' argument must return void");
FunctionType *FT =
FunctionType::get(RetType, ParamTypeList, isVarArg);
PointerType *PFT = PointerType::getUnqual(FT);
Fn = nullptr;
if (!FunctionName.empty()) {
// If this was a definition of a forward reference, remove the definition
// from the forward reference table and fill in the forward ref.
auto FRVI = ForwardRefVals.find(FunctionName);
if (FRVI != ForwardRefVals.end()) {
Fn = M->getFunction(FunctionName);
if (!Fn)
return Error(FRVI->second.second, "invalid forward reference to "
"function as global value!");
if (Fn->getType() != PFT)
return Error(FRVI->second.second, "invalid forward reference to "
"function '" + FunctionName + "' with wrong type!");
ForwardRefVals.erase(FRVI);
} else if ((Fn = M->getFunction(FunctionName))) {
// Reject redefinitions.
return Error(NameLoc, "invalid redefinition of function '" +
FunctionName + "'");
} else if (M->getNamedValue(FunctionName)) {
return Error(NameLoc, "redefinition of function '@" + FunctionName + "'");
}
} else {
// If this is a definition of a forward referenced function, make sure the
// types agree.
auto I = ForwardRefValIDs.find(NumberedVals.size());
if (I != ForwardRefValIDs.end()) {
Fn = cast<Function>(I->second.first);
if (Fn->getType() != PFT)
return Error(NameLoc, "type of definition and forward reference of '@" +
Twine(NumberedVals.size()) + "' disagree");
ForwardRefValIDs.erase(I);
}
}
if (!Fn)
Fn = Function::Create(FT, GlobalValue::ExternalLinkage, FunctionName, M);
else // Move the forward-reference to the correct spot in the module.
M->getFunctionList().splice(M->end(), M->getFunctionList(), Fn);
if (FunctionName.empty())
NumberedVals.push_back(Fn);
Fn->setLinkage((GlobalValue::LinkageTypes)Linkage);
Fn->setVisibility((GlobalValue::VisibilityTypes)Visibility);
Fn->setDLLStorageClass((GlobalValue::DLLStorageClassTypes)DLLStorageClass);
Fn->setCallingConv(CC);
Fn->setAttributes(PAL);
Fn->setUnnamedAddr(UnnamedAddr);
Fn->setAlignment(Alignment);
Fn->setSection(Section);
Fn->setComdat(C);
Fn->setPersonalityFn(PersonalityFn);
if (!GC.empty()) Fn->setGC(GC);
Fn->setPrefixData(Prefix);
Fn->setPrologueData(Prologue);
ForwardRefAttrGroups[Fn] = FwdRefAttrGrps;
// Add all of the arguments we parsed to the function.
Function::arg_iterator ArgIt = Fn->arg_begin();
for (unsigned i = 0, e = ArgList.size(); i != e; ++i, ++ArgIt) {
// If the argument has a name, insert it into the argument symbol table.
if (ArgList[i].Name.empty()) continue;
// Set the name, if it conflicted, it will be auto-renamed.
ArgIt->setName(ArgList[i].Name);
if (ArgIt->getName() != ArgList[i].Name)
return Error(ArgList[i].Loc, "redefinition of argument '%" +
ArgList[i].Name + "'");
}
if (isDefine)
return false;
// Check the declaration has no block address forward references.
ValID ID;
if (FunctionName.empty()) {
ID.Kind = ValID::t_GlobalID;
ID.UIntVal = NumberedVals.size() - 1;
} else {
ID.Kind = ValID::t_GlobalName;
ID.StrVal = FunctionName;
}
auto Blocks = ForwardRefBlockAddresses.find(ID);
if (Blocks != ForwardRefBlockAddresses.end())
return Error(Blocks->first.Loc,
"cannot take blockaddress inside a declaration");
return false;
}
bool LLParser::PerFunctionState::resolveForwardRefBlockAddresses() {
ValID ID;
if (FunctionNumber == -1) {
ID.Kind = ValID::t_GlobalName;
ID.StrVal = F.getName();
} else {
ID.Kind = ValID::t_GlobalID;
ID.UIntVal = FunctionNumber;
}
auto Blocks = P.ForwardRefBlockAddresses.find(ID);
if (Blocks == P.ForwardRefBlockAddresses.end())
return false;
for (const auto &I : Blocks->second) {
const ValID &BBID = I.first;
GlobalValue *GV = I.second;
assert((BBID.Kind == ValID::t_LocalID || BBID.Kind == ValID::t_LocalName) &&
"Expected local id or name");
BasicBlock *BB;
if (BBID.Kind == ValID::t_LocalName)
BB = GetBB(BBID.StrVal, BBID.Loc);
else
BB = GetBB(BBID.UIntVal, BBID.Loc);
if (!BB)
return P.Error(BBID.Loc, "referenced value is not a basic block");
GV->replaceAllUsesWith(BlockAddress::get(&F, BB));
GV->eraseFromParent();
}
P.ForwardRefBlockAddresses.erase(Blocks);
return false;
}
/// ParseFunctionBody
/// ::= '{' BasicBlock+ UseListOrderDirective* '}'
bool LLParser::ParseFunctionBody(Function &Fn) {
if (Lex.getKind() != lltok::lbrace)
return TokError("expected '{' in function body");
Lex.Lex(); // eat the {.
int FunctionNumber = -1;
if (!Fn.hasName()) FunctionNumber = NumberedVals.size()-1;
PerFunctionState PFS(*this, Fn, FunctionNumber);
// Resolve block addresses and allow basic blocks to be forward-declared
// within this function.
if (PFS.resolveForwardRefBlockAddresses())
return true;
SaveAndRestore<PerFunctionState *> ScopeExit(BlockAddressPFS, &PFS);
// We need at least one basic block.
if (Lex.getKind() == lltok::rbrace || Lex.getKind() == lltok::kw_uselistorder)
return TokError("function body requires at least one basic block");
while (Lex.getKind() != lltok::rbrace &&
Lex.getKind() != lltok::kw_uselistorder)
if (ParseBasicBlock(PFS)) return true;
while (Lex.getKind() != lltok::rbrace)
if (ParseUseListOrder(&PFS))
return true;
// Eat the }.
Lex.Lex();
// Verify function is ok.
return PFS.FinishFunction();
}
/// ParseBasicBlock
/// ::= LabelStr? Instruction*
bool LLParser::ParseBasicBlock(PerFunctionState &PFS) {
// If this basic block starts out with a name, remember it.
std::string Name;
LocTy NameLoc = Lex.getLoc();
if (Lex.getKind() == lltok::LabelStr) {
Name = Lex.getStrVal();
Lex.Lex();
}
BasicBlock *BB = PFS.DefineBB(Name, NameLoc);
if (!BB)
return Error(NameLoc,
"unable to create block named '" + Name + "'");
std::string NameStr;
// Parse the instructions in this block until we get a terminator.
Instruction *Inst;
do {
// This instruction may have three possibilities for a name: a) none
// specified, b) name specified "%foo =", c) number specified: "%4 =".
LocTy NameLoc = Lex.getLoc();
int NameID = -1;
NameStr = "";
if (Lex.getKind() == lltok::LocalVarID) {
NameID = Lex.getUIntVal();
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after instruction id"))
return true;
} else if (Lex.getKind() == lltok::LocalVar) {
NameStr = Lex.getStrVal();
Lex.Lex();
if (ParseToken(lltok::equal, "expected '=' after instruction name"))
return true;
}
switch (ParseInstruction(Inst, BB, PFS)) {
default: llvm_unreachable("Unknown ParseInstruction result!");
case InstError: return true;
case InstNormal:
BB->getInstList().push_back(Inst);
// With a normal result, we check to see if the instruction is followed by
// a comma and metadata.
if (EatIfPresent(lltok::comma))
if (ParseInstructionMetadata(*Inst))
return true;
break;
case InstExtraComma:
BB->getInstList().push_back(Inst);
// If the instruction parser ate an extra comma at the end of it, it
// *must* be followed by metadata.
if (ParseInstructionMetadata(*Inst))
return true;
break;
}
// Set the name on the instruction.
if (PFS.SetInstName(NameID, NameStr, NameLoc, Inst)) return true;
} while (!isa<TerminatorInst>(Inst));
return false;
}
//===----------------------------------------------------------------------===//
// Instruction Parsing.
//===----------------------------------------------------------------------===//
/// ParseInstruction - Parse one of the many different instructions.
///
int LLParser::ParseInstruction(Instruction *&Inst, BasicBlock *BB,
PerFunctionState &PFS) {
lltok::Kind Token = Lex.getKind();
if (Token == lltok::Eof)
return TokError("found end of file when expecting more instructions");
LocTy Loc = Lex.getLoc();
unsigned KeywordVal = Lex.getUIntVal();
Lex.Lex(); // Eat the keyword.
switch (Token) {
default: return Error(Loc, "expected instruction opcode");
// Terminator Instructions.
case lltok::kw_unreachable: Inst = new UnreachableInst(Context); return false;
case lltok::kw_ret: return ParseRet(Inst, BB, PFS);
case lltok::kw_br: return ParseBr(Inst, PFS);
case lltok::kw_switch: return ParseSwitch(Inst, PFS);
case lltok::kw_indirectbr: return ParseIndirectBr(Inst, PFS);
case lltok::kw_invoke: return ParseInvoke(Inst, PFS);
case lltok::kw_resume: return ParseResume(Inst, PFS);
case lltok::kw_cleanupret: return ParseCleanupRet(Inst, PFS);
case lltok::kw_catchret: return ParseCatchRet(Inst, PFS);
case lltok::kw_catchswitch: return ParseCatchSwitch(Inst, PFS);
case lltok::kw_catchpad: return ParseCatchPad(Inst, PFS);
case lltok::kw_cleanuppad: return ParseCleanupPad(Inst, PFS);
// Binary Operators.
case lltok::kw_add:
case lltok::kw_sub:
case lltok::kw_mul:
case lltok::kw_shl: {
bool NUW = EatIfPresent(lltok::kw_nuw);
bool NSW = EatIfPresent(lltok::kw_nsw);
if (!NUW) NUW = EatIfPresent(lltok::kw_nuw);
if (ParseArithmetic(Inst, PFS, KeywordVal, 1)) return true;
if (NUW) cast<BinaryOperator>(Inst)->setHasNoUnsignedWrap(true);
if (NSW) cast<BinaryOperator>(Inst)->setHasNoSignedWrap(true);
return false;
}
case lltok::kw_fadd:
case lltok::kw_fsub:
case lltok::kw_fmul:
case lltok::kw_fdiv:
case lltok::kw_frem: {
FastMathFlags FMF = EatFastMathFlagsIfPresent();
int Res = ParseArithmetic(Inst, PFS, KeywordVal, 2);
if (Res != 0)
return Res;
if (FMF.any())
Inst->setFastMathFlags(FMF);
return 0;
}
case lltok::kw_sdiv:
case lltok::kw_udiv:
case lltok::kw_lshr:
case lltok::kw_ashr: {
bool Exact = EatIfPresent(lltok::kw_exact);
if (ParseArithmetic(Inst, PFS, KeywordVal, 1)) return true;
if (Exact) cast<BinaryOperator>(Inst)->setIsExact(true);
return false;
}
case lltok::kw_urem:
case lltok::kw_srem: return ParseArithmetic(Inst, PFS, KeywordVal, 1);
case lltok::kw_and:
case lltok::kw_or:
case lltok::kw_xor: return ParseLogical(Inst, PFS, KeywordVal);
case lltok::kw_icmp: return ParseCompare(Inst, PFS, KeywordVal);
case lltok::kw_fcmp: {
FastMathFlags FMF = EatFastMathFlagsIfPresent();
int Res = ParseCompare(Inst, PFS, KeywordVal);
if (Res != 0)
return Res;
if (FMF.any())
Inst->setFastMathFlags(FMF);
return 0;
}
// Casts.
case lltok::kw_trunc:
case lltok::kw_zext:
case lltok::kw_sext:
case lltok::kw_fptrunc:
case lltok::kw_fpext:
case lltok::kw_bitcast:
case lltok::kw_addrspacecast:
case lltok::kw_uitofp:
case lltok::kw_sitofp:
case lltok::kw_fptoui:
case lltok::kw_fptosi:
case lltok::kw_inttoptr:
case lltok::kw_ptrtoint: return ParseCast(Inst, PFS, KeywordVal);
// Other.
case lltok::kw_select: return ParseSelect(Inst, PFS);
case lltok::kw_va_arg: return ParseVA_Arg(Inst, PFS);
case lltok::kw_extractelement: return ParseExtractElement(Inst, PFS);
case lltok::kw_insertelement: return ParseInsertElement(Inst, PFS);
case lltok::kw_shufflevector: return ParseShuffleVector(Inst, PFS);
case lltok::kw_phi: return ParsePHI(Inst, PFS);
case lltok::kw_landingpad: return ParseLandingPad(Inst, PFS);
// Call.
case lltok::kw_call: return ParseCall(Inst, PFS, CallInst::TCK_None);
case lltok::kw_tail: return ParseCall(Inst, PFS, CallInst::TCK_Tail);
case lltok::kw_musttail: return ParseCall(Inst, PFS, CallInst::TCK_MustTail);
case lltok::kw_notail: return ParseCall(Inst, PFS, CallInst::TCK_NoTail);
// Memory.
case lltok::kw_alloca: return ParseAlloc(Inst, PFS);
case lltok::kw_load: return ParseLoad(Inst, PFS);
case lltok::kw_store: return ParseStore(Inst, PFS);
case lltok::kw_cmpxchg: return ParseCmpXchg(Inst, PFS);
case lltok::kw_atomicrmw: return ParseAtomicRMW(Inst, PFS);
case lltok::kw_fence: return ParseFence(Inst, PFS);
case lltok::kw_getelementptr: return ParseGetElementPtr(Inst, PFS);
case lltok::kw_extractvalue: return ParseExtractValue(Inst, PFS);
case lltok::kw_insertvalue: return ParseInsertValue(Inst, PFS);
}
}
/// ParseCmpPredicate - Parse an integer or fp predicate, based on Kind.
bool LLParser::ParseCmpPredicate(unsigned &P, unsigned Opc) {
if (Opc == Instruction::FCmp) {
switch (Lex.getKind()) {
default: return TokError("expected fcmp predicate (e.g. 'oeq')");
case lltok::kw_oeq: P = CmpInst::FCMP_OEQ; break;
case lltok::kw_one: P = CmpInst::FCMP_ONE; break;
case lltok::kw_olt: P = CmpInst::FCMP_OLT; break;
case lltok::kw_ogt: P = CmpInst::FCMP_OGT; break;
case lltok::kw_ole: P = CmpInst::FCMP_OLE; break;
case lltok::kw_oge: P = CmpInst::FCMP_OGE; break;
case lltok::kw_ord: P = CmpInst::FCMP_ORD; break;
case lltok::kw_uno: P = CmpInst::FCMP_UNO; break;
case lltok::kw_ueq: P = CmpInst::FCMP_UEQ; break;
case lltok::kw_une: P = CmpInst::FCMP_UNE; break;
case lltok::kw_ult: P = CmpInst::FCMP_ULT; break;
case lltok::kw_ugt: P = CmpInst::FCMP_UGT; break;
case lltok::kw_ule: P = CmpInst::FCMP_ULE; break;
case lltok::kw_uge: P = CmpInst::FCMP_UGE; break;
case lltok::kw_true: P = CmpInst::FCMP_TRUE; break;
case lltok::kw_false: P = CmpInst::FCMP_FALSE; break;
}
} else {
switch (Lex.getKind()) {
default: return TokError("expected icmp predicate (e.g. 'eq')");
case lltok::kw_eq: P = CmpInst::ICMP_EQ; break;
case lltok::kw_ne: P = CmpInst::ICMP_NE; break;
case lltok::kw_slt: P = CmpInst::ICMP_SLT; break;
case lltok::kw_sgt: P = CmpInst::ICMP_SGT; break;
case lltok::kw_sle: P = CmpInst::ICMP_SLE; break;
case lltok::kw_sge: P = CmpInst::ICMP_SGE; break;
case lltok::kw_ult: P = CmpInst::ICMP_ULT; break;
case lltok::kw_ugt: P = CmpInst::ICMP_UGT; break;
case lltok::kw_ule: P = CmpInst::ICMP_ULE; break;
case lltok::kw_uge: P = CmpInst::ICMP_UGE; break;
}
}
Lex.Lex();
return false;
}
//===----------------------------------------------------------------------===//
// Terminator Instructions.
//===----------------------------------------------------------------------===//
/// ParseRet - Parse a return instruction.
/// ::= 'ret' void (',' !dbg, !1)*
/// ::= 'ret' TypeAndValue (',' !dbg, !1)*
bool LLParser::ParseRet(Instruction *&Inst, BasicBlock *BB,
PerFunctionState &PFS) {
SMLoc TypeLoc = Lex.getLoc();
Type *Ty = nullptr;
if (ParseType(Ty, true /*void allowed*/)) return true;
Type *ResType = PFS.getFunction().getReturnType();
if (Ty->isVoidTy()) {
if (!ResType->isVoidTy())
return Error(TypeLoc, "value doesn't match function result type '" +
getTypeString(ResType) + "'");
Inst = ReturnInst::Create(Context);
return false;
}
Value *RV;
if (ParseValue(Ty, RV, PFS)) return true;
if (ResType != RV->getType())
return Error(TypeLoc, "value doesn't match function result type '" +
getTypeString(ResType) + "'");
Inst = ReturnInst::Create(Context, RV);
return false;
}
/// ParseBr
/// ::= 'br' TypeAndValue
/// ::= 'br' TypeAndValue ',' TypeAndValue ',' TypeAndValue
bool LLParser::ParseBr(Instruction *&Inst, PerFunctionState &PFS) {
LocTy Loc, Loc2;
Value *Op0;
BasicBlock *Op1, *Op2;
if (ParseTypeAndValue(Op0, Loc, PFS)) return true;
if (BasicBlock *BB = dyn_cast<BasicBlock>(Op0)) {
Inst = BranchInst::Create(BB);
return false;
}
if (Op0->getType() != Type::getInt1Ty(Context))
return Error(Loc, "branch condition must have 'i1' type");
if (ParseToken(lltok::comma, "expected ',' after branch condition") ||
ParseTypeAndBasicBlock(Op1, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after true destination") ||
ParseTypeAndBasicBlock(Op2, Loc2, PFS))
return true;
Inst = BranchInst::Create(Op1, Op2, Op0);
return false;
}
/// ParseSwitch
/// Instruction
/// ::= 'switch' TypeAndValue ',' TypeAndValue '[' JumpTable ']'
/// JumpTable
/// ::= (TypeAndValue ',' TypeAndValue)*
bool LLParser::ParseSwitch(Instruction *&Inst, PerFunctionState &PFS) {
LocTy CondLoc, BBLoc;
Value *Cond;
BasicBlock *DefaultBB;
if (ParseTypeAndValue(Cond, CondLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after switch condition") ||
ParseTypeAndBasicBlock(DefaultBB, BBLoc, PFS) ||
ParseToken(lltok::lsquare, "expected '[' with switch table"))
return true;
if (!Cond->getType()->isIntegerTy())
return Error(CondLoc, "switch condition must have integer type");
// Parse the jump table pairs.
SmallPtrSet<Value*, 32> SeenCases;
SmallVector<std::pair<ConstantInt*, BasicBlock*>, 32> Table;
while (Lex.getKind() != lltok::rsquare) {
Value *Constant;
BasicBlock *DestBB;
if (ParseTypeAndValue(Constant, CondLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after case value") ||
ParseTypeAndBasicBlock(DestBB, PFS))
return true;
if (!SeenCases.insert(Constant).second)
return Error(CondLoc, "duplicate case value in switch");
if (!isa<ConstantInt>(Constant))
return Error(CondLoc, "case value is not a constant integer");
Table.push_back(std::make_pair(cast<ConstantInt>(Constant), DestBB));
}
Lex.Lex(); // Eat the ']'.
SwitchInst *SI = SwitchInst::Create(Cond, DefaultBB, Table.size());
for (unsigned i = 0, e = Table.size(); i != e; ++i)
SI->addCase(Table[i].first, Table[i].second);
Inst = SI;
return false;
}
/// ParseIndirectBr
/// Instruction
/// ::= 'indirectbr' TypeAndValue ',' '[' LabelList ']'
bool LLParser::ParseIndirectBr(Instruction *&Inst, PerFunctionState &PFS) {
LocTy AddrLoc;
Value *Address;
if (ParseTypeAndValue(Address, AddrLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after indirectbr address") ||
ParseToken(lltok::lsquare, "expected '[' with indirectbr"))
return true;
if (!Address->getType()->isPointerTy())
return Error(AddrLoc, "indirectbr address must have pointer type");
// Parse the destination list.
SmallVector<BasicBlock*, 16> DestList;
if (Lex.getKind() != lltok::rsquare) {
BasicBlock *DestBB;
if (ParseTypeAndBasicBlock(DestBB, PFS))
return true;
DestList.push_back(DestBB);
while (EatIfPresent(lltok::comma)) {
if (ParseTypeAndBasicBlock(DestBB, PFS))
return true;
DestList.push_back(DestBB);
}
}
if (ParseToken(lltok::rsquare, "expected ']' at end of block list"))
return true;
IndirectBrInst *IBI = IndirectBrInst::Create(Address, DestList.size());
for (unsigned i = 0, e = DestList.size(); i != e; ++i)
IBI->addDestination(DestList[i]);
Inst = IBI;
return false;
}
/// ParseInvoke
/// ::= 'invoke' OptionalCallingConv OptionalAttrs Type Value ParamList
/// OptionalAttrs 'to' TypeAndValue 'unwind' TypeAndValue
bool LLParser::ParseInvoke(Instruction *&Inst, PerFunctionState &PFS) {
LocTy CallLoc = Lex.getLoc();
AttrBuilder RetAttrs, FnAttrs;
std::vector<unsigned> FwdRefAttrGrps;
LocTy NoBuiltinLoc;
unsigned CC;
Type *RetType = nullptr;
LocTy RetTypeLoc;
ValID CalleeID;
SmallVector<ParamInfo, 16> ArgList;
SmallVector<OperandBundleDef, 2> BundleList;
BasicBlock *NormalBB, *UnwindBB;
if (ParseOptionalCallingConv(CC) || ParseOptionalReturnAttrs(RetAttrs) ||
ParseType(RetType, RetTypeLoc, true /*void allowed*/) ||
ParseValID(CalleeID) || ParseParameterList(ArgList, PFS) ||
ParseFnAttributeValuePairs(FnAttrs, FwdRefAttrGrps, false,
NoBuiltinLoc) ||
ParseOptionalOperandBundles(BundleList, PFS) ||
ParseToken(lltok::kw_to, "expected 'to' in invoke") ||
ParseTypeAndBasicBlock(NormalBB, PFS) ||
ParseToken(lltok::kw_unwind, "expected 'unwind' in invoke") ||
ParseTypeAndBasicBlock(UnwindBB, PFS))
return true;
// If RetType is a non-function pointer type, then this is the short syntax
// for the call, which means that RetType is just the return type. Infer the
// rest of the function argument types from the arguments that are present.
FunctionType *Ty = dyn_cast<FunctionType>(RetType);
if (!Ty) {
// Pull out the types of all of the arguments...
std::vector<Type*> ParamTypes;
for (unsigned i = 0, e = ArgList.size(); i != e; ++i)
ParamTypes.push_back(ArgList[i].V->getType());
if (!FunctionType::isValidReturnType(RetType))
return Error(RetTypeLoc, "Invalid result type for LLVM function");
Ty = FunctionType::get(RetType, ParamTypes, false);
}
CalleeID.FTy = Ty;
// Look up the callee.
Value *Callee;
if (ConvertValIDToValue(PointerType::getUnqual(Ty), CalleeID, Callee, &PFS))
return true;
// Set up the Attribute for the function.
SmallVector<AttributeSet, 8> Attrs;
if (RetAttrs.hasAttributes())
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::ReturnIndex,
RetAttrs));
SmallVector<Value*, 8> Args;
// Loop through FunctionType's arguments and ensure they are specified
// correctly. Also, gather any parameter attributes.
FunctionType::param_iterator I = Ty->param_begin();
FunctionType::param_iterator E = Ty->param_end();
for (unsigned i = 0, e = ArgList.size(); i != e; ++i) {
Type *ExpectedTy = nullptr;
if (I != E) {
ExpectedTy = *I++;
} else if (!Ty->isVarArg()) {
return Error(ArgList[i].Loc, "too many arguments specified");
}
if (ExpectedTy && ExpectedTy != ArgList[i].V->getType())
return Error(ArgList[i].Loc, "argument is not of expected type '" +
getTypeString(ExpectedTy) + "'");
Args.push_back(ArgList[i].V);
if (ArgList[i].Attrs.hasAttributes(i + 1)) {
AttrBuilder B(ArgList[i].Attrs, i + 1);
Attrs.push_back(AttributeSet::get(RetType->getContext(), i + 1, B));
}
}
if (I != E)
return Error(CallLoc, "not enough parameters specified for call");
if (FnAttrs.hasAttributes()) {
if (FnAttrs.hasAlignmentAttr())
return Error(CallLoc, "invoke instructions may not have an alignment");
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::FunctionIndex,
FnAttrs));
}
// Finish off the Attribute and check them
AttributeSet PAL = AttributeSet::get(Context, Attrs);
InvokeInst *II =
InvokeInst::Create(Ty, Callee, NormalBB, UnwindBB, Args, BundleList);
II->setCallingConv(CC);
II->setAttributes(PAL);
ForwardRefAttrGroups[II] = FwdRefAttrGrps;
Inst = II;
return false;
}
/// ParseResume
/// ::= 'resume' TypeAndValue
bool LLParser::ParseResume(Instruction *&Inst, PerFunctionState &PFS) {
Value *Exn; LocTy ExnLoc;
if (ParseTypeAndValue(Exn, ExnLoc, PFS))
return true;
ResumeInst *RI = ResumeInst::Create(Exn);
Inst = RI;
return false;
}
bool LLParser::ParseExceptionArgs(SmallVectorImpl<Value *> &Args,
PerFunctionState &PFS) {
if (ParseToken(lltok::lsquare, "expected '[' in catchpad/cleanuppad"))
return true;
while (Lex.getKind() != lltok::rsquare) {
// If this isn't the first argument, we need a comma.
if (!Args.empty() &&
ParseToken(lltok::comma, "expected ',' in argument list"))
return true;
// Parse the argument.
LocTy ArgLoc;
Type *ArgTy = nullptr;
if (ParseType(ArgTy, ArgLoc))
return true;
Value *V;
if (ArgTy->isMetadataTy()) {
if (ParseMetadataAsValue(V, PFS))
return true;
} else {
if (ParseValue(ArgTy, V, PFS))
return true;
}
Args.push_back(V);
}
Lex.Lex(); // Lex the ']'.
return false;
}
/// ParseCleanupRet
/// ::= 'cleanupret' from Value unwind ('to' 'caller' | TypeAndValue)
bool LLParser::ParseCleanupRet(Instruction *&Inst, PerFunctionState &PFS) {
Value *CleanupPad = nullptr;
if (ParseToken(lltok::kw_from, "expected 'from' after cleanupret"))
return true;
if (ParseValue(Type::getTokenTy(Context), CleanupPad, PFS))
return true;
if (ParseToken(lltok::kw_unwind, "expected 'unwind' in cleanupret"))
return true;
BasicBlock *UnwindBB = nullptr;
if (Lex.getKind() == lltok::kw_to) {
Lex.Lex();
if (ParseToken(lltok::kw_caller, "expected 'caller' in cleanupret"))
return true;
} else {
if (ParseTypeAndBasicBlock(UnwindBB, PFS)) {
return true;
}
}
Inst = CleanupReturnInst::Create(CleanupPad, UnwindBB);
return false;
}
/// ParseCatchRet
/// ::= 'catchret' from Parent Value 'to' TypeAndValue
bool LLParser::ParseCatchRet(Instruction *&Inst, PerFunctionState &PFS) {
Value *CatchPad = nullptr;
if (ParseToken(lltok::kw_from, "expected 'from' after catchret"))
return true;
if (ParseValue(Type::getTokenTy(Context), CatchPad, PFS))
return true;
BasicBlock *BB;
if (ParseToken(lltok::kw_to, "expected 'to' in catchret") ||
ParseTypeAndBasicBlock(BB, PFS))
return true;
Inst = CatchReturnInst::Create(CatchPad, BB);
return false;
}
/// ParseCatchSwitch
/// ::= 'catchswitch' within Parent
bool LLParser::ParseCatchSwitch(Instruction *&Inst, PerFunctionState &PFS) {
Value *ParentPad;
LocTy BBLoc;
if (ParseToken(lltok::kw_within, "expected 'within' after catchswitch"))
return true;
if (Lex.getKind() != lltok::kw_none && Lex.getKind() != lltok::LocalVar &&
Lex.getKind() != lltok::LocalVarID)
return TokError("expected scope value for catchswitch");
if (ParseValue(Type::getTokenTy(Context), ParentPad, PFS))
return true;
if (ParseToken(lltok::lsquare, "expected '[' with catchswitch labels"))
return true;
SmallVector<BasicBlock *, 32> Table;
do {
BasicBlock *DestBB;
if (ParseTypeAndBasicBlock(DestBB, PFS))
return true;
Table.push_back(DestBB);
} while (EatIfPresent(lltok::comma));
if (ParseToken(lltok::rsquare, "expected ']' after catchswitch labels"))
return true;
if (ParseToken(lltok::kw_unwind,
"expected 'unwind' after catchswitch scope"))
return true;
BasicBlock *UnwindBB = nullptr;
if (EatIfPresent(lltok::kw_to)) {
if (ParseToken(lltok::kw_caller, "expected 'caller' in catchswitch"))
return true;
} else {
if (ParseTypeAndBasicBlock(UnwindBB, PFS))
return true;
}
auto *CatchSwitch =
CatchSwitchInst::Create(ParentPad, UnwindBB, Table.size());
for (BasicBlock *DestBB : Table)
CatchSwitch->addHandler(DestBB);
Inst = CatchSwitch;
return false;
}
/// ParseCatchPad
/// ::= 'catchpad' ParamList 'to' TypeAndValue 'unwind' TypeAndValue
bool LLParser::ParseCatchPad(Instruction *&Inst, PerFunctionState &PFS) {
Value *CatchSwitch = nullptr;
if (ParseToken(lltok::kw_within, "expected 'within' after catchpad"))
return true;
if (Lex.getKind() != lltok::LocalVar && Lex.getKind() != lltok::LocalVarID)
return TokError("expected scope value for catchpad");
if (ParseValue(Type::getTokenTy(Context), CatchSwitch, PFS))
return true;
SmallVector<Value *, 8> Args;
if (ParseExceptionArgs(Args, PFS))
return true;
Inst = CatchPadInst::Create(CatchSwitch, Args);
return false;
}
/// ParseCleanupPad
/// ::= 'cleanuppad' within Parent ParamList
bool LLParser::ParseCleanupPad(Instruction *&Inst, PerFunctionState &PFS) {
Value *ParentPad = nullptr;
if (ParseToken(lltok::kw_within, "expected 'within' after cleanuppad"))
return true;
if (Lex.getKind() != lltok::kw_none && Lex.getKind() != lltok::LocalVar &&
Lex.getKind() != lltok::LocalVarID)
return TokError("expected scope value for cleanuppad");
if (ParseValue(Type::getTokenTy(Context), ParentPad, PFS))
return true;
SmallVector<Value *, 8> Args;
if (ParseExceptionArgs(Args, PFS))
return true;
Inst = CleanupPadInst::Create(ParentPad, Args);
return false;
}
//===----------------------------------------------------------------------===//
// Binary Operators.
//===----------------------------------------------------------------------===//
/// ParseArithmetic
/// ::= ArithmeticOps TypeAndValue ',' Value
///
/// If OperandType is 0, then any FP or integer operand is allowed. If it is 1,
/// then any integer operand is allowed, if it is 2, any fp operand is allowed.
bool LLParser::ParseArithmetic(Instruction *&Inst, PerFunctionState &PFS,
unsigned Opc, unsigned OperandType) {
LocTy Loc; Value *LHS, *RHS;
if (ParseTypeAndValue(LHS, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' in arithmetic operation") ||
ParseValue(LHS->getType(), RHS, PFS))
return true;
bool Valid;
switch (OperandType) {
default: llvm_unreachable("Unknown operand type!");
case 0: // int or FP.
Valid = LHS->getType()->isIntOrIntVectorTy() ||
LHS->getType()->isFPOrFPVectorTy();
break;
case 1: Valid = LHS->getType()->isIntOrIntVectorTy(); break;
case 2: Valid = LHS->getType()->isFPOrFPVectorTy(); break;
}
if (!Valid)
return Error(Loc, "invalid operand type for instruction");
Inst = BinaryOperator::Create((Instruction::BinaryOps)Opc, LHS, RHS);
return false;
}
/// ParseLogical
/// ::= ArithmeticOps TypeAndValue ',' Value {
bool LLParser::ParseLogical(Instruction *&Inst, PerFunctionState &PFS,
unsigned Opc) {
LocTy Loc; Value *LHS, *RHS;
if (ParseTypeAndValue(LHS, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' in logical operation") ||
ParseValue(LHS->getType(), RHS, PFS))
return true;
if (!LHS->getType()->isIntOrIntVectorTy())
return Error(Loc,"instruction requires integer or integer vector operands");
Inst = BinaryOperator::Create((Instruction::BinaryOps)Opc, LHS, RHS);
return false;
}
/// ParseCompare
/// ::= 'icmp' IPredicates TypeAndValue ',' Value
/// ::= 'fcmp' FPredicates TypeAndValue ',' Value
bool LLParser::ParseCompare(Instruction *&Inst, PerFunctionState &PFS,
unsigned Opc) {
// Parse the integer/fp comparison predicate.
LocTy Loc;
unsigned Pred;
Value *LHS, *RHS;
if (ParseCmpPredicate(Pred, Opc) ||
ParseTypeAndValue(LHS, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after compare value") ||
ParseValue(LHS->getType(), RHS, PFS))
return true;
if (Opc == Instruction::FCmp) {
if (!LHS->getType()->isFPOrFPVectorTy())
return Error(Loc, "fcmp requires floating point operands");
Inst = new FCmpInst(CmpInst::Predicate(Pred), LHS, RHS);
} else {
assert(Opc == Instruction::ICmp && "Unknown opcode for CmpInst!");
if (!LHS->getType()->isIntOrIntVectorTy() &&
!LHS->getType()->getScalarType()->isPointerTy())
return Error(Loc, "icmp requires integer operands");
Inst = new ICmpInst(CmpInst::Predicate(Pred), LHS, RHS);
}
return false;
}
//===----------------------------------------------------------------------===//
// Other Instructions.
//===----------------------------------------------------------------------===//
/// ParseCast
/// ::= CastOpc TypeAndValue 'to' Type
bool LLParser::ParseCast(Instruction *&Inst, PerFunctionState &PFS,
unsigned Opc) {
LocTy Loc;
Value *Op;
Type *DestTy = nullptr;
if (ParseTypeAndValue(Op, Loc, PFS) ||
ParseToken(lltok::kw_to, "expected 'to' after cast value") ||
ParseType(DestTy))
return true;
if (!CastInst::castIsValid((Instruction::CastOps)Opc, Op, DestTy)) {
CastInst::castIsValid((Instruction::CastOps)Opc, Op, DestTy);
return Error(Loc, "invalid cast opcode for cast from '" +
getTypeString(Op->getType()) + "' to '" +
getTypeString(DestTy) + "'");
}
Inst = CastInst::Create((Instruction::CastOps)Opc, Op, DestTy);
return false;
}
/// ParseSelect
/// ::= 'select' TypeAndValue ',' TypeAndValue ',' TypeAndValue
bool LLParser::ParseSelect(Instruction *&Inst, PerFunctionState &PFS) {
LocTy Loc;
Value *Op0, *Op1, *Op2;
if (ParseTypeAndValue(Op0, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after select condition") ||
ParseTypeAndValue(Op1, PFS) ||
ParseToken(lltok::comma, "expected ',' after select value") ||
ParseTypeAndValue(Op2, PFS))
return true;
if (const char *Reason = SelectInst::areInvalidOperands(Op0, Op1, Op2))
return Error(Loc, Reason);
Inst = SelectInst::Create(Op0, Op1, Op2);
return false;
}
/// ParseVA_Arg
/// ::= 'va_arg' TypeAndValue ',' Type
bool LLParser::ParseVA_Arg(Instruction *&Inst, PerFunctionState &PFS) {
Value *Op;
Type *EltTy = nullptr;
LocTy TypeLoc;
if (ParseTypeAndValue(Op, PFS) ||
ParseToken(lltok::comma, "expected ',' after vaarg operand") ||
ParseType(EltTy, TypeLoc))
return true;
if (!EltTy->isFirstClassType())
return Error(TypeLoc, "va_arg requires operand with first class type");
Inst = new VAArgInst(Op, EltTy);
return false;
}
/// ParseExtractElement
/// ::= 'extractelement' TypeAndValue ',' TypeAndValue
bool LLParser::ParseExtractElement(Instruction *&Inst, PerFunctionState &PFS) {
LocTy Loc;
Value *Op0, *Op1;
if (ParseTypeAndValue(Op0, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after extract value") ||
ParseTypeAndValue(Op1, PFS))
return true;
if (!ExtractElementInst::isValidOperands(Op0, Op1))
return Error(Loc, "invalid extractelement operands");
Inst = ExtractElementInst::Create(Op0, Op1);
return false;
}
/// ParseInsertElement
/// ::= 'insertelement' TypeAndValue ',' TypeAndValue ',' TypeAndValue
bool LLParser::ParseInsertElement(Instruction *&Inst, PerFunctionState &PFS) {
LocTy Loc;
Value *Op0, *Op1, *Op2;
if (ParseTypeAndValue(Op0, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after insertelement value") ||
ParseTypeAndValue(Op1, PFS) ||
ParseToken(lltok::comma, "expected ',' after insertelement value") ||
ParseTypeAndValue(Op2, PFS))
return true;
if (!InsertElementInst::isValidOperands(Op0, Op1, Op2))
return Error(Loc, "invalid insertelement operands");
Inst = InsertElementInst::Create(Op0, Op1, Op2);
return false;
}
/// ParseShuffleVector
/// ::= 'shufflevector' TypeAndValue ',' TypeAndValue ',' TypeAndValue
bool LLParser::ParseShuffleVector(Instruction *&Inst, PerFunctionState &PFS) {
LocTy Loc;
Value *Op0, *Op1, *Op2;
if (ParseTypeAndValue(Op0, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after shuffle mask") ||
ParseTypeAndValue(Op1, PFS) ||
ParseToken(lltok::comma, "expected ',' after shuffle value") ||
ParseTypeAndValue(Op2, PFS))
return true;
if (!ShuffleVectorInst::isValidOperands(Op0, Op1, Op2))
return Error(Loc, "invalid shufflevector operands");
Inst = new ShuffleVectorInst(Op0, Op1, Op2);
return false;
}
/// ParsePHI
/// ::= 'phi' Type '[' Value ',' Value ']' (',' '[' Value ',' Value ']')*
int LLParser::ParsePHI(Instruction *&Inst, PerFunctionState &PFS) {
Type *Ty = nullptr; LocTy TypeLoc;
Value *Op0, *Op1;
if (ParseType(Ty, TypeLoc) ||
ParseToken(lltok::lsquare, "expected '[' in phi value list") ||
ParseValue(Ty, Op0, PFS) ||
ParseToken(lltok::comma, "expected ',' after insertelement value") ||
ParseValue(Type::getLabelTy(Context), Op1, PFS) ||
ParseToken(lltok::rsquare, "expected ']' in phi value list"))
return true;
bool AteExtraComma = false;
SmallVector<std::pair<Value*, BasicBlock*>, 16> PHIVals;
while (true) {
PHIVals.push_back(std::make_pair(Op0, cast<BasicBlock>(Op1)));
if (!EatIfPresent(lltok::comma))
break;
if (Lex.getKind() == lltok::MetadataVar) {
AteExtraComma = true;
break;
}
if (ParseToken(lltok::lsquare, "expected '[' in phi value list") ||
ParseValue(Ty, Op0, PFS) ||
ParseToken(lltok::comma, "expected ',' after insertelement value") ||
ParseValue(Type::getLabelTy(Context), Op1, PFS) ||
ParseToken(lltok::rsquare, "expected ']' in phi value list"))
return true;
}
if (!Ty->isFirstClassType())
return Error(TypeLoc, "phi node must have first class type");
PHINode *PN = PHINode::Create(Ty, PHIVals.size());
for (unsigned i = 0, e = PHIVals.size(); i != e; ++i)
PN->addIncoming(PHIVals[i].first, PHIVals[i].second);
Inst = PN;
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseLandingPad
/// ::= 'landingpad' Type 'personality' TypeAndValue 'cleanup'? Clause+
/// Clause
/// ::= 'catch' TypeAndValue
/// ::= 'filter'
/// ::= 'filter' TypeAndValue ( ',' TypeAndValue )*
bool LLParser::ParseLandingPad(Instruction *&Inst, PerFunctionState &PFS) {
Type *Ty = nullptr; LocTy TyLoc;
if (ParseType(Ty, TyLoc))
return true;
std::unique_ptr<LandingPadInst> LP(LandingPadInst::Create(Ty, 0));
LP->setCleanup(EatIfPresent(lltok::kw_cleanup));
while (Lex.getKind() == lltok::kw_catch || Lex.getKind() == lltok::kw_filter){
LandingPadInst::ClauseType CT;
if (EatIfPresent(lltok::kw_catch))
CT = LandingPadInst::Catch;
else if (EatIfPresent(lltok::kw_filter))
CT = LandingPadInst::Filter;
else
return TokError("expected 'catch' or 'filter' clause type");
Value *V;
LocTy VLoc;
if (ParseTypeAndValue(V, VLoc, PFS))
return true;
// A 'catch' type expects a non-array constant. A filter clause expects an
// array constant.
if (CT == LandingPadInst::Catch) {
if (isa<ArrayType>(V->getType()))
Error(VLoc, "'catch' clause has an invalid type");
} else {
if (!isa<ArrayType>(V->getType()))
Error(VLoc, "'filter' clause has an invalid type");
}
Constant *CV = dyn_cast<Constant>(V);
if (!CV)
return Error(VLoc, "clause argument must be a constant");
LP->addClause(CV);
}
Inst = LP.release();
return false;
}
/// ParseCall
/// ::= 'call' OptionalFastMathFlags OptionalCallingConv
/// OptionalAttrs Type Value ParameterList OptionalAttrs
/// ::= 'tail' 'call' OptionalFastMathFlags OptionalCallingConv
/// OptionalAttrs Type Value ParameterList OptionalAttrs
/// ::= 'musttail' 'call' OptionalFastMathFlags OptionalCallingConv
/// OptionalAttrs Type Value ParameterList OptionalAttrs
/// ::= 'notail' 'call' OptionalFastMathFlags OptionalCallingConv
/// OptionalAttrs Type Value ParameterList OptionalAttrs
bool LLParser::ParseCall(Instruction *&Inst, PerFunctionState &PFS,
CallInst::TailCallKind TCK) {
AttrBuilder RetAttrs, FnAttrs;
std::vector<unsigned> FwdRefAttrGrps;
LocTy BuiltinLoc;
unsigned CC;
Type *RetType = nullptr;
LocTy RetTypeLoc;
ValID CalleeID;
SmallVector<ParamInfo, 16> ArgList;
SmallVector<OperandBundleDef, 2> BundleList;
LocTy CallLoc = Lex.getLoc();
if (TCK != CallInst::TCK_None &&
ParseToken(lltok::kw_call,
"expected 'tail call', 'musttail call', or 'notail call'"))
return true;
FastMathFlags FMF = EatFastMathFlagsIfPresent();
if (ParseOptionalCallingConv(CC) || ParseOptionalReturnAttrs(RetAttrs) ||
ParseType(RetType, RetTypeLoc, true /*void allowed*/) ||
ParseValID(CalleeID) ||
ParseParameterList(ArgList, PFS, TCK == CallInst::TCK_MustTail,
PFS.getFunction().isVarArg()) ||
ParseFnAttributeValuePairs(FnAttrs, FwdRefAttrGrps, false, BuiltinLoc) ||
ParseOptionalOperandBundles(BundleList, PFS))
return true;
if (FMF.any() && !RetType->isFPOrFPVectorTy())
return Error(CallLoc, "fast-math-flags specified for call without "
"floating-point scalar or vector return type");
// If RetType is a non-function pointer type, then this is the short syntax
// for the call, which means that RetType is just the return type. Infer the
// rest of the function argument types from the arguments that are present.
FunctionType *Ty = dyn_cast<FunctionType>(RetType);
if (!Ty) {
// Pull out the types of all of the arguments...
std::vector<Type*> ParamTypes;
for (unsigned i = 0, e = ArgList.size(); i != e; ++i)
ParamTypes.push_back(ArgList[i].V->getType());
if (!FunctionType::isValidReturnType(RetType))
return Error(RetTypeLoc, "Invalid result type for LLVM function");
Ty = FunctionType::get(RetType, ParamTypes, false);
}
CalleeID.FTy = Ty;
// Look up the callee.
Value *Callee;
if (ConvertValIDToValue(PointerType::getUnqual(Ty), CalleeID, Callee, &PFS))
return true;
// Set up the Attribute for the function.
SmallVector<AttributeSet, 8> Attrs;
if (RetAttrs.hasAttributes())
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::ReturnIndex,
RetAttrs));
SmallVector<Value*, 8> Args;
// Loop through FunctionType's arguments and ensure they are specified
// correctly. Also, gather any parameter attributes.
FunctionType::param_iterator I = Ty->param_begin();
FunctionType::param_iterator E = Ty->param_end();
for (unsigned i = 0, e = ArgList.size(); i != e; ++i) {
Type *ExpectedTy = nullptr;
if (I != E) {
ExpectedTy = *I++;
} else if (!Ty->isVarArg()) {
return Error(ArgList[i].Loc, "too many arguments specified");
}
if (ExpectedTy && ExpectedTy != ArgList[i].V->getType())
return Error(ArgList[i].Loc, "argument is not of expected type '" +
getTypeString(ExpectedTy) + "'");
Args.push_back(ArgList[i].V);
if (ArgList[i].Attrs.hasAttributes(i + 1)) {
AttrBuilder B(ArgList[i].Attrs, i + 1);
Attrs.push_back(AttributeSet::get(RetType->getContext(), i + 1, B));
}
}
if (I != E)
return Error(CallLoc, "not enough parameters specified for call");
if (FnAttrs.hasAttributes()) {
if (FnAttrs.hasAlignmentAttr())
return Error(CallLoc, "call instructions may not have an alignment");
Attrs.push_back(AttributeSet::get(RetType->getContext(),
AttributeSet::FunctionIndex,
FnAttrs));
}
// Finish off the Attribute and check them
AttributeSet PAL = AttributeSet::get(Context, Attrs);
CallInst *CI = CallInst::Create(Ty, Callee, Args, BundleList);
CI->setTailCallKind(TCK);
CI->setCallingConv(CC);
if (FMF.any())
CI->setFastMathFlags(FMF);
CI->setAttributes(PAL);
ForwardRefAttrGroups[CI] = FwdRefAttrGrps;
Inst = CI;
return false;
}
//===----------------------------------------------------------------------===//
// Memory Instructions.
//===----------------------------------------------------------------------===//
/// ParseAlloc
/// ::= 'alloca' 'inalloca'? 'swifterror'? Type (',' TypeAndValue)?
/// (',' 'align' i32)?
int LLParser::ParseAlloc(Instruction *&Inst, PerFunctionState &PFS) {
Value *Size = nullptr;
LocTy SizeLoc, TyLoc;
unsigned Alignment = 0;
Type *Ty = nullptr;
bool IsInAlloca = EatIfPresent(lltok::kw_inalloca);
bool IsSwiftError = EatIfPresent(lltok::kw_swifterror);
if (ParseType(Ty, TyLoc)) return true;
if (Ty->isFunctionTy() || !PointerType::isValidElementType(Ty))
return Error(TyLoc, "invalid type for alloca");
bool AteExtraComma = false;
if (EatIfPresent(lltok::comma)) {
if (Lex.getKind() == lltok::kw_align) {
if (ParseOptionalAlignment(Alignment)) return true;
} else if (Lex.getKind() == lltok::MetadataVar) {
AteExtraComma = true;
} else {
if (ParseTypeAndValue(Size, SizeLoc, PFS) ||
ParseOptionalCommaAlign(Alignment, AteExtraComma))
return true;
}
}
if (Size && !Size->getType()->isIntegerTy())
return Error(SizeLoc, "element count must have integer type");
AllocaInst *AI = new AllocaInst(Ty, Size, Alignment);
AI->setUsedWithInAlloca(IsInAlloca);
AI->setSwiftError(IsSwiftError);
Inst = AI;
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseLoad
/// ::= 'load' 'volatile'? TypeAndValue (',' 'align' i32)?
/// ::= 'load' 'atomic' 'volatile'? TypeAndValue
/// 'singlethread'? AtomicOrdering (',' 'align' i32)?
int LLParser::ParseLoad(Instruction *&Inst, PerFunctionState &PFS) {
Value *Val; LocTy Loc;
unsigned Alignment = 0;
bool AteExtraComma = false;
bool isAtomic = false;
AtomicOrdering Ordering = AtomicOrdering::NotAtomic;
SynchronizationScope Scope = CrossThread;
if (Lex.getKind() == lltok::kw_atomic) {
isAtomic = true;
Lex.Lex();
}
bool isVolatile = false;
if (Lex.getKind() == lltok::kw_volatile) {
isVolatile = true;
Lex.Lex();
}
Type *Ty;
LocTy ExplicitTypeLoc = Lex.getLoc();
if (ParseType(Ty) ||
ParseToken(lltok::comma, "expected comma after load's type") ||
ParseTypeAndValue(Val, Loc, PFS) ||
ParseScopeAndOrdering(isAtomic, Scope, Ordering) ||
ParseOptionalCommaAlign(Alignment, AteExtraComma))
return true;
if (!Val->getType()->isPointerTy() || !Ty->isFirstClassType())
return Error(Loc, "load operand must be a pointer to a first class type");
if (isAtomic && !Alignment)
return Error(Loc, "atomic load must have explicit non-zero alignment");
if (Ordering == AtomicOrdering::Release ||
Ordering == AtomicOrdering::AcquireRelease)
return Error(Loc, "atomic load cannot use Release ordering");
if (Ty != cast<PointerType>(Val->getType())->getElementType())
return Error(ExplicitTypeLoc,
"explicit pointee type doesn't match operand's pointee type");
Inst = new LoadInst(Ty, Val, "", isVolatile, Alignment, Ordering, Scope);
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseStore
/// ::= 'store' 'volatile'? TypeAndValue ',' TypeAndValue (',' 'align' i32)?
/// ::= 'store' 'atomic' 'volatile'? TypeAndValue ',' TypeAndValue
/// 'singlethread'? AtomicOrdering (',' 'align' i32)?
int LLParser::ParseStore(Instruction *&Inst, PerFunctionState &PFS) {
Value *Val, *Ptr; LocTy Loc, PtrLoc;
unsigned Alignment = 0;
bool AteExtraComma = false;
bool isAtomic = false;
AtomicOrdering Ordering = AtomicOrdering::NotAtomic;
SynchronizationScope Scope = CrossThread;
if (Lex.getKind() == lltok::kw_atomic) {
isAtomic = true;
Lex.Lex();
}
bool isVolatile = false;
if (Lex.getKind() == lltok::kw_volatile) {
isVolatile = true;
Lex.Lex();
}
if (ParseTypeAndValue(Val, Loc, PFS) ||
ParseToken(lltok::comma, "expected ',' after store operand") ||
ParseTypeAndValue(Ptr, PtrLoc, PFS) ||
ParseScopeAndOrdering(isAtomic, Scope, Ordering) ||
ParseOptionalCommaAlign(Alignment, AteExtraComma))
return true;
if (!Ptr->getType()->isPointerTy())
return Error(PtrLoc, "store operand must be a pointer");
if (!Val->getType()->isFirstClassType())
return Error(Loc, "store operand must be a first class value");
if (cast<PointerType>(Ptr->getType())->getElementType() != Val->getType())
return Error(Loc, "stored value and pointer type do not match");
if (isAtomic && !Alignment)
return Error(Loc, "atomic store must have explicit non-zero alignment");
if (Ordering == AtomicOrdering::Acquire ||
Ordering == AtomicOrdering::AcquireRelease)
return Error(Loc, "atomic store cannot use Acquire ordering");
Inst = new StoreInst(Val, Ptr, isVolatile, Alignment, Ordering, Scope);
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseCmpXchg
/// ::= 'cmpxchg' 'weak'? 'volatile'? TypeAndValue ',' TypeAndValue ','
/// TypeAndValue 'singlethread'? AtomicOrdering AtomicOrdering
int LLParser::ParseCmpXchg(Instruction *&Inst, PerFunctionState &PFS) {
Value *Ptr, *Cmp, *New; LocTy PtrLoc, CmpLoc, NewLoc;
bool AteExtraComma = false;
AtomicOrdering SuccessOrdering = AtomicOrdering::NotAtomic;
AtomicOrdering FailureOrdering = AtomicOrdering::NotAtomic;
SynchronizationScope Scope = CrossThread;
bool isVolatile = false;
bool isWeak = false;
if (EatIfPresent(lltok::kw_weak))
isWeak = true;
if (EatIfPresent(lltok::kw_volatile))
isVolatile = true;
if (ParseTypeAndValue(Ptr, PtrLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after cmpxchg address") ||
ParseTypeAndValue(Cmp, CmpLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after cmpxchg cmp operand") ||
ParseTypeAndValue(New, NewLoc, PFS) ||
ParseScopeAndOrdering(true /*Always atomic*/, Scope, SuccessOrdering) ||
ParseOrdering(FailureOrdering))
return true;
if (SuccessOrdering == AtomicOrdering::Unordered ||
FailureOrdering == AtomicOrdering::Unordered)
return TokError("cmpxchg cannot be unordered");
if (isStrongerThan(FailureOrdering, SuccessOrdering))
return TokError("cmpxchg failure argument shall be no stronger than the "
"success argument");
if (FailureOrdering == AtomicOrdering::Release ||
FailureOrdering == AtomicOrdering::AcquireRelease)
return TokError(
"cmpxchg failure ordering cannot include release semantics");
if (!Ptr->getType()->isPointerTy())
return Error(PtrLoc, "cmpxchg operand must be a pointer");
if (cast<PointerType>(Ptr->getType())->getElementType() != Cmp->getType())
return Error(CmpLoc, "compare value and pointer type do not match");
if (cast<PointerType>(Ptr->getType())->getElementType() != New->getType())
return Error(NewLoc, "new value and pointer type do not match");
if (!New->getType()->isFirstClassType())
return Error(NewLoc, "cmpxchg operand must be a first class value");
AtomicCmpXchgInst *CXI = new AtomicCmpXchgInst(
Ptr, Cmp, New, SuccessOrdering, FailureOrdering, Scope);
CXI->setVolatile(isVolatile);
CXI->setWeak(isWeak);
Inst = CXI;
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseAtomicRMW
/// ::= 'atomicrmw' 'volatile'? BinOp TypeAndValue ',' TypeAndValue
/// 'singlethread'? AtomicOrdering
int LLParser::ParseAtomicRMW(Instruction *&Inst, PerFunctionState &PFS) {
Value *Ptr, *Val; LocTy PtrLoc, ValLoc;
bool AteExtraComma = false;
AtomicOrdering Ordering = AtomicOrdering::NotAtomic;
SynchronizationScope Scope = CrossThread;
bool isVolatile = false;
AtomicRMWInst::BinOp Operation;
if (EatIfPresent(lltok::kw_volatile))
isVolatile = true;
switch (Lex.getKind()) {
default: return TokError("expected binary operation in atomicrmw");
case lltok::kw_xchg: Operation = AtomicRMWInst::Xchg; break;
case lltok::kw_add: Operation = AtomicRMWInst::Add; break;
case lltok::kw_sub: Operation = AtomicRMWInst::Sub; break;
case lltok::kw_and: Operation = AtomicRMWInst::And; break;
case lltok::kw_nand: Operation = AtomicRMWInst::Nand; break;
case lltok::kw_or: Operation = AtomicRMWInst::Or; break;
case lltok::kw_xor: Operation = AtomicRMWInst::Xor; break;
case lltok::kw_max: Operation = AtomicRMWInst::Max; break;
case lltok::kw_min: Operation = AtomicRMWInst::Min; break;
case lltok::kw_umax: Operation = AtomicRMWInst::UMax; break;
case lltok::kw_umin: Operation = AtomicRMWInst::UMin; break;
}
Lex.Lex(); // Eat the operation.
if (ParseTypeAndValue(Ptr, PtrLoc, PFS) ||
ParseToken(lltok::comma, "expected ',' after atomicrmw address") ||
ParseTypeAndValue(Val, ValLoc, PFS) ||
ParseScopeAndOrdering(true /*Always atomic*/, Scope, Ordering))
return true;
if (Ordering == AtomicOrdering::Unordered)
return TokError("atomicrmw cannot be unordered");
if (!Ptr->getType()->isPointerTy())
return Error(PtrLoc, "atomicrmw operand must be a pointer");
if (cast<PointerType>(Ptr->getType())->getElementType() != Val->getType())
return Error(ValLoc, "atomicrmw value and pointer type do not match");
if (!Val->getType()->isIntegerTy())
return Error(ValLoc, "atomicrmw operand must be an integer");
unsigned Size = Val->getType()->getPrimitiveSizeInBits();
if (Size < 8 || (Size & (Size - 1)))
return Error(ValLoc, "atomicrmw operand must be power-of-two byte-sized"
" integer");
AtomicRMWInst *RMWI =
new AtomicRMWInst(Operation, Ptr, Val, Ordering, Scope);
RMWI->setVolatile(isVolatile);
Inst = RMWI;
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseFence
/// ::= 'fence' 'singlethread'? AtomicOrdering
int LLParser::ParseFence(Instruction *&Inst, PerFunctionState &PFS) {
AtomicOrdering Ordering = AtomicOrdering::NotAtomic;
SynchronizationScope Scope = CrossThread;
if (ParseScopeAndOrdering(true /*Always atomic*/, Scope, Ordering))
return true;
if (Ordering == AtomicOrdering::Unordered)
return TokError("fence cannot be unordered");
if (Ordering == AtomicOrdering::Monotonic)
return TokError("fence cannot be monotonic");
Inst = new FenceInst(Context, Ordering, Scope);
return InstNormal;
}
/// ParseGetElementPtr
/// ::= 'getelementptr' 'inbounds'? TypeAndValue (',' TypeAndValue)*
int LLParser::ParseGetElementPtr(Instruction *&Inst, PerFunctionState &PFS) {
Value *Ptr = nullptr;
Value *Val = nullptr;
LocTy Loc, EltLoc;
bool InBounds = EatIfPresent(lltok::kw_inbounds);
Type *Ty = nullptr;
LocTy ExplicitTypeLoc = Lex.getLoc();
if (ParseType(Ty) ||
ParseToken(lltok::comma, "expected comma after getelementptr's type") ||
ParseTypeAndValue(Ptr, Loc, PFS))
return true;
Type *BaseType = Ptr->getType();
PointerType *BasePointerType = dyn_cast<PointerType>(BaseType->getScalarType());
if (!BasePointerType)
return Error(Loc, "base of getelementptr must be a pointer");
if (Ty != BasePointerType->getElementType())
return Error(ExplicitTypeLoc,
"explicit pointee type doesn't match operand's pointee type");
SmallVector<Value*, 16> Indices;
bool AteExtraComma = false;
// GEP returns a vector of pointers if at least one of parameters is a vector.
// All vector parameters should have the same vector width.
unsigned GEPWidth = BaseType->isVectorTy() ?
BaseType->getVectorNumElements() : 0;
while (EatIfPresent(lltok::comma)) {
if (Lex.getKind() == lltok::MetadataVar) {
AteExtraComma = true;
break;
}
if (ParseTypeAndValue(Val, EltLoc, PFS)) return true;
if (!Val->getType()->getScalarType()->isIntegerTy())
return Error(EltLoc, "getelementptr index must be an integer");
if (Val->getType()->isVectorTy()) {
unsigned ValNumEl = Val->getType()->getVectorNumElements();
if (GEPWidth && GEPWidth != ValNumEl)
return Error(EltLoc,
"getelementptr vector index has a wrong number of elements");
GEPWidth = ValNumEl;
}
Indices.push_back(Val);
}
SmallPtrSet<Type*, 4> Visited;
if (!Indices.empty() && !Ty->isSized(&Visited))
return Error(Loc, "base element of getelementptr must be sized");
if (!GetElementPtrInst::getIndexedType(Ty, Indices))
return Error(Loc, "invalid getelementptr indices");
Inst = GetElementPtrInst::Create(Ty, Ptr, Indices);
if (InBounds)
cast<GetElementPtrInst>(Inst)->setIsInBounds(true);
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseExtractValue
/// ::= 'extractvalue' TypeAndValue (',' uint32)+
int LLParser::ParseExtractValue(Instruction *&Inst, PerFunctionState &PFS) {
Value *Val; LocTy Loc;
SmallVector<unsigned, 4> Indices;
bool AteExtraComma;
if (ParseTypeAndValue(Val, Loc, PFS) ||
ParseIndexList(Indices, AteExtraComma))
return true;
if (!Val->getType()->isAggregateType())
return Error(Loc, "extractvalue operand must be aggregate type");
if (!ExtractValueInst::getIndexedType(Val->getType(), Indices))
return Error(Loc, "invalid indices for extractvalue");
Inst = ExtractValueInst::Create(Val, Indices);
return AteExtraComma ? InstExtraComma : InstNormal;
}
/// ParseInsertValue
/// ::= 'insertvalue' TypeAndValue ',' TypeAndValue (',' uint32)+
int LLParser::ParseInsertValue(Instruction *&Inst, PerFunctionState &PFS) {
Value *Val0, *Val1; LocTy Loc0, Loc1;
SmallVector<unsigned, 4> Indices;
bool AteExtraComma;
if (ParseTypeAndValue(Val0, Loc0, PFS) ||
ParseToken(lltok::comma, "expected comma after insertvalue operand") ||
ParseTypeAndValue(Val1, Loc1, PFS) ||
ParseIndexList(Indices, AteExtraComma))
return true;
if (!Val0->getType()->isAggregateType())
return Error(Loc0, "insertvalue operand must be aggregate type");
Type *IndexedType = ExtractValueInst::getIndexedType(Val0->getType(), Indices);
if (!IndexedType)
return Error(Loc0, "invalid indices for insertvalue");
if (IndexedType != Val1->getType())
return Error(Loc1, "insertvalue operand and field disagree in type: '" +
getTypeString(Val1->getType()) + "' instead of '" +
getTypeString(IndexedType) + "'");
Inst = InsertValueInst::Create(Val0, Val1, Indices);
return AteExtraComma ? InstExtraComma : InstNormal;
}
//===----------------------------------------------------------------------===//
// Embedded metadata.
//===----------------------------------------------------------------------===//
/// ParseMDNodeVector
/// ::= { Element (',' Element)* }
/// Element
/// ::= 'null' | TypeAndValue
bool LLParser::ParseMDNodeVector(SmallVectorImpl<Metadata *> &Elts) {
if (ParseToken(lltok::lbrace, "expected '{' here"))
return true;
// Check for an empty list.
if (EatIfPresent(lltok::rbrace))
return false;
do {
// Null is a special case since it is typeless.
if (EatIfPresent(lltok::kw_null)) {
Elts.push_back(nullptr);
continue;
}
Metadata *MD;
if (ParseMetadata(MD, nullptr))
return true;
Elts.push_back(MD);
} while (EatIfPresent(lltok::comma));
return ParseToken(lltok::rbrace, "expected end of metadata node");
}
//===----------------------------------------------------------------------===//
// Use-list order directives.
//===----------------------------------------------------------------------===//
bool LLParser::sortUseListOrder(Value *V, ArrayRef<unsigned> Indexes,
SMLoc Loc) {
if (V->use_empty())
return Error(Loc, "value has no uses");
unsigned NumUses = 0;
SmallDenseMap<const Use *, unsigned, 16> Order;
for (const Use &U : V->uses()) {
if (++NumUses > Indexes.size())
break;
Order[&U] = Indexes[NumUses - 1];
}
if (NumUses < 2)
return Error(Loc, "value only has one use");
if (Order.size() != Indexes.size() || NumUses > Indexes.size())
return Error(Loc, "wrong number of indexes, expected " +
Twine(std::distance(V->use_begin(), V->use_end())));
V->sortUseList([&](const Use &L, const Use &R) {
return Order.lookup(&L) < Order.lookup(&R);
});
return false;
}
/// ParseUseListOrderIndexes
/// ::= '{' uint32 (',' uint32)+ '}'
bool LLParser::ParseUseListOrderIndexes(SmallVectorImpl<unsigned> &Indexes) {
SMLoc Loc = Lex.getLoc();
if (ParseToken(lltok::lbrace, "expected '{' here"))
return true;
if (Lex.getKind() == lltok::rbrace)
return Lex.Error("expected non-empty list of uselistorder indexes");
// Use Offset, Max, and IsOrdered to check consistency of indexes. The
// indexes should be distinct numbers in the range [0, size-1], and should
// not be in order.
unsigned Offset = 0;
unsigned Max = 0;
bool IsOrdered = true;
assert(Indexes.empty() && "Expected empty order vector");
do {
unsigned Index;
if (ParseUInt32(Index))
return true;
// Update consistency checks.
Offset += Index - Indexes.size();
Max = std::max(Max, Index);
IsOrdered &= Index == Indexes.size();
Indexes.push_back(Index);
} while (EatIfPresent(lltok::comma));
if (ParseToken(lltok::rbrace, "expected '}' here"))
return true;
if (Indexes.size() < 2)
return Error(Loc, "expected >= 2 uselistorder indexes");
if (Offset != 0 || Max >= Indexes.size())
return Error(Loc, "expected distinct uselistorder indexes in range [0, size)");
if (IsOrdered)
return Error(Loc, "expected uselistorder indexes to change the order");
return false;
}
/// ParseUseListOrder
/// ::= 'uselistorder' Type Value ',' UseListOrderIndexes
bool LLParser::ParseUseListOrder(PerFunctionState *PFS) {
SMLoc Loc = Lex.getLoc();
if (ParseToken(lltok::kw_uselistorder, "expected uselistorder directive"))
return true;
Value *V;
SmallVector<unsigned, 16> Indexes;
if (ParseTypeAndValue(V, PFS) ||
ParseToken(lltok::comma, "expected comma in uselistorder directive") ||
ParseUseListOrderIndexes(Indexes))
return true;
return sortUseListOrder(V, Indexes, Loc);
}
/// ParseUseListOrderBB
/// ::= 'uselistorder_bb' @foo ',' %bar ',' UseListOrderIndexes
bool LLParser::ParseUseListOrderBB() {
assert(Lex.getKind() == lltok::kw_uselistorder_bb);
SMLoc Loc = Lex.getLoc();
Lex.Lex();
ValID Fn, Label;
SmallVector<unsigned, 16> Indexes;
if (ParseValID(Fn) ||
ParseToken(lltok::comma, "expected comma in uselistorder_bb directive") ||
ParseValID(Label) ||
ParseToken(lltok::comma, "expected comma in uselistorder_bb directive") ||
ParseUseListOrderIndexes(Indexes))
return true;
// Check the function.
GlobalValue *GV;
if (Fn.Kind == ValID::t_GlobalName)
GV = M->getNamedValue(Fn.StrVal);
else if (Fn.Kind == ValID::t_GlobalID)
GV = Fn.UIntVal < NumberedVals.size() ? NumberedVals[Fn.UIntVal] : nullptr;
else
return Error(Fn.Loc, "expected function name in uselistorder_bb");
if (!GV)
return Error(Fn.Loc, "invalid function forward reference in uselistorder_bb");
auto *F = dyn_cast<Function>(GV);
if (!F)
return Error(Fn.Loc, "expected function name in uselistorder_bb");
if (F->isDeclaration())
return Error(Fn.Loc, "invalid declaration in uselistorder_bb");
// Check the basic block.
if (Label.Kind == ValID::t_LocalID)
return Error(Label.Loc, "invalid numeric label in uselistorder_bb");
if (Label.Kind != ValID::t_LocalName)
return Error(Label.Loc, "expected basic block name in uselistorder_bb");
Value *V = F->getValueSymbolTable()->lookup(Label.StrVal);
if (!V)
return Error(Label.Loc, "invalid basic block in uselistorder_bb");
if (!isa<BasicBlock>(V))
return Error(Label.Loc, "expected basic block in uselistorder_bb");
return sortUseListOrder(V, Indexes, Loc);
}