//===-- DebugLoc.cpp - Implement DebugLoc class ---------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "llvm/Support/DebugLoc.h" #include "llvm/ADT/DenseMapInfo.h" #include "LLVMContextImpl.h" using namespace llvm; //===----------------------------------------------------------------------===// // DebugLoc Implementation //===----------------------------------------------------------------------===// MDNode *DebugLoc::getScope(const LLVMContext &Ctx) const { if (ScopeIdx == 0) return 0; if (ScopeIdx > 0) { // Positive ScopeIdx is an index into ScopeRecords, which has no inlined-at // position specified. assert(unsigned(ScopeIdx) <= Ctx.pImpl->ScopeRecords.size() && "Invalid ScopeIdx!"); return Ctx.pImpl->ScopeRecords[ScopeIdx-1].get(); } // Otherwise, the index is in the ScopeInlinedAtRecords array. assert(unsigned(-ScopeIdx) <= Ctx.pImpl->ScopeInlinedAtRecords.size() && "Invalid ScopeIdx"); return Ctx.pImpl->ScopeInlinedAtRecords[-ScopeIdx-1].first.get(); } MDNode *DebugLoc::getInlinedAt(const LLVMContext &Ctx) const { // Positive ScopeIdx is an index into ScopeRecords, which has no inlined-at // position specified. Zero is invalid. if (ScopeIdx >= 0) return 0; // Otherwise, the index is in the ScopeInlinedAtRecords array. assert(unsigned(-ScopeIdx) <= Ctx.pImpl->ScopeInlinedAtRecords.size() && "Invalid ScopeIdx"); return Ctx.pImpl->ScopeInlinedAtRecords[-ScopeIdx-1].second.get(); } /// Return both the Scope and the InlinedAt values. void DebugLoc::getScopeAndInlinedAt(MDNode *&Scope, MDNode *&IA, const LLVMContext &Ctx) const { if (ScopeIdx == 0) { Scope = IA = 0; return; } if (ScopeIdx > 0) { // Positive ScopeIdx is an index into ScopeRecords, which has no inlined-at // position specified. assert(unsigned(ScopeIdx) <= Ctx.pImpl->ScopeRecords.size() && "Invalid ScopeIdx!"); Scope = Ctx.pImpl->ScopeRecords[ScopeIdx-1].get(); IA = 0; return; } // Otherwise, the index is in the ScopeInlinedAtRecords array. assert(unsigned(-ScopeIdx) <= Ctx.pImpl->ScopeInlinedAtRecords.size() && "Invalid ScopeIdx"); Scope = Ctx.pImpl->ScopeInlinedAtRecords[-ScopeIdx-1].first.get(); IA = Ctx.pImpl->ScopeInlinedAtRecords[-ScopeIdx-1].second.get(); } DebugLoc DebugLoc::get(unsigned Line, unsigned Col, MDNode *Scope, MDNode *InlinedAt) { DebugLoc Result; // If no scope is available, this is an unknown location. if (Scope == 0) return Result; // Saturate line and col to "unknown". if (Col > 255) Col = 0; if (Line >= (1 << 24)) Line = 0; Result.LineCol = Line | (Col << 24); LLVMContext &Ctx = Scope->getContext(); // If there is no inlined-at location, use the ScopeRecords array. if (InlinedAt == 0) Result.ScopeIdx = Ctx.pImpl->getOrAddScopeRecordIdxEntry(Scope, 0); else Result.ScopeIdx = Ctx.pImpl->getOrAddScopeInlinedAtIdxEntry(Scope, InlinedAt, 0); return Result; } /// getAsMDNode - This method converts the compressed DebugLoc node into a /// DILocation compatible MDNode. MDNode *DebugLoc::getAsMDNode(const LLVMContext &Ctx) const { if (isUnknown()) return 0; MDNode *Scope, *IA; getScopeAndInlinedAt(Scope, IA, Ctx); assert(Scope && "If scope is null, this should be isUnknown()"); LLVMContext &Ctx2 = Scope->getContext(); const Type *Int32 = Type::getInt32Ty(Ctx2); Value *Elts[] = { ConstantInt::get(Int32, getLine()), ConstantInt::get(Int32, getCol()), Scope, IA }; return MDNode::get(Ctx2, Elts); } /// getFromDILocation - Translate the DILocation quad into a DebugLoc. DebugLoc DebugLoc::getFromDILocation(MDNode *N) { if (N == 0 || N->getNumOperands() != 4) return DebugLoc(); MDNode *Scope = dyn_cast_or_null(N->getOperand(2)); if (Scope == 0) return DebugLoc(); unsigned LineNo = 0, ColNo = 0; if (ConstantInt *Line = dyn_cast_or_null(N->getOperand(0))) LineNo = Line->getZExtValue(); if (ConstantInt *Col = dyn_cast_or_null(N->getOperand(1))) ColNo = Col->getZExtValue(); return get(LineNo, ColNo, Scope, dyn_cast_or_null(N->getOperand(3))); } /// getFromDILexicalBlock - Translate the DILexicalBlock into a DebugLoc. DebugLoc DebugLoc::getFromDILexicalBlock(MDNode *N) { if (N == 0 || N->getNumOperands() < 3) return DebugLoc(); MDNode *Scope = dyn_cast_or_null(N->getOperand(1)); if (Scope == 0) return DebugLoc(); unsigned LineNo = 0, ColNo = 0; if (ConstantInt *Line = dyn_cast_or_null(N->getOperand(2))) LineNo = Line->getZExtValue(); if (ConstantInt *Col = dyn_cast_or_null(N->getOperand(3))) ColNo = Col->getZExtValue(); return get(LineNo, ColNo, Scope, NULL); } //===----------------------------------------------------------------------===// // DenseMap specialization //===----------------------------------------------------------------------===// DebugLoc DenseMapInfo::getEmptyKey() { return DebugLoc::getEmptyKey(); } DebugLoc DenseMapInfo::getTombstoneKey() { return DebugLoc::getTombstoneKey(); } unsigned DenseMapInfo::getHashValue(const DebugLoc &Key) { FoldingSetNodeID ID; ID.AddInteger(Key.LineCol); ID.AddInteger(Key.ScopeIdx); return ID.ComputeHash(); } bool DenseMapInfo::isEqual(const DebugLoc &LHS, const DebugLoc &RHS) { return LHS == RHS; } //===----------------------------------------------------------------------===// // LLVMContextImpl Implementation //===----------------------------------------------------------------------===// int LLVMContextImpl::getOrAddScopeRecordIdxEntry(MDNode *Scope, int ExistingIdx) { // If we already have an entry for this scope, return it. int &Idx = ScopeRecordIdx[Scope]; if (Idx) return Idx; // If we don't have an entry, but ExistingIdx is specified, use it. if (ExistingIdx) return Idx = ExistingIdx; // Otherwise add a new entry. // Start out ScopeRecords with a minimal reasonable size to avoid // excessive reallocation starting out. if (ScopeRecords.empty()) ScopeRecords.reserve(128); // Index is biased by 1 for index. Idx = ScopeRecords.size()+1; ScopeRecords.push_back(DebugRecVH(Scope, this, Idx)); return Idx; } int LLVMContextImpl::getOrAddScopeInlinedAtIdxEntry(MDNode *Scope, MDNode *IA, int ExistingIdx) { // If we already have an entry, return it. int &Idx = ScopeInlinedAtIdx[std::make_pair(Scope, IA)]; if (Idx) return Idx; // If we don't have an entry, but ExistingIdx is specified, use it. if (ExistingIdx) return Idx = ExistingIdx; // Start out ScopeInlinedAtRecords with a minimal reasonable size to avoid // excessive reallocation starting out. if (ScopeInlinedAtRecords.empty()) ScopeInlinedAtRecords.reserve(128); // Index is biased by 1 and negated. Idx = -ScopeInlinedAtRecords.size()-1; ScopeInlinedAtRecords.push_back(std::make_pair(DebugRecVH(Scope, this, Idx), DebugRecVH(IA, this, Idx))); return Idx; } //===----------------------------------------------------------------------===// // DebugRecVH Implementation //===----------------------------------------------------------------------===// /// deleted - The MDNode this is pointing to got deleted, so this pointer needs /// to drop to null and we need remove our entry from the DenseMap. void DebugRecVH::deleted() { // If this is a non-canonical reference, just drop the value to null, we know // it doesn't have a map entry. if (Idx == 0) { setValPtr(0); return; } MDNode *Cur = get(); // If the index is positive, it is an entry in ScopeRecords. if (Idx > 0) { assert(Ctx->ScopeRecordIdx[Cur] == Idx && "Mapping out of date!"); Ctx->ScopeRecordIdx.erase(Cur); // Reset this VH to null and we're done. setValPtr(0); Idx = 0; return; } // Otherwise, it is an entry in ScopeInlinedAtRecords, we don't know if it // is the scope or the inlined-at record entry. assert(unsigned(-Idx-1) < Ctx->ScopeInlinedAtRecords.size()); std::pair &Entry = Ctx->ScopeInlinedAtRecords[-Idx-1]; assert((this == &Entry.first || this == &Entry.second) && "Mapping out of date!"); MDNode *OldScope = Entry.first.get(); MDNode *OldInlinedAt = Entry.second.get(); assert(OldScope != 0 && OldInlinedAt != 0 && "Entry should be non-canonical if either val dropped to null"); // Otherwise, we do have an entry in it, nuke it and we're done. assert(Ctx->ScopeInlinedAtIdx[std::make_pair(OldScope, OldInlinedAt)] == Idx&& "Mapping out of date"); Ctx->ScopeInlinedAtIdx.erase(std::make_pair(OldScope, OldInlinedAt)); // Reset this VH to null. Drop both 'Idx' values to null to indicate that // we're in non-canonical form now. setValPtr(0); Entry.first.Idx = Entry.second.Idx = 0; } void DebugRecVH::allUsesReplacedWith(Value *NewVa) { // If being replaced with a non-mdnode value (e.g. undef) handle this as if // the mdnode got deleted. MDNode *NewVal = dyn_cast(NewVa); if (NewVal == 0) return deleted(); // If this is a non-canonical reference, just change it, we know it already // doesn't have a map entry. if (Idx == 0) { setValPtr(NewVa); return; } MDNode *OldVal = get(); assert(OldVal != NewVa && "Node replaced with self?"); // If the index is positive, it is an entry in ScopeRecords. if (Idx > 0) { assert(Ctx->ScopeRecordIdx[OldVal] == Idx && "Mapping out of date!"); Ctx->ScopeRecordIdx.erase(OldVal); setValPtr(NewVal); int NewEntry = Ctx->getOrAddScopeRecordIdxEntry(NewVal, Idx); // If NewVal already has an entry, this becomes a non-canonical reference, // just drop Idx to 0 to signify this. if (NewEntry != Idx) Idx = 0; return; } // Otherwise, it is an entry in ScopeInlinedAtRecords, we don't know if it // is the scope or the inlined-at record entry. assert(unsigned(-Idx-1) < Ctx->ScopeInlinedAtRecords.size()); std::pair &Entry = Ctx->ScopeInlinedAtRecords[-Idx-1]; assert((this == &Entry.first || this == &Entry.second) && "Mapping out of date!"); MDNode *OldScope = Entry.first.get(); MDNode *OldInlinedAt = Entry.second.get(); assert(OldScope != 0 && OldInlinedAt != 0 && "Entry should be non-canonical if either val dropped to null"); // Otherwise, we do have an entry in it, nuke it and we're done. assert(Ctx->ScopeInlinedAtIdx[std::make_pair(OldScope, OldInlinedAt)] == Idx&& "Mapping out of date"); Ctx->ScopeInlinedAtIdx.erase(std::make_pair(OldScope, OldInlinedAt)); // Reset this VH to the new value. setValPtr(NewVal); int NewIdx = Ctx->getOrAddScopeInlinedAtIdxEntry(Entry.first.get(), Entry.second.get(), Idx); // If NewVal already has an entry, this becomes a non-canonical reference, // just drop Idx to 0 to signify this. if (NewIdx != Idx) { std::pair &Entry=Ctx->ScopeInlinedAtRecords[-Idx-1]; Entry.first.Idx = Entry.second.Idx = 0; } }