//===- ValueLattice.h - Value constraint analysis ---------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLVM_ANALYSIS_VALUELATTICE_H #define LLVM_ANALYSIS_VALUELATTICE_H #include "llvm/IR/ConstantRange.h" #include "llvm/IR/Constants.h" #include "llvm/IR/Instructions.h" // //===----------------------------------------------------------------------===// // ValueLatticeElement //===----------------------------------------------------------------------===// /// This class represents lattice values for constants. /// /// FIXME: This is basically just for bringup, this can be made a lot more rich /// in the future. /// namespace llvm { class ValueLatticeElement { enum ValueLatticeElementTy { /// This Value has no known value yet. As a result, this implies the /// producing instruction is dead. Caution: We use this as the starting /// state in our local meet rules. In this usage, it's taken to mean /// "nothing known yet". /// Transition to any other state allowed. unknown, /// This Value is an UndefValue constant or produces undef. Undefined values /// can be merged with constants (or single element constant ranges), /// assuming all uses of the result will be replaced. /// Transition allowed to the following states: /// constant /// constantrange_including_undef /// overdefined undef, /// This Value has a specific constant value. The constant cannot be undef. /// (For constant integers, constantrange is used instead. Integer typed /// constantexprs can appear as constant.) Note that the constant state /// can be reached by merging undef & constant states. /// Transition allowed to the following states: /// overdefined constant, /// This Value is known to not have the specified value. (For constant /// integers, constantrange is used instead. As above, integer typed /// constantexprs can appear here.) /// Transition allowed to the following states: /// overdefined notconstant, /// The Value falls within this range. (Used only for integer typed values.) /// Transition allowed to the following states: /// constantrange (new range must be a superset of the existing range) /// constantrange_including_undef /// overdefined constantrange, /// This Value falls within this range, but also may be undef. /// Merging it with other constant ranges results in /// constantrange_including_undef. /// Transition allowed to the following states: /// overdefined constantrange_including_undef, /// We can not precisely model the dynamic values this value might take. /// No transitions are allowed after reaching overdefined. overdefined, }; ValueLatticeElementTy Tag : 8; /// Number of times a constant range has been extended with widening enabled. unsigned NumRangeExtensions : 8; /// The union either stores a pointer to a constant or a constant range, /// associated to the lattice element. We have to ensure that Range is /// initialized or destroyed when changing state to or from constantrange. union { Constant *ConstVal; ConstantRange Range; }; /// Destroy contents of lattice value, without destructing the object. void destroy() { switch (Tag) { case overdefined: case unknown: case undef: case constant: case notconstant: break; case constantrange_including_undef: case constantrange: Range.~ConstantRange(); break; }; } public: /// Struct to control some aspects related to merging constant ranges. struct MergeOptions { /// The merge value may include undef. bool MayIncludeUndef; /// Handle repeatedly extending a range by going to overdefined after a /// number of steps. bool CheckWiden; /// The number of allowed widening steps (including setting the range /// initially). unsigned MaxWidenSteps; MergeOptions() : MergeOptions(false, false) {} MergeOptions(bool MayIncludeUndef, bool CheckWiden, unsigned MaxWidenSteps = 1) : MayIncludeUndef(MayIncludeUndef), CheckWiden(CheckWiden), MaxWidenSteps(MaxWidenSteps) {} MergeOptions &setMayIncludeUndef(bool V = true) { MayIncludeUndef = V; return *this; } MergeOptions &setCheckWiden(bool V = true) { CheckWiden = V; return *this; } MergeOptions &setMaxWidenSteps(unsigned Steps = 1) { CheckWiden = true; MaxWidenSteps = Steps; return *this; } }; // ConstVal and Range are initialized on-demand. ValueLatticeElement() : Tag(unknown), NumRangeExtensions(0) {} ~ValueLatticeElement() { destroy(); } ValueLatticeElement(const ValueLatticeElement &Other) : Tag(Other.Tag), NumRangeExtensions(0) { switch (Other.Tag) { case constantrange: case constantrange_including_undef: new (&Range) ConstantRange(Other.Range); NumRangeExtensions = Other.NumRangeExtensions; break; case constant: case notconstant: ConstVal = Other.ConstVal; break; case overdefined: case unknown: case undef: break; } } ValueLatticeElement(ValueLatticeElement &&Other) : Tag(Other.Tag), NumRangeExtensions(0) { switch (Other.Tag) { case constantrange: case constantrange_including_undef: new (&Range) ConstantRange(std::move(Other.Range)); NumRangeExtensions = Other.NumRangeExtensions; break; case constant: case notconstant: ConstVal = Other.ConstVal; break; case overdefined: case unknown: case undef: break; } Other.Tag = unknown; } ValueLatticeElement &operator=(const ValueLatticeElement &Other) { destroy(); new (this) ValueLatticeElement(Other); return *this; } ValueLatticeElement &operator=(ValueLatticeElement &&Other) { destroy(); new (this) ValueLatticeElement(std::move(Other)); return *this; } static ValueLatticeElement get(Constant *C) { ValueLatticeElement Res; if (isa(C)) Res.markUndef(); else Res.markConstant(C); return Res; } static ValueLatticeElement getNot(Constant *C) { ValueLatticeElement Res; assert(!isa(C) && "!= undef is not supported"); Res.markNotConstant(C); return Res; } static ValueLatticeElement getRange(ConstantRange CR, bool MayIncludeUndef = false) { if (CR.isFullSet()) return getOverdefined(); if (CR.isEmptySet()) { ValueLatticeElement Res; if (MayIncludeUndef) Res.markUndef(); return Res; } ValueLatticeElement Res; Res.markConstantRange(std::move(CR), MergeOptions().setMayIncludeUndef(MayIncludeUndef)); return Res; } static ValueLatticeElement getOverdefined() { ValueLatticeElement Res; Res.markOverdefined(); return Res; } bool isUndef() const { return Tag == undef; } bool isUnknown() const { return Tag == unknown; } bool isUnknownOrUndef() const { return Tag == unknown || Tag == undef; } bool isConstant() const { return Tag == constant; } bool isNotConstant() const { return Tag == notconstant; } bool isConstantRangeIncludingUndef() const { return Tag == constantrange_including_undef; } /// Returns true if this value is a constant range. Use \p UndefAllowed to /// exclude non-singleton constant ranges that may also be undef. Note that /// this function also returns true if the range may include undef, but only /// contains a single element. In that case, it can be replaced by a constant. bool isConstantRange(bool UndefAllowed = true) const { return Tag == constantrange || (Tag == constantrange_including_undef && (UndefAllowed || Range.isSingleElement())); } bool isOverdefined() const { return Tag == overdefined; } Constant *getConstant() const { assert(isConstant() && "Cannot get the constant of a non-constant!"); return ConstVal; } Constant *getNotConstant() const { assert(isNotConstant() && "Cannot get the constant of a non-notconstant!"); return ConstVal; } /// Returns the constant range for this value. Use \p UndefAllowed to exclude /// non-singleton constant ranges that may also be undef. Note that this /// function also returns a range if the range may include undef, but only /// contains a single element. In that case, it can be replaced by a constant. const ConstantRange &getConstantRange(bool UndefAllowed = true) const { assert(isConstantRange(UndefAllowed) && "Cannot get the constant-range of a non-constant-range!"); return Range; } Optional asConstantInteger() const { if (isConstant() && isa(getConstant())) { return cast(getConstant())->getValue(); } else if (isConstantRange() && getConstantRange().isSingleElement()) { return *getConstantRange().getSingleElement(); } return None; } bool markOverdefined() { if (isOverdefined()) return false; destroy(); Tag = overdefined; return true; } bool markUndef() { if (isUndef()) return false; assert(isUnknown()); Tag = undef; return true; } bool markConstant(Constant *V, bool MayIncludeUndef = false) { if (isa(V)) return markUndef(); if (isConstant()) { assert(getConstant() == V && "Marking constant with different value"); return false; } if (ConstantInt *CI = dyn_cast(V)) return markConstantRange( ConstantRange(CI->getValue()), MergeOptions().setMayIncludeUndef(MayIncludeUndef)); assert(isUnknown() || isUndef()); Tag = constant; ConstVal = V; return true; } bool markNotConstant(Constant *V) { assert(V && "Marking constant with NULL"); if (ConstantInt *CI = dyn_cast(V)) return markConstantRange( ConstantRange(CI->getValue() + 1, CI->getValue())); if (isa(V)) return false; if (isNotConstant()) { assert(getNotConstant() == V && "Marking !constant with different value"); return false; } assert(isUnknown()); Tag = notconstant; ConstVal = V; return true; } /// Mark the object as constant range with \p NewR. If the object is already a /// constant range, nothing changes if the existing range is equal to \p /// NewR and the tag. Otherwise \p NewR must be a superset of the existing /// range or the object must be undef. The tag is set to /// constant_range_including_undef if either the existing value or the new /// range may include undef. bool markConstantRange(ConstantRange NewR, MergeOptions Opts = MergeOptions()) { assert(!NewR.isEmptySet() && "should only be called for non-empty sets"); if (NewR.isFullSet()) return markOverdefined(); ValueLatticeElementTy OldTag = Tag; ValueLatticeElementTy NewTag = (isUndef() || isConstantRangeIncludingUndef() || Opts.MayIncludeUndef) ? constantrange_including_undef : constantrange; if (isConstantRange()) { Tag = NewTag; if (getConstantRange() == NewR) return Tag != OldTag; // Simple form of widening. If a range is extended multiple times, go to // overdefined. if (Opts.CheckWiden && ++NumRangeExtensions > Opts.MaxWidenSteps) return markOverdefined(); assert(NewR.contains(getConstantRange()) && "Existing range must be a subset of NewR"); Range = std::move(NewR); return true; } assert(isUnknown() || isUndef()); NumRangeExtensions = 0; Tag = NewTag; new (&Range) ConstantRange(std::move(NewR)); return true; } /// Updates this object to approximate both this object and RHS. Returns /// true if this object has been changed. bool mergeIn(const ValueLatticeElement &RHS, MergeOptions Opts = MergeOptions()) { if (RHS.isUnknown() || isOverdefined()) return false; if (RHS.isOverdefined()) { markOverdefined(); return true; } if (isUndef()) { assert(!RHS.isUnknown()); if (RHS.isUndef()) return false; if (RHS.isConstant()) return markConstant(RHS.getConstant(), true); if (RHS.isConstantRange()) return markConstantRange(RHS.getConstantRange(true), Opts.setMayIncludeUndef()); return markOverdefined(); } if (isUnknown()) { assert(!RHS.isUnknown() && "Unknow RHS should be handled earlier"); *this = RHS; return true; } if (isConstant()) { if (RHS.isConstant() && getConstant() == RHS.getConstant()) return false; if (RHS.isUndef()) return false; markOverdefined(); return true; } if (isNotConstant()) { if (RHS.isNotConstant() && getNotConstant() == RHS.getNotConstant()) return false; markOverdefined(); return true; } auto OldTag = Tag; assert(isConstantRange() && "New ValueLattice type?"); if (RHS.isUndef()) { Tag = constantrange_including_undef; return OldTag != Tag; } if (!RHS.isConstantRange()) { // We can get here if we've encountered a constantexpr of integer type // and merge it with a constantrange. markOverdefined(); return true; } ConstantRange NewR = getConstantRange().unionWith(RHS.getConstantRange()); return markConstantRange( std::move(NewR), Opts.setMayIncludeUndef(RHS.isConstantRangeIncludingUndef())); } // Compares this symbolic value with Other using Pred and returns either /// true, false or undef constants, or nullptr if the comparison cannot be /// evaluated. Constant *getCompare(CmpInst::Predicate Pred, Type *Ty, const ValueLatticeElement &Other) const { if (isUnknownOrUndef() || Other.isUnknownOrUndef()) return UndefValue::get(Ty); if (isConstant() && Other.isConstant()) return ConstantExpr::getCompare(Pred, getConstant(), Other.getConstant()); if (ICmpInst::isEquality(Pred)) { // not(C) != C => true, not(C) == C => false. if ((isNotConstant() && Other.isConstant() && getNotConstant() == Other.getConstant()) || (isConstant() && Other.isNotConstant() && getConstant() == Other.getNotConstant())) return Pred == ICmpInst::ICMP_NE ? ConstantInt::getTrue(Ty) : ConstantInt::getFalse(Ty); } // Integer constants are represented as ConstantRanges with single // elements. if (!isConstantRange() || !Other.isConstantRange()) return nullptr; const auto &CR = getConstantRange(); const auto &OtherCR = Other.getConstantRange(); if (ConstantRange::makeSatisfyingICmpRegion(Pred, OtherCR).contains(CR)) return ConstantInt::getTrue(Ty); if (ConstantRange::makeSatisfyingICmpRegion( CmpInst::getInversePredicate(Pred), OtherCR) .contains(CR)) return ConstantInt::getFalse(Ty); return nullptr; } unsigned getNumRangeExtensions() const { return NumRangeExtensions; } void setNumRangeExtensions(unsigned N) { NumRangeExtensions = N; } }; static_assert(sizeof(ValueLatticeElement) <= 40, "size of ValueLatticeElement changed unexpectedly"); raw_ostream &operator<<(raw_ostream &OS, const ValueLatticeElement &Val); } // end namespace llvm #endif