The Floating class wraps a APFloat, which might heap allocate memory to represent large floating values. When writing those to bytecode, we would free() the heap allocation after writing, when destroying the actual APFloat we wrote. Fix this by seralizing a Floating as Semantics + APInt. This will be neccessary in more cases later, when we support arbitrary-precision integers or _BitInt. Differential Revision: https://reviews.llvm.org/D155165
212 lines
6.9 KiB
C++
212 lines
6.9 KiB
C++
//===--- Floating.h - Types for the constexpr VM ----------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// Defines the VM types and helpers operating on types.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_CLANG_AST_INTERP_FLOATING_H
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#define LLVM_CLANG_AST_INTERP_FLOATING_H
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#include "Primitives.h"
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#include "clang/AST/APValue.h"
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#include "llvm/ADT/APFloat.h"
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namespace clang {
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namespace interp {
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using APFloat = llvm::APFloat;
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using APSInt = llvm::APSInt;
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class Floating final {
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private:
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// The underlying value storage.
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APFloat F;
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public:
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/// Zero-initializes a Floating.
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Floating() : F(0.0f) {}
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Floating(const APFloat &F) : F(F) {}
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// Static constructors for special floating point values.
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static Floating getInf(const llvm::fltSemantics &Sem) {
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return Floating(APFloat::getInf(Sem));
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}
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const APFloat &getAPFloat() const { return F; }
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bool operator<(Floating RHS) const { return F < RHS.F; }
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bool operator>(Floating RHS) const { return F > RHS.F; }
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bool operator<=(Floating RHS) const { return F <= RHS.F; }
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bool operator>=(Floating RHS) const { return F >= RHS.F; }
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bool operator==(Floating RHS) const { return F == RHS.F; }
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bool operator!=(Floating RHS) const { return F != RHS.F; }
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Floating operator-() const { return Floating(-F); }
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APFloat::opStatus convertToInteger(APSInt &Result) const {
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bool IsExact;
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return F.convertToInteger(Result, llvm::APFloat::rmTowardZero, &IsExact);
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}
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Floating toSemantics(const llvm::fltSemantics *Sem,
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llvm::RoundingMode RM) const {
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APFloat Copy = F;
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bool LosesInfo;
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Copy.convert(*Sem, RM, &LosesInfo);
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(void)LosesInfo;
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return Floating(Copy);
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}
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/// Convert this Floating to one with the same semantics as \Other.
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Floating toSemantics(const Floating &Other, llvm::RoundingMode RM) const {
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return toSemantics(&Other.F.getSemantics(), RM);
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}
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APSInt toAPSInt(unsigned NumBits = 0) const {
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return APSInt(F.bitcastToAPInt());
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}
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APValue toAPValue() const { return APValue(F); }
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void print(llvm::raw_ostream &OS) const {
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// Can't use APFloat::print() since it appends a newline.
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SmallVector<char, 16> Buffer;
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F.toString(Buffer);
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OS << Buffer;
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}
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unsigned bitWidth() const { return F.semanticsSizeInBits(F.getSemantics()); }
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bool isSigned() const { return true; }
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bool isNegative() const { return F.isNegative(); }
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bool isPositive() const { return !F.isNegative(); }
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bool isZero() const { return F.isZero(); }
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bool isNonZero() const { return F.isNonZero(); }
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bool isMin() const { return F.isSmallest(); }
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bool isMinusOne() const { return F.isExactlyValue(-1.0); }
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bool isNan() const { return F.isNaN(); }
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bool isInf() const { return F.isInfinity(); }
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bool isFinite() const { return F.isFinite(); }
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bool isNormal() const { return F.isNormal(); }
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bool isDenormal() const { return F.isDenormal(); }
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llvm::FPClassTest classify() const { return F.classify(); }
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APFloat::fltCategory getCategory() const { return F.getCategory(); }
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ComparisonCategoryResult compare(const Floating &RHS) const {
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llvm::APFloatBase::cmpResult CmpRes = F.compare(RHS.F);
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switch (CmpRes) {
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case llvm::APFloatBase::cmpLessThan:
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return ComparisonCategoryResult::Less;
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case llvm::APFloatBase::cmpEqual:
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return ComparisonCategoryResult::Equal;
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case llvm::APFloatBase::cmpGreaterThan:
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return ComparisonCategoryResult::Greater;
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case llvm::APFloatBase::cmpUnordered:
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return ComparisonCategoryResult::Unordered;
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}
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llvm_unreachable("Inavlid cmpResult value");
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}
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static APFloat::opStatus fromIntegral(APSInt Val,
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const llvm::fltSemantics &Sem,
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llvm::RoundingMode RM,
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Floating &Result) {
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APFloat F = APFloat(Sem);
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APFloat::opStatus Status = F.convertFromAPInt(Val, Val.isSigned(), RM);
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Result = Floating(F);
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return Status;
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}
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static Floating bitcastFromMemory(const std::byte *Buff,
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const llvm::fltSemantics &Sem) {
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size_t Size = APFloat::semanticsSizeInBits(Sem);
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llvm::APInt API(Size, true);
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llvm::LoadIntFromMemory(API, (const uint8_t *)Buff, Size / 8);
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return Floating(APFloat(Sem, API));
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}
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// === Serialization support ===
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size_t bytesToSerialize() const {
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return sizeof(llvm::fltSemantics *) +
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(APFloat::semanticsSizeInBits(F.getSemantics()) / 8);
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}
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void serialize(std::byte *Buff) const {
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// Semantics followed by an APInt.
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*reinterpret_cast<const llvm::fltSemantics **>(Buff) = &F.getSemantics();
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llvm::APInt API = F.bitcastToAPInt();
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llvm::StoreIntToMemory(API, (uint8_t *)(Buff + sizeof(void *)),
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bitWidth() / 8);
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}
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static Floating deserialize(const std::byte *Buff) {
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const llvm::fltSemantics *Sem;
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std::memcpy((void *)&Sem, Buff, sizeof(void *));
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return bitcastFromMemory(Buff + sizeof(void *), *Sem);
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}
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static Floating abs(const Floating &F) {
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APFloat V = F.F;
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if (V.isNegative())
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V.changeSign();
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return Floating(V);
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}
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// -------
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static APFloat::opStatus add(const Floating &A, const Floating &B,
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llvm::RoundingMode RM, Floating *R) {
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*R = Floating(A.F);
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return R->F.add(B.F, RM);
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}
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static APFloat::opStatus increment(const Floating &A, llvm::RoundingMode RM,
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Floating *R) {
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APFloat One(A.F.getSemantics(), 1);
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*R = Floating(A.F);
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return R->F.add(One, RM);
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}
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static APFloat::opStatus sub(const Floating &A, const Floating &B,
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llvm::RoundingMode RM, Floating *R) {
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*R = Floating(A.F);
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return R->F.subtract(B.F, RM);
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}
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static APFloat::opStatus decrement(const Floating &A, llvm::RoundingMode RM,
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Floating *R) {
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APFloat One(A.F.getSemantics(), 1);
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*R = Floating(A.F);
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return R->F.subtract(One, RM);
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}
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static APFloat::opStatus mul(const Floating &A, const Floating &B,
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llvm::RoundingMode RM, Floating *R) {
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*R = Floating(A.F);
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return R->F.multiply(B.F, RM);
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}
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static APFloat::opStatus div(const Floating &A, const Floating &B,
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llvm::RoundingMode RM, Floating *R) {
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*R = Floating(A.F);
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return R->F.divide(B.F, RM);
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}
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static bool neg(const Floating &A, Floating *R) {
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*R = -A;
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return false;
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}
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};
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llvm::raw_ostream &operator<<(llvm::raw_ostream &OS, Floating F);
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Floating getSwappedBytes(Floating F);
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} // namespace interp
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} // namespace clang
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#endif
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