268 lines
9.9 KiB
C++
268 lines
9.9 KiB
C++
//===- WholeProgramDevirt.h - Whole-program devirt pass ---------*- 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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// This file defines parts of the whole-program devirtualization pass
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// implementation that may be usefully unit tested.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_TRANSFORMS_IPO_WHOLEPROGRAMDEVIRT_H
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#define LLVM_TRANSFORMS_IPO_WHOLEPROGRAMDEVIRT_H
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#include "llvm/IR/Module.h"
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#include "llvm/IR/PassManager.h"
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#include "llvm/Transforms/IPO/FunctionImport.h"
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#include <cassert>
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#include <cstdint>
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#include <set>
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#include <utility>
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#include <vector>
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namespace llvm {
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template <typename T> class ArrayRef;
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template <typename T> class MutableArrayRef;
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class Function;
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class GlobalVariable;
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class ModuleSummaryIndex;
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struct ValueInfo;
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namespace wholeprogramdevirt {
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// A bit vector that keeps track of which bits are used. We use this to
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// pack constant values compactly before and after each virtual table.
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struct AccumBitVector {
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std::vector<uint8_t> Bytes;
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// Bits in BytesUsed[I] are 1 if matching bit in Bytes[I] is used, 0 if not.
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std::vector<uint8_t> BytesUsed;
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std::pair<uint8_t *, uint8_t *> getPtrToData(uint64_t Pos, uint8_t Size) {
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if (Bytes.size() < Pos + Size) {
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Bytes.resize(Pos + Size);
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BytesUsed.resize(Pos + Size);
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}
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return std::make_pair(Bytes.data() + Pos, BytesUsed.data() + Pos);
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}
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// Set little-endian value Val with size Size at bit position Pos,
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// and mark bytes as used.
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void setLE(uint64_t Pos, uint64_t Val, uint8_t Size) {
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assert(Pos % 8 == 0);
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auto DataUsed = getPtrToData(Pos / 8, Size);
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for (unsigned I = 0; I != Size; ++I) {
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DataUsed.first[I] = Val >> (I * 8);
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assert(!DataUsed.second[I]);
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DataUsed.second[I] = 0xff;
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}
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}
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// Set big-endian value Val with size Size at bit position Pos,
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// and mark bytes as used.
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void setBE(uint64_t Pos, uint64_t Val, uint8_t Size) {
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assert(Pos % 8 == 0);
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auto DataUsed = getPtrToData(Pos / 8, Size);
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for (unsigned I = 0; I != Size; ++I) {
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DataUsed.first[Size - I - 1] = Val >> (I * 8);
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assert(!DataUsed.second[Size - I - 1]);
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DataUsed.second[Size - I - 1] = 0xff;
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}
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}
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// Set bit at bit position Pos to b and mark bit as used.
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void setBit(uint64_t Pos, bool b) {
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auto DataUsed = getPtrToData(Pos / 8, 1);
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if (b)
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*DataUsed.first |= 1 << (Pos % 8);
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assert(!(*DataUsed.second & (1 << Pos % 8)));
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*DataUsed.second |= 1 << (Pos % 8);
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}
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};
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// The bits that will be stored before and after a particular vtable.
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struct VTableBits {
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// The vtable global.
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GlobalVariable *GV;
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// Cache of the vtable's size in bytes.
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uint64_t ObjectSize = 0;
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// The bit vector that will be laid out before the vtable. Note that these
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// bytes are stored in reverse order until the globals are rebuilt. This means
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// that any values in the array must be stored using the opposite endianness
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// from the target.
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AccumBitVector Before;
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// The bit vector that will be laid out after the vtable.
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AccumBitVector After;
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};
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// Information about a member of a particular type identifier.
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struct TypeMemberInfo {
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// The VTableBits for the vtable.
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VTableBits *Bits;
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// The offset in bytes from the start of the vtable (i.e. the address point).
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uint64_t Offset;
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bool operator<(const TypeMemberInfo &other) const {
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return Bits < other.Bits || (Bits == other.Bits && Offset < other.Offset);
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}
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};
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// A virtual call target, i.e. an entry in a particular vtable.
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struct VirtualCallTarget {
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VirtualCallTarget(Function *Fn, const TypeMemberInfo *TM);
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// For testing only.
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VirtualCallTarget(const TypeMemberInfo *TM, bool IsBigEndian)
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: Fn(nullptr), TM(TM), IsBigEndian(IsBigEndian), WasDevirt(false) {}
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// The function stored in the vtable.
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Function *Fn;
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// A pointer to the type identifier member through which the pointer to Fn is
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// accessed.
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const TypeMemberInfo *TM;
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// When doing virtual constant propagation, this stores the return value for
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// the function when passed the currently considered argument list.
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uint64_t RetVal;
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// Whether the target is big endian.
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bool IsBigEndian;
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// Whether at least one call site to the target was devirtualized.
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bool WasDevirt;
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// The minimum byte offset before the address point. This covers the bytes in
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// the vtable object before the address point (e.g. RTTI, access-to-top,
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// vtables for other base classes) and is equal to the offset from the start
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// of the vtable object to the address point.
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uint64_t minBeforeBytes() const { return TM->Offset; }
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// The minimum byte offset after the address point. This covers the bytes in
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// the vtable object after the address point (e.g. the vtable for the current
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// class and any later base classes) and is equal to the size of the vtable
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// object minus the offset from the start of the vtable object to the address
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// point.
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uint64_t minAfterBytes() const { return TM->Bits->ObjectSize - TM->Offset; }
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// The number of bytes allocated (for the vtable plus the byte array) before
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// the address point.
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uint64_t allocatedBeforeBytes() const {
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return minBeforeBytes() + TM->Bits->Before.Bytes.size();
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}
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// The number of bytes allocated (for the vtable plus the byte array) after
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// the address point.
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uint64_t allocatedAfterBytes() const {
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return minAfterBytes() + TM->Bits->After.Bytes.size();
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}
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// Set the bit at position Pos before the address point to RetVal.
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void setBeforeBit(uint64_t Pos) {
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assert(Pos >= 8 * minBeforeBytes());
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TM->Bits->Before.setBit(Pos - 8 * minBeforeBytes(), RetVal);
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}
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// Set the bit at position Pos after the address point to RetVal.
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void setAfterBit(uint64_t Pos) {
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assert(Pos >= 8 * minAfterBytes());
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TM->Bits->After.setBit(Pos - 8 * minAfterBytes(), RetVal);
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}
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// Set the bytes at position Pos before the address point to RetVal.
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// Because the bytes in Before are stored in reverse order, we use the
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// opposite endianness to the target.
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void setBeforeBytes(uint64_t Pos, uint8_t Size) {
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assert(Pos >= 8 * minBeforeBytes());
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if (IsBigEndian)
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TM->Bits->Before.setLE(Pos - 8 * minBeforeBytes(), RetVal, Size);
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else
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TM->Bits->Before.setBE(Pos - 8 * minBeforeBytes(), RetVal, Size);
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}
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// Set the bytes at position Pos after the address point to RetVal.
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void setAfterBytes(uint64_t Pos, uint8_t Size) {
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assert(Pos >= 8 * minAfterBytes());
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if (IsBigEndian)
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TM->Bits->After.setBE(Pos - 8 * minAfterBytes(), RetVal, Size);
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else
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TM->Bits->After.setLE(Pos - 8 * minAfterBytes(), RetVal, Size);
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}
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};
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// Find the minimum offset that we may store a value of size Size bits at. If
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// IsAfter is set, look for an offset before the object, otherwise look for an
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// offset after the object.
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uint64_t findLowestOffset(ArrayRef<VirtualCallTarget> Targets, bool IsAfter,
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uint64_t Size);
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// Set the stored value in each of Targets to VirtualCallTarget::RetVal at the
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// given allocation offset before the vtable address. Stores the computed
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// byte/bit offset to OffsetByte/OffsetBit.
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void setBeforeReturnValues(MutableArrayRef<VirtualCallTarget> Targets,
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uint64_t AllocBefore, unsigned BitWidth,
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int64_t &OffsetByte, uint64_t &OffsetBit);
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// Set the stored value in each of Targets to VirtualCallTarget::RetVal at the
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// given allocation offset after the vtable address. Stores the computed
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// byte/bit offset to OffsetByte/OffsetBit.
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void setAfterReturnValues(MutableArrayRef<VirtualCallTarget> Targets,
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uint64_t AllocAfter, unsigned BitWidth,
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int64_t &OffsetByte, uint64_t &OffsetBit);
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} // end namespace wholeprogramdevirt
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struct WholeProgramDevirtPass : public PassInfoMixin<WholeProgramDevirtPass> {
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ModuleSummaryIndex *ExportSummary;
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const ModuleSummaryIndex *ImportSummary;
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bool UseCommandLine = false;
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WholeProgramDevirtPass()
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: ExportSummary(nullptr), ImportSummary(nullptr), UseCommandLine(true) {}
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WholeProgramDevirtPass(ModuleSummaryIndex *ExportSummary,
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const ModuleSummaryIndex *ImportSummary)
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: ExportSummary(ExportSummary), ImportSummary(ImportSummary) {
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assert(!(ExportSummary && ImportSummary));
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}
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PreservedAnalyses run(Module &M, ModuleAnalysisManager &);
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};
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struct VTableSlotSummary {
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StringRef TypeID;
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uint64_t ByteOffset;
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};
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void updateVCallVisibilityInModule(Module &M,
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bool WholeProgramVisibilityEnabledInLTO);
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void updateVCallVisibilityInIndex(ModuleSummaryIndex &Index,
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bool WholeProgramVisibilityEnabledInLTO);
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/// Perform index-based whole program devirtualization on the \p Summary
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/// index. Any devirtualized targets used by a type test in another module
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/// are added to the \p ExportedGUIDs set. For any local devirtualized targets
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/// only used within the defining module, the information necessary for
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/// locating the corresponding WPD resolution is recorded for the ValueInfo
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/// in case it is exported by cross module importing (in which case the
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/// devirtualized target name will need adjustment).
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void runWholeProgramDevirtOnIndex(
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ModuleSummaryIndex &Summary, std::set<GlobalValue::GUID> &ExportedGUIDs,
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std::map<ValueInfo, std::vector<VTableSlotSummary>> &LocalWPDTargetsMap);
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/// Call after cross-module importing to update the recorded single impl
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/// devirt target names for any locals that were exported.
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void updateIndexWPDForExports(
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ModuleSummaryIndex &Summary,
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function_ref<bool(StringRef, ValueInfo)> isExported,
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std::map<ValueInfo, std::vector<VTableSlotSummary>> &LocalWPDTargetsMap);
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} // end namespace llvm
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#endif // LLVM_TRANSFORMS_IPO_WHOLEPROGRAMDEVIRT_H
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