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//===- ConstantInitBuilder.h - Builder for LLVM IR constants ----*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This class provides a convenient interface for building complex
// global initializers of the sort that are frequently required for
// language ABIs.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_CODEGEN_CONSTANTINITBUILDER_H
#define LLVM_CLANG_CODEGEN_CONSTANTINITBUILDER_H
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/GlobalValue.h"
#include "clang/AST/CharUnits.h"
#include "clang/CodeGen/ConstantInitFuture.h"
#include <vector>
namespace clang {
namespace CodeGen {
class CodeGenModule;
/// A convenience builder class for complex constant initializers,
/// especially for anonymous global structures used by various language
/// runtimes.
///
/// The basic usage pattern is expected to be something like:
/// ConstantInitBuilder builder(CGM);
/// auto toplevel = builder.beginStruct();
/// toplevel.addInt(CGM.SizeTy, widgets.size());
/// auto widgetArray = builder.beginArray();
/// for (auto &widget : widgets) {
/// auto widgetDesc = widgetArray.beginStruct();
/// widgetDesc.addInt(CGM.SizeTy, widget.getPower());
/// widgetDesc.add(CGM.GetAddrOfConstantString(widget.getName()));
/// widgetDesc.add(CGM.GetAddrOfGlobal(widget.getInitializerDecl()));
/// widgetDesc.finishAndAddTo(widgetArray);
/// }
/// widgetArray.finishAndAddTo(toplevel);
/// auto global = toplevel.finishAndCreateGlobal("WIDGET_LIST", Align,
/// /*constant*/ true);
class ConstantInitBuilderBase {
struct SelfReference {
llvm::GlobalVariable *Dummy;
llvm::SmallVector<llvm::Constant*, 4> Indices;
SelfReference(llvm::GlobalVariable *dummy) : Dummy(dummy) {}
};
CodeGenModule &CGM;
llvm::SmallVector<llvm::Constant*, 16> Buffer;
std::vector<SelfReference> SelfReferences;
bool Frozen = false;
friend class ConstantInitFuture;
friend class ConstantAggregateBuilderBase;
template <class, class>
friend class ConstantAggregateBuilderTemplateBase;
protected:
explicit ConstantInitBuilderBase(CodeGenModule &CGM) : CGM(CGM) {}
~ConstantInitBuilderBase() {
assert(Buffer.empty() && "didn't claim all values out of buffer");
assert(SelfReferences.empty() && "didn't apply all self-references");
}
private:
llvm::GlobalVariable *createGlobal(llvm::Constant *initializer,
const llvm::Twine &name,
CharUnits alignment,
bool constant = false,
llvm::GlobalValue::LinkageTypes linkage
= llvm::GlobalValue::InternalLinkage,
unsigned addressSpace = 0);
ConstantInitFuture createFuture(llvm::Constant *initializer);
void setGlobalInitializer(llvm::GlobalVariable *GV,
llvm::Constant *initializer);
void resolveSelfReferences(llvm::GlobalVariable *GV);
void abandon(size_t newEnd);
};
/// A concrete base class for struct and array aggregate
/// initializer builders.
class ConstantAggregateBuilderBase {
protected:
ConstantInitBuilderBase &Builder;
ConstantAggregateBuilderBase *Parent;
size_t Begin;
mutable size_t CachedOffsetEnd = 0;
bool Finished = false;
bool Frozen = false;
bool Packed = false;
mutable CharUnits CachedOffsetFromGlobal;
llvm::SmallVectorImpl<llvm::Constant*> &getBuffer() {
return Builder.Buffer;
}
const llvm::SmallVectorImpl<llvm::Constant*> &getBuffer() const {
return Builder.Buffer;
}
ConstantAggregateBuilderBase(ConstantInitBuilderBase &builder,
ConstantAggregateBuilderBase *parent)
: Builder(builder), Parent(parent), Begin(builder.Buffer.size()) {
if (parent) {
assert(!parent->Frozen && "parent already has child builder active");
parent->Frozen = true;
} else {
assert(!builder.Frozen && "builder already has child builder active");
builder.Frozen = true;
}
}
~ConstantAggregateBuilderBase() {
assert(Finished && "didn't finish aggregate builder");
}
void markFinished() {
assert(!Frozen && "child builder still active");
assert(!Finished && "builder already finished");
Finished = true;
if (Parent) {
assert(Parent->Frozen &&
"parent not frozen while child builder active");
Parent->Frozen = false;
} else {
assert(Builder.Frozen &&
"builder not frozen while child builder active");
Builder.Frozen = false;
}
}
public:
// Not copyable.
ConstantAggregateBuilderBase(const ConstantAggregateBuilderBase &) = delete;
ConstantAggregateBuilderBase &operator=(const ConstantAggregateBuilderBase &)
= delete;
// Movable, mostly to allow returning. But we have to write this out
// properly to satisfy the assert in the destructor.
ConstantAggregateBuilderBase(ConstantAggregateBuilderBase &&other)
: Builder(other.Builder), Parent(other.Parent), Begin(other.Begin),
CachedOffsetEnd(other.CachedOffsetEnd),
Finished(other.Finished), Frozen(other.Frozen), Packed(other.Packed),
CachedOffsetFromGlobal(other.CachedOffsetFromGlobal) {
other.Finished = true;
}
ConstantAggregateBuilderBase &operator=(ConstantAggregateBuilderBase &&other)
= delete;
/// Return the number of elements that have been added to
/// this struct or array.
size_t size() const {
assert(!this->Finished && "cannot query after finishing builder");
assert(!this->Frozen && "cannot query while sub-builder is active");
assert(this->Begin <= this->getBuffer().size());
return this->getBuffer().size() - this->Begin;
}
/// Return true if no elements have yet been added to this struct or array.
bool empty() const {
return size() == 0;
}
/// Abandon this builder completely.
void abandon() {
markFinished();
Builder.abandon(Begin);
}
/// Add a new value to this initializer.
void add(llvm::Constant *value) {
assert(value && "adding null value to constant initializer");
assert(!Finished && "cannot add more values after finishing builder");
assert(!Frozen && "cannot add values while subbuilder is active");
Builder.Buffer.push_back(value);
}
/// Add an integer value of type size_t.
void addSize(CharUnits size);
/// Add an integer value of a specific type.
void addInt(llvm::IntegerType *intTy, uint64_t value,
bool isSigned = false) {
add(llvm::ConstantInt::get(intTy, value, isSigned));
}
/// Add a null pointer of a specific type.
void addNullPointer(llvm::PointerType *ptrTy) {
add(llvm::ConstantPointerNull::get(ptrTy));
}
/// Add a bitcast of a value to a specific type.
void addBitCast(llvm::Constant *value, llvm::Type *type) {
add(llvm::ConstantExpr::getBitCast(value, type));
}
/// Add a bunch of new values to this initializer.
void addAll(llvm::ArrayRef<llvm::Constant *> values) {
assert(!Finished && "cannot add more values after finishing builder");
assert(!Frozen && "cannot add values while subbuilder is active");
Builder.Buffer.append(values.begin(), values.end());
}
/// Add a relative offset to the given target address, i.e. the
/// static difference between the target address and the address
/// of the relative offset. The target must be known to be defined
/// in the current linkage unit. The offset will have the given
/// integer type, which must be no wider than intptr_t. Some
/// targets may not fully support this operation.
void addRelativeOffset(llvm::IntegerType *type, llvm::Constant *target) {
add(getRelativeOffset(type, target));
}
/// Add a relative offset to the target address, plus a small
/// constant offset. This is primarily useful when the relative
/// offset is known to be a multiple of (say) four and therefore
/// the tag can be used to express an extra two bits of information.
void addTaggedRelativeOffset(llvm::IntegerType *type,
llvm::Constant *address,
unsigned tag) {
llvm::Constant *offset = getRelativeOffset(type, address);
if (tag) {
offset = llvm::ConstantExpr::getAdd(offset,
llvm::ConstantInt::get(type, tag));
}
add(offset);
}
/// Return the offset from the start of the initializer to the
/// next position, assuming no padding is required prior to it.
///
/// This operation will not succeed if any unsized placeholders are
/// currently in place in the initializer.
CharUnits getNextOffsetFromGlobal() const {
assert(!Finished && "cannot add more values after finishing builder");
assert(!Frozen && "cannot add values while subbuilder is active");
return getOffsetFromGlobalTo(Builder.Buffer.size());
}
/// An opaque class to hold the abstract position of a placeholder.
class PlaceholderPosition {
size_t Index;
friend class ConstantAggregateBuilderBase;
PlaceholderPosition(size_t index) : Index(index) {}
};
/// Add a placeholder value to the structure. The returned position
/// can be used to set the value later; it will not be invalidated by
/// any intermediate operations except (1) filling the same position or
/// (2) finishing the entire builder.
///
/// This is useful for emitting certain kinds of structure which
/// contain some sort of summary field, generally a count, before any
/// of the data. By emitting a placeholder first, the structure can
/// be emitted eagerly.
PlaceholderPosition addPlaceholder() {
assert(!Finished && "cannot add more values after finishing builder");
assert(!Frozen && "cannot add values while subbuilder is active");
Builder.Buffer.push_back(nullptr);
return Builder.Buffer.size() - 1;
}
/// Add a placeholder, giving the expected type that will be filled in.
PlaceholderPosition addPlaceholderWithSize(llvm::Type *expectedType);
/// Fill a previously-added placeholder.
void fillPlaceholderWithInt(PlaceholderPosition position,
llvm::IntegerType *type, uint64_t value,
bool isSigned = false) {
fillPlaceholder(position, llvm::ConstantInt::get(type, value, isSigned));
}
/// Fill a previously-added placeholder.
void fillPlaceholder(PlaceholderPosition position, llvm::Constant *value) {
assert(!Finished && "cannot change values after finishing builder");
assert(!Frozen && "cannot add values while subbuilder is active");
llvm::Constant *&slot = Builder.Buffer[position.Index];
assert(slot == nullptr && "placeholder already filled");
slot = value;
}
/// Produce an address which will eventually point to the next
/// position to be filled. This is computed with an indexed
/// getelementptr rather than by computing offsets.
///
/// The returned pointer will have type T*, where T is the given
/// position.
llvm::Constant *getAddrOfCurrentPosition(llvm::Type *type);
llvm::ArrayRef<llvm::Constant*> getGEPIndicesToCurrentPosition(
llvm::SmallVectorImpl<llvm::Constant*> &indices) {
getGEPIndicesTo(indices, Builder.Buffer.size());
return indices;
}
protected:
llvm::Constant *finishArray(llvm::Type *eltTy);
llvm::Constant *finishStruct(llvm::StructType *structTy);
private:
void getGEPIndicesTo(llvm::SmallVectorImpl<llvm::Constant*> &indices,
size_t position) const;
llvm::Constant *getRelativeOffset(llvm::IntegerType *offsetType,
llvm::Constant *target);
CharUnits getOffsetFromGlobalTo(size_t index) const;
};
template <class Impl, class Traits>
class ConstantAggregateBuilderTemplateBase
: public Traits::AggregateBuilderBase {
using super = typename Traits::AggregateBuilderBase;
public:
using InitBuilder = typename Traits::InitBuilder;
using ArrayBuilder = typename Traits::ArrayBuilder;
using StructBuilder = typename Traits::StructBuilder;
using AggregateBuilderBase = typename Traits::AggregateBuilderBase;
protected:
ConstantAggregateBuilderTemplateBase(InitBuilder &builder,
AggregateBuilderBase *parent)
: super(builder, parent) {}
Impl &asImpl() { return *static_cast<Impl*>(this); }
public:
ArrayBuilder beginArray(llvm::Type *eltTy = nullptr) {
return ArrayBuilder(static_cast<InitBuilder&>(this->Builder), this, eltTy);
}
StructBuilder beginStruct(llvm::StructType *ty = nullptr) {
return StructBuilder(static_cast<InitBuilder&>(this->Builder), this, ty);
}
/// Given that this builder was created by beginning an array or struct
/// component on the given parent builder, finish the array/struct
/// component and add it to the parent.
///
/// It is an intentional choice that the parent is passed in explicitly
/// despite it being redundant with information already kept in the
/// builder. This aids in readability by making it easier to find the
/// places that add components to a builder, as well as "bookending"
/// the sub-builder more explicitly.
void finishAndAddTo(AggregateBuilderBase &parent) {
assert(this->Parent == &parent && "adding to non-parent builder");
parent.add(asImpl().finishImpl());
}
/// Given that this builder was created by beginning an array or struct
/// directly on a ConstantInitBuilder, finish the array/struct and
/// create a global variable with it as the initializer.
template <class... As>
llvm::GlobalVariable *finishAndCreateGlobal(As &&...args) {
assert(!this->Parent && "finishing non-root builder");
return this->Builder.createGlobal(asImpl().finishImpl(),
std::forward<As>(args)...);
}
/// Given that this builder was created by beginning an array or struct
/// directly on a ConstantInitBuilder, finish the array/struct and
/// set it as the initializer of the given global variable.
void finishAndSetAsInitializer(llvm::GlobalVariable *global) {
assert(!this->Parent && "finishing non-root builder");
return this->Builder.setGlobalInitializer(global, asImpl().finishImpl());
}
/// Given that this builder was created by beginning an array or struct
/// directly on a ConstantInitBuilder, finish the array/struct and
/// return a future which can be used to install the initializer in
/// a global later.
///
/// This is useful for allowing a finished initializer to passed to
/// an API which will build the global. However, the "future" preserves
/// a dependency on the original builder; it is an error to pass it aside.
ConstantInitFuture finishAndCreateFuture() {
assert(!this->Parent && "finishing non-root builder");
return this->Builder.createFuture(asImpl().finishImpl());
}
};
template <class Traits>
class ConstantArrayBuilderTemplateBase
: public ConstantAggregateBuilderTemplateBase<typename Traits::ArrayBuilder,
Traits> {
using super =
ConstantAggregateBuilderTemplateBase<typename Traits::ArrayBuilder, Traits>;
public:
using InitBuilder = typename Traits::InitBuilder;
using AggregateBuilderBase = typename Traits::AggregateBuilderBase;
private:
llvm::Type *EltTy;
template <class, class>
friend class ConstantAggregateBuilderTemplateBase;
protected:
ConstantArrayBuilderTemplateBase(InitBuilder &builder,
AggregateBuilderBase *parent,
llvm::Type *eltTy)
: super(builder, parent), EltTy(eltTy) {}
private:
/// Form an array constant from the values that have been added to this
/// builder.
llvm::Constant *finishImpl() {
return AggregateBuilderBase::finishArray(EltTy);
}
};
/// A template class designed to allow other frontends to
/// easily customize the builder classes used by ConstantInitBuilder,
/// and thus to extend the API to work with the abstractions they
/// prefer. This would probably not be necessary if C++ just
/// supported extension methods.
template <class Traits>
class ConstantStructBuilderTemplateBase
: public ConstantAggregateBuilderTemplateBase<typename Traits::StructBuilder,
Traits> {
using super =
ConstantAggregateBuilderTemplateBase<typename Traits::StructBuilder,Traits>;
public:
using InitBuilder = typename Traits::InitBuilder;
using AggregateBuilderBase = typename Traits::AggregateBuilderBase;
private:
llvm::StructType *StructTy;
template <class, class>
friend class ConstantAggregateBuilderTemplateBase;
protected:
ConstantStructBuilderTemplateBase(InitBuilder &builder,
AggregateBuilderBase *parent,
llvm::StructType *structTy)
: super(builder, parent), StructTy(structTy) {
if (structTy) this->Packed = structTy->isPacked();
}
public:
void setPacked(bool packed) {
this->Packed = packed;
}
/// Use the given type for the struct if its element count is correct.
/// Don't add more elements after calling this.
void suggestType(llvm::StructType *structTy) {
if (this->size() == structTy->getNumElements()) {
StructTy = structTy;
}
}
private:
/// Form an array constant from the values that have been added to this
/// builder.
llvm::Constant *finishImpl() {
return AggregateBuilderBase::finishStruct(StructTy);
}
};
/// A template class designed to allow other frontends to
/// easily customize the builder classes used by ConstantInitBuilder,
/// and thus to extend the API to work with the abstractions they
/// prefer. This would probably not be necessary if C++ just
/// supported extension methods.
template <class Traits>
class ConstantInitBuilderTemplateBase : public ConstantInitBuilderBase {
protected:
ConstantInitBuilderTemplateBase(CodeGenModule &CGM)
: ConstantInitBuilderBase(CGM) {}
public:
using InitBuilder = typename Traits::InitBuilder;
using ArrayBuilder = typename Traits::ArrayBuilder;
using StructBuilder = typename Traits::StructBuilder;
ArrayBuilder beginArray(llvm::Type *eltTy = nullptr) {
return ArrayBuilder(static_cast<InitBuilder&>(*this), nullptr, eltTy);
}
StructBuilder beginStruct(llvm::StructType *structTy = nullptr) {
return StructBuilder(static_cast<InitBuilder&>(*this), nullptr, structTy);
}
};
class ConstantInitBuilder;
class ConstantStructBuilder;
class ConstantArrayBuilder;
struct ConstantInitBuilderTraits {
using InitBuilder = ConstantInitBuilder;
using AggregateBuilderBase = ConstantAggregateBuilderBase;
using ArrayBuilder = ConstantArrayBuilder;
using StructBuilder = ConstantStructBuilder;
};
/// The standard implementation of ConstantInitBuilder used in Clang.
class ConstantInitBuilder
: public ConstantInitBuilderTemplateBase<ConstantInitBuilderTraits> {
public:
explicit ConstantInitBuilder(CodeGenModule &CGM) :
ConstantInitBuilderTemplateBase(CGM) {}
};
/// A helper class of ConstantInitBuilder, used for building constant
/// array initializers.
class ConstantArrayBuilder
: public ConstantArrayBuilderTemplateBase<ConstantInitBuilderTraits> {
template <class Traits>
friend class ConstantInitBuilderTemplateBase;
// The use of explicit qualification is a GCC workaround.
template <class Impl, class Traits>
friend class CodeGen::ConstantAggregateBuilderTemplateBase;
ConstantArrayBuilder(ConstantInitBuilder &builder,
ConstantAggregateBuilderBase *parent,
llvm::Type *eltTy)
: ConstantArrayBuilderTemplateBase(builder, parent, eltTy) {}
};
/// A helper class of ConstantInitBuilder, used for building constant
/// struct initializers.
class ConstantStructBuilder
: public ConstantStructBuilderTemplateBase<ConstantInitBuilderTraits> {
template <class Traits>
friend class ConstantInitBuilderTemplateBase;
// The use of explicit qualification is a GCC workaround.
template <class Impl, class Traits>
friend class CodeGen::ConstantAggregateBuilderTemplateBase;
ConstantStructBuilder(ConstantInitBuilder &builder,
ConstantAggregateBuilderBase *parent,
llvm::StructType *structTy)
: ConstantStructBuilderTemplateBase(builder, parent, structTy) {}
};
} // end namespace CodeGen
} // end namespace clang
#endif