include/llvm/FuzzMutate/OpDescriptor.h - llvm - Git at Google

 //===-- OpDescriptor.h ------------------------------------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Provides the fuzzerop::Descriptor class and related tools for describing
 // operations an IR fuzzer can work with.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_FUZZMUTATE_OPDESCRIPTOR_H
 #define LLVM_FUZZMUTATE_OPDESCRIPTOR_H

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/IR/Constants.h"
 #include "llvm/IR/DerivedTypes.h"
 #include "llvm/IR/Instructions.h"
 #include "llvm/IR/Type.h"
 #include "llvm/IR/Value.h"
 #include <functional>

 namespace llvm {
 namespace fuzzerop {

 /// @{
 /// Populate a small list of potentially interesting constants of a given type.
 void makeConstantsWithType(Type *T, std::vector<Constant *> &Cs);
 std::vector<Constant *> makeConstantsWithType(Type *T);
 /// @}

 /// A matcher/generator for finding suitable values for the next source in an
 /// operation's partially completed argument list.
 ///
 /// Given that we're building some operation X and may have already filled some
 /// subset of its operands, this predicate determines if some value New is
 /// suitable for the next operand or generates a set of values that are
 /// suitable.
 class SourcePred {
 public:
   /// Given a list of already selected operands, returns whether a given new
   /// operand is suitable for the next operand.
   using PredT = std::function<bool(ArrayRef<Value *> Cur, const Value *New)>;
   /// Given a list of already selected operands and a set of valid base types
   /// for a fuzzer, generates a list of constants that could be used for the
   /// next operand.
   using MakeT = std::function<std::vector<Constant *>(
       ArrayRef<Value *> Cur, ArrayRef<Type *> BaseTypes)>;

 private:
   PredT Pred;
   MakeT Make;

 public:
   /// Create a fully general source predicate.
   SourcePred(PredT Pred, MakeT Make) : Pred(Pred), Make(Make) {}
   SourcePred(PredT Pred, NoneType) : Pred(Pred) {
     Make = [Pred](ArrayRef<Value *> Cur, ArrayRef<Type *> BaseTypes) {
       // Default filter just calls Pred on each of the base types.
       std::vector<Constant *> Result;
       for (Type *T : BaseTypes) {
         Constant *V = UndefValue::get(T);
         if (Pred(Cur, V))
           makeConstantsWithType(T, Result);
       }
       if (Result.empty())
         report_fatal_error("Predicate does not match for base types");
       return Result;
     };
   }

   /// Returns true if \c New is compatible for the argument after \c Cur
   bool matches(ArrayRef<Value *> Cur, const Value *New) {
     return Pred(Cur, New);
   }

   /// Generates a list of potential values for the argument after \c Cur.
   std::vector<Constant *> generate(ArrayRef<Value *> Cur,
                                    ArrayRef<Type *> BaseTypes) {
     return Make(Cur, BaseTypes);
   }
 };

 /// A description of some operation we can build while fuzzing IR.
 struct OpDescriptor {
   unsigned Weight;
   SmallVector<SourcePred, 2> SourcePreds;
   std::function<Value *(ArrayRef<Value *>, Instruction *)> BuilderFunc;
 };

 static inline SourcePred onlyType(Type *Only) {
   auto Pred = [Only](ArrayRef<Value *>, const Value *V) {
     return V->getType() == Only;
   };
   auto Make = [Only](ArrayRef<Value *>, ArrayRef<Type *>) {
     return makeConstantsWithType(Only);
   };
   return {Pred, Make};
 }

 static inline SourcePred anyType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     return !V->getType()->isVoidTy();
   };
   auto Make = None;
   return {Pred, Make};
 }

 static inline SourcePred anyIntType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     return V->getType()->isIntegerTy();
   };
   auto Make = None;
   return {Pred, Make};
 }

 static inline SourcePred anyFloatType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     return V->getType()->isFloatingPointTy();
   };
   auto Make = None;
   return {Pred, Make};
 }

 static inline SourcePred anyPtrType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     return V->getType()->isPointerTy() && !V->isSwiftError();
   };
   auto Make = [](ArrayRef<Value *>, ArrayRef<Type *> Ts) {
     std::vector<Constant *> Result;
     // TODO: Should these point at something?
     for (Type *T : Ts)
       Result.push_back(UndefValue::get(PointerType::getUnqual(T)));
     return Result;
   };
   return {Pred, Make};
 }

 static inline SourcePred sizedPtrType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     if (V->isSwiftError())
       return false;

     if (const auto *PtrT = dyn_cast<PointerType>(V->getType()))
       return PtrT->getElementType()->isSized();
     return false;
   };
   auto Make = [](ArrayRef<Value *>, ArrayRef<Type *> Ts) {
     std::vector<Constant *> Result;

     for (Type *T : Ts)
       if (T->isSized())
         Result.push_back(UndefValue::get(PointerType::getUnqual(T)));

     return Result;
   };
   return {Pred, Make};
 }

 static inline SourcePred anyAggregateType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     // We can't index zero sized arrays.
     if (isa<ArrayType>(V->getType()))
       return V->getType()->getArrayNumElements() > 0;

     // Structs can also be zero sized. I.e opaque types.
     if (isa<StructType>(V->getType()))
       return V->getType()->getStructNumElements() > 0;

     return V->getType()->isAggregateType();
   };
   // TODO: For now we only find aggregates in BaseTypes. It might be better to
   // manufacture them out of the base types in some cases.
   auto Find = None;
   return {Pred, Find};
 }

 static inline SourcePred anyVectorType() {
   auto Pred = [](ArrayRef<Value *>, const Value *V) {
     return V->getType()->isVectorTy();
   };
   // TODO: For now we only find vectors in BaseTypes. It might be better to
   // manufacture vectors out of the base types, but it's tricky to be sure
   // that's actually a reasonable type.
   auto Make = None;
   return {Pred, Make};
 }

 /// Match values that have the same type as the first source.
 static inline SourcePred matchFirstType() {
   auto Pred = [](ArrayRef<Value *> Cur, const Value *V) {
     assert(!Cur.empty() && "No first source yet");
     return V->getType() == Cur[0]->getType();
   };
   auto Make = [](ArrayRef<Value *> Cur, ArrayRef<Type *>) {
     assert(!Cur.empty() && "No first source yet");
     return makeConstantsWithType(Cur[0]->getType());
   };
   return {Pred, Make};
 }

 /// Match values that have the first source's scalar type.
 static inline SourcePred matchScalarOfFirstType() {
   auto Pred = [](ArrayRef<Value *> Cur, const Value *V) {
     assert(!Cur.empty() && "No first source yet");
     return V->getType() == Cur[0]->getType()->getScalarType();
   };
   auto Make = [](ArrayRef<Value *> Cur, ArrayRef<Type *>) {
     assert(!Cur.empty() && "No first source yet");
     return makeConstantsWithType(Cur[0]->getType()->getScalarType());
   };
   return {Pred, Make};
 }

 } // end fuzzerop namespace
 } // end llvm namespace

 #endif // LLVM_FUZZMUTATE_OPDESCRIPTOR_H
	//===-- OpDescriptor.h ------------------------------------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Provides the fuzzerop::Descriptor class and related tools for describing
	// operations an IR fuzzer can work with.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_FUZZMUTATE_OPDESCRIPTOR_H
	#define LLVM_FUZZMUTATE_OPDESCRIPTOR_H

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/IR/Constants.h"
	#include "llvm/IR/DerivedTypes.h"
	#include "llvm/IR/Instructions.h"
	#include "llvm/IR/Type.h"
	#include "llvm/IR/Value.h"
	#include <functional>

	namespace llvm {
	namespace fuzzerop {

	/// @{
	/// Populate a small list of potentially interesting constants of a given type.
	void makeConstantsWithType(Type T, std::vector<Constant > &Cs);
	std::vector<Constant > makeConstantsWithType(Type T);
	/// @}

	/// A matcher/generator for finding suitable values for the next source in an
	/// operation's partially completed argument list.
	///
	/// Given that we're building some operation X and may have already filled some
	/// subset of its operands, this predicate determines if some value New is
	/// suitable for the next operand or generates a set of values that are
	/// suitable.
	class SourcePred {
	public:
	/// Given a list of already selected operands, returns whether a given new
	/// operand is suitable for the next operand.
	using PredT = std::function<bool(ArrayRef<Value > Cur, const Value New)>;
	/// Given a list of already selected operands and a set of valid base types
	/// for a fuzzer, generates a list of constants that could be used for the
	/// next operand.
	using MakeT = std::function<std::vector<Constant *>(
	ArrayRef<Value > Cur, ArrayRef<Type > BaseTypes)>;

	private:
	PredT Pred;
	MakeT Make;

	public:
	/// Create a fully general source predicate.
	SourcePred(PredT Pred, MakeT Make) : Pred(Pred), Make(Make) {}
	SourcePred(PredT Pred, NoneType) : Pred(Pred) {
	Make = [Pred](ArrayRef<Value > Cur, ArrayRef<Type > BaseTypes) {
	// Default filter just calls Pred on each of the base types.
	std::vector<Constant *> Result;
	for (Type *T : BaseTypes) {
	Constant *V = UndefValue::get(T);
	if (Pred(Cur, V))
	makeConstantsWithType(T, Result);
	}
	if (Result.empty())
	report_fatal_error("Predicate does not match for base types");
	return Result;
	};
	}

	/// Returns true if \c New is compatible for the argument after \c Cur
	bool matches(ArrayRef<Value > Cur, const Value New) {
	return Pred(Cur, New);
	}

	/// Generates a list of potential values for the argument after \c Cur.
	std::vector<Constant > generate(ArrayRef<Value > Cur,
	ArrayRef<Type *> BaseTypes) {
	return Make(Cur, BaseTypes);
	}
	};

	/// A description of some operation we can build while fuzzing IR.
	struct OpDescriptor {
	unsigned Weight;
	SmallVector<SourcePred, 2> SourcePreds;
	std::function<Value (ArrayRef<Value >, Instruction *)> BuilderFunc;
	};

	static inline SourcePred onlyType(Type *Only) {
	auto Pred = [Only](ArrayRef<Value >, const Value V) {
	return V->getType() == Only;
	};
	auto Make = [Only](ArrayRef<Value >, ArrayRef<Type >) {
	return makeConstantsWithType(Only);
	};
	return {Pred, Make};
	}

	static inline SourcePred anyType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	return !V->getType()->isVoidTy();
	};
	auto Make = None;
	return {Pred, Make};
	}

	static inline SourcePred anyIntType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	return V->getType()->isIntegerTy();
	};
	auto Make = None;
	return {Pred, Make};
	}

	static inline SourcePred anyFloatType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	return V->getType()->isFloatingPointTy();
	};
	auto Make = None;
	return {Pred, Make};
	}

	static inline SourcePred anyPtrType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	return V->getType()->isPointerTy() && !V->isSwiftError();
	};
	auto Make = [](ArrayRef<Value >, ArrayRef<Type > Ts) {
	std::vector<Constant *> Result;
	// TODO: Should these point at something?
	for (Type *T : Ts)
	Result.push_back(UndefValue::get(PointerType::getUnqual(T)));
	return Result;
	};
	return {Pred, Make};
	}

	static inline SourcePred sizedPtrType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	if (V->isSwiftError())
	return false;

	if (const auto *PtrT = dyn_cast<PointerType>(V->getType()))
	return PtrT->getElementType()->isSized();
	return false;
	};
	auto Make = [](ArrayRef<Value >, ArrayRef<Type > Ts) {
	std::vector<Constant *> Result;

	for (Type *T : Ts)
	if (T->isSized())
	Result.push_back(UndefValue::get(PointerType::getUnqual(T)));

	return Result;
	};
	return {Pred, Make};
	}

	static inline SourcePred anyAggregateType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	// We can't index zero sized arrays.
	if (isa<ArrayType>(V->getType()))
	return V->getType()->getArrayNumElements() > 0;

	// Structs can also be zero sized. I.e opaque types.
	if (isa<StructType>(V->getType()))
	return V->getType()->getStructNumElements() > 0;

	return V->getType()->isAggregateType();
	};
	// TODO: For now we only find aggregates in BaseTypes. It might be better to
	// manufacture them out of the base types in some cases.
	auto Find = None;
	return {Pred, Find};
	}

	static inline SourcePred anyVectorType() {
	auto Pred = [](ArrayRef<Value >, const Value V) {
	return V->getType()->isVectorTy();
	};
	// TODO: For now we only find vectors in BaseTypes. It might be better to
	// manufacture vectors out of the base types, but it's tricky to be sure
	// that's actually a reasonable type.
	auto Make = None;
	return {Pred, Make};
	}

	/// Match values that have the same type as the first source.
	static inline SourcePred matchFirstType() {
	auto Pred = [](ArrayRef<Value > Cur, const Value V) {
	assert(!Cur.empty() && "No first source yet");
	return V->getType() == Cur[0]->getType();
	};
	auto Make = [](ArrayRef<Value > Cur, ArrayRef<Type >) {
	assert(!Cur.empty() && "No first source yet");
	return makeConstantsWithType(Cur[0]->getType());
	};
	return {Pred, Make};
	}

	/// Match values that have the first source's scalar type.
	static inline SourcePred matchScalarOfFirstType() {
	auto Pred = [](ArrayRef<Value > Cur, const Value V) {
	assert(!Cur.empty() && "No first source yet");
	return V->getType() == Cur[0]->getType()->getScalarType();
	};
	auto Make = [](ArrayRef<Value > Cur, ArrayRef<Type >) {
	assert(!Cur.empty() && "No first source yet");
	return makeConstantsWithType(Cur[0]->getType()->getScalarType());
	};
	return {Pred, Make};
	}

	} // end fuzzerop namespace
	} // end llvm namespace

	#endif // LLVM_FUZZMUTATE_OPDESCRIPTOR_H