startop/view_compiler/dex_builder.h - LeafOS-Project/android_frameworks_base - Gitiles

 /*
  * Copyright (C) 2018 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 #ifndef DEX_BUILDER_H_
 #define DEX_BUILDER_H_

 #include <forward_list>
 #include <map>
 #include <optional>
 #include <string>
 #include <unordered_map>
 #include <vector>

 #include "dex/dex_instruction.h"
 #include "slicer/dex_ir.h"
 #include "slicer/writer.h"

 namespace startop {
 namespace dex {

 // TODO: remove this once the dex generation code is complete.
 void WriteTestDexFile(const std::string& filename);

 //////////////////////////
 // Forward declarations //
 //////////////////////////
 class DexBuilder;

 // Our custom allocator for dex::Writer
 //
 // This keeps track of all allocations and ensures they are freed when
 // TrackingAllocator is destroyed. Pointers to memory allocated by this
 // allocator must not outlive the allocator.
 class TrackingAllocator : public ::dex::Writer::Allocator {
  public:
   virtual void* Allocate(size_t size);
   virtual void Free(void* ptr);

  private:
   std::unordered_map<void*, std::unique_ptr<uint8_t[]>> allocations_;
 };

 // Represents a DEX type descriptor.
 //
 // TODO: add a way to create a descriptor for a reference of a class type.
 class TypeDescriptor {
  public:
   // Named constructors for base type descriptors.
   static const TypeDescriptor Int();
   static const TypeDescriptor Void();

   // Creates a type descriptor from a fully-qualified class name. For example, it turns the class
   // name java.lang.Object into the descriptor Ljava/lang/Object.
   static TypeDescriptor FromClassname(const std::string& name);

   // Return the full descriptor, such as I or Ljava/lang/Object
   const std::string& descriptor() const { return descriptor_; }
   // Return the shorty descriptor, such as I or L
   std::string short_descriptor() const { return descriptor().substr(0, 1); }

   bool operator<(const TypeDescriptor& rhs) const { return descriptor_ < rhs.descriptor_; }

  private:
   explicit TypeDescriptor(std::string descriptor) : descriptor_{descriptor} {}

   const std::string descriptor_;
 };

 // Defines a function signature. For example, Prototype{TypeDescriptor::VOID, TypeDescriptor::Int}
 // represents the function type (Int) -> Void.
 class Prototype {
  public:
   template <typename... TypeDescriptors>
   explicit Prototype(TypeDescriptor return_type, TypeDescriptors... param_types)
       : return_type_{return_type}, param_types_{param_types...} {}

   // Encode this prototype into the dex file.
   ir::Proto* Encode(DexBuilder* dex) const;

   // Get the shorty descriptor, such as VII for (Int, Int) -> Void
   std::string Shorty() const;

   bool operator<(const Prototype& rhs) const {
     return std::make_tuple(return_type_, param_types_) <
            std::make_tuple(rhs.return_type_, rhs.param_types_);
   }

  private:
   const TypeDescriptor return_type_;
   const std::vector<TypeDescriptor> param_types_;
 };

 // Represents a DEX register or constant. We separate regular registers and parameters
 // because we will not know the real parameter id until after all instructions
 // have been generated.
 class Value {
  public:
   static constexpr Value Local(size_t id) { return Value{id, Kind::kLocalRegister}; }
   static constexpr Value Parameter(size_t id) { return Value{id, Kind::kParameter}; }
   static constexpr Value Immediate(size_t value) { return Value{value, Kind::kImmediate}; }
   static constexpr Value String(size_t value) { return Value{value, Kind::kString}; }
   static constexpr Value Label(size_t id) { return Value{id, Kind::kLabel}; }
   static constexpr Value Type(size_t id) { return Value{id, Kind::kType}; }

   bool is_register() const { return kind_ == Kind::kLocalRegister; }
   bool is_parameter() const { return kind_ == Kind::kParameter; }
   bool is_variable() const { return is_register() || is_parameter(); }
   bool is_immediate() const { return kind_ == Kind::kImmediate; }
   bool is_string() const { return kind_ == Kind::kString; }
   bool is_label() const { return kind_ == Kind::kLabel; }
   bool is_type() const { return kind_ == Kind::kType; }

   size_t value() const { return value_; }

  private:
   enum class Kind { kLocalRegister, kParameter, kImmediate, kString, kLabel, kType };

   const size_t value_;
   const Kind kind_;

   constexpr Value(size_t value, Kind kind) : value_{value}, kind_{kind} {}
 };

 // A virtual instruction. We convert these to real instructions in MethodBuilder::Encode.
 // Virtual instructions are needed to keep track of information that is not known until all of the
 // code is generated. This information includes things like how many local registers are created and
 // branch target locations.
 class Instruction {
  public:
   // The operation performed by this instruction. These are virtual instructions that do not
   // correspond exactly to DEX instructions.
   enum class Op {
     kBindLabel,
     kBranchEqz,
     kBranchNEqz,
     kCheckCast,
     kInvokeDirect,
     kInvokeInterface,
     kInvokeStatic,
     kInvokeVirtual,
     kMove,
     kNew,
     kReturn,
     kReturnObject,
   };

   ////////////////////////
   // Named Constructors //
   ////////////////////////

   // For instructions with no return value and no arguments.
   static inline Instruction OpNoArgs(Op opcode) {
     return Instruction{opcode, /*method_id*/ 0, /*dest*/ {}};
   }
   // For most instructions, which take some number of arguments and have an optional return value.
   template <typename... T>
   static inline Instruction OpWithArgs(Op opcode, std::optional<const Value> dest, T... args) {
     return Instruction{opcode, /*method_id=*/0, /*result_is_object=*/false, dest, args...};
   }

   // A cast instruction. Basically, `(type)val`
   static inline Instruction Cast(Value val, Value type) {
     DCHECK(type.is_type());
     return OpWithArgs(Op::kCheckCast, val, type);
   }

   // For method calls.
   template <typename... T>
   static inline Instruction InvokeVirtual(size_t method_id, std::optional<const Value> dest,
                                           Value this_arg, T... args) {
     return Instruction{
         Op::kInvokeVirtual, method_id, /*result_is_object=*/false, dest, this_arg, args...};
   }
   // Returns an object
   template <typename... T>
   static inline Instruction InvokeVirtualObject(size_t method_id, std::optional<const Value> dest,
                                                 Value this_arg, T... args) {
     return Instruction{
         Op::kInvokeVirtual, method_id, /*result_is_object=*/true, dest, this_arg, args...};
   }
   // For direct calls (basically, constructors).
   template <typename... T>
   static inline Instruction InvokeDirect(size_t method_id, std::optional<const Value> dest,
                                          Value this_arg, T... args) {
     return Instruction{
         Op::kInvokeDirect, method_id, /*result_is_object=*/false, dest, this_arg, args...};
   }
   // Returns an object
   template <typename... T>
   static inline Instruction InvokeDirectObject(size_t method_id, std::optional<const Value> dest,
                                                Value this_arg, T... args) {
     return Instruction{
         Op::kInvokeDirect, method_id, /*result_is_object=*/true, dest, this_arg, args...};
   }
   // For static calls.
   template <typename... T>
   static inline Instruction InvokeStatic(size_t method_id, std::optional<const Value> dest,
                                          T... args) {
     return Instruction{Op::kInvokeStatic, method_id, /*result_is_object=*/false, dest, args...};
   }
   // Returns an object
   template <typename... T>
   static inline Instruction InvokeStaticObject(size_t method_id, std::optional<const Value> dest,
                                                T... args) {
     return Instruction{Op::kInvokeStatic, method_id, /*result_is_object=*/true, dest, args...};
   }
   // For static calls.
   template <typename... T>
   static inline Instruction InvokeInterface(size_t method_id, std::optional<const Value> dest,
                                             T... args) {
     return Instruction{Op::kInvokeInterface, method_id, /*result_is_object=*/false, dest, args...};
   }

   ///////////////
   // Accessors //
   ///////////////

   Op opcode() const { return opcode_; }
   size_t method_id() const { return method_id_; }
   bool result_is_object() const { return result_is_object_; }
   const std::optional<const Value>& dest() const { return dest_; }
   const std::vector<const Value>& args() const { return args_; }

  private:
   inline Instruction(Op opcode, size_t method_id, std::optional<const Value> dest)
       : opcode_{opcode}, method_id_{method_id}, result_is_object_{false}, dest_{dest}, args_{} {}

   template <typename... T>
   inline constexpr Instruction(Op opcode, size_t method_id, bool result_is_object,
                                std::optional<const Value> dest, T... args)
       : opcode_{opcode},
         method_id_{method_id},
         result_is_object_{result_is_object},
         dest_{dest},
         args_{args...} {}

   const Op opcode_;
   // The index of the method to invoke, for kInvokeVirtual and similar opcodes.
   const size_t method_id_{0};
   const bool result_is_object_;
   const std::optional<const Value> dest_;
   const std::vector<const Value> args_;
 };

 // Needed for CHECK_EQ, DCHECK_EQ, etc.
 std::ostream& operator<<(std::ostream& out, const Instruction::Op& opcode);

 // Keeps track of information needed to manipulate or call a method.
 struct MethodDeclData {
   size_t id;
   ir::MethodDecl* decl;
 };

 // Tools to help build methods and their bodies.
 class MethodBuilder {
  public:
   MethodBuilder(DexBuilder* dex, ir::Class* class_def, ir::MethodDecl* decl);

   // Encode the method into DEX format.
   ir::EncodedMethod* Encode();

   // Create a new register to be used to storing values. Note that these are not SSA registers, like
   // might be expected in similar code generators. This does no liveness tracking or anything, so
   // it's up to the caller to reuse registers as appropriate.
   Value MakeRegister();

   Value MakeLabel();

   /////////////////////////////////
   // Instruction builder methods //
   /////////////////////////////////

   void AddInstruction(Instruction instruction);

   // return-void
   void BuildReturn();
   void BuildReturn(Value src, bool is_object = false);
   // const/4
   void BuildConst4(Value target, int value);
   void BuildConstString(Value target, const std::string& value);
   template <typename... T>
   void BuildNew(Value target, TypeDescriptor type, Prototype constructor, T... args);

   // TODO: add builders for more instructions

   DexBuilder* dex_file() const { return dex_; }

  private:
   void EncodeInstructions();
   void EncodeInstruction(const Instruction& instruction);

   // Encodes a return instruction. For instructions with no return value, the opcode field is
   // ignored. Otherwise, this specifies which return instruction will be used (return,
   // return-object, etc.)
   void EncodeReturn(const Instruction& instruction, ::art::Instruction::Code opcode);

   void EncodeMove(const Instruction& instruction);
   void EncodeInvoke(const Instruction& instruction, ::art::Instruction::Code opcode);
   void EncodeBranch(art::Instruction::Code op, const Instruction& instruction);
   void EncodeNew(const Instruction& instruction);
   void EncodeCast(const Instruction& instruction);

   // Low-level instruction format encoding. See
   // https://source.android.com/devices/tech/dalvik/instruction-formats for documentation of
   // formats.

   inline void Encode10x(art::Instruction::Code opcode) {
     // 00|op
     buffer_.push_back(opcode);
   }

   inline void Encode11x(art::Instruction::Code opcode, uint8_t a) {
     // aa|op
     buffer_.push_back((a << 8) | opcode);
   }

   inline void Encode11n(art::Instruction::Code opcode, uint8_t a, int8_t b) {
     // b|a|op

     // Make sure the fields are in bounds (4 bits for a, 4 bits for b).
     CHECK_LT(a, 16);
     CHECK_LE(-8, b);
     CHECK_LT(b, 8);

     buffer_.push_back(((b & 0xf) << 12) | (a << 8) | opcode);
   }

   inline void Encode21c(art::Instruction::Code opcode, uint8_t a, uint16_t b) {
     // aa|op|bbbb
     buffer_.push_back((a << 8) | opcode);
     buffer_.push_back(b);
   }

   inline void Encode35c(art::Instruction::Code opcode, size_t a, uint16_t b, uint8_t c, uint8_t d,
                         uint8_t e, uint8_t f, uint8_t g) {
     // a|g|op|bbbb|f|e|d|c

     CHECK_LE(a, 5);
     CHECK_LT(c, 16);
     CHECK_LT(d, 16);
     CHECK_LT(e, 16);
     CHECK_LT(f, 16);
     CHECK_LT(g, 16);
     buffer_.push_back((a << 12) | (g << 8) | opcode);
     buffer_.push_back(b);
     buffer_.push_back((f << 12) | (e << 8) | (d << 4) | c);
   }

   // Converts a register or parameter to its DEX register number.
   size_t RegisterValue(const Value& value) const;

   // Sets a label's address to the current position in the instruction buffer. If there are any
   // forward references to the label, this function will back-patch them.
   void BindLabel(const Value& label);

   // Returns the offset of the label relative to the given instruction offset. If the label is not
   // bound, a reference will be saved and it will automatically be patched when the label is bound.
   ::dex::u2 LabelValue(const Value& label, size_t instruction_offset, size_t field_offset);

   DexBuilder* dex_;
   ir::Class* class_;
   ir::MethodDecl* decl_;

   // A list of the instructions we will eventually encode.
   std::vector<Instruction> instructions_;

   // A buffer to hold instructions that have been encoded.
   std::vector<::dex::u2> buffer_;

   // How many registers we've allocated
   size_t num_registers_{0};

   // Stores information needed to back-patch a label once it is bound. We need to know the start of
   // the instruction that refers to the label, and the offset to where the actual label value should
   // go.
   struct LabelReference {
     size_t instruction_offset;
     size_t field_offset;
   };

   struct LabelData {
     std::optional<size_t> bound_address;
     std::forward_list<LabelReference> references;
   };

   std::vector<LabelData> labels_;

   // During encoding, keep track of the largest number of arguments needed, so we can use it for our
   // outs count
   size_t max_args_{0};
 };

 // A helper to build class definitions.
 class ClassBuilder {
  public:
   ClassBuilder(DexBuilder* parent, const std::string& name, ir::Class* class_def);

   void set_source_file(const std::string& source);

   // Create a method with the given name and prototype. The returned MethodBuilder can be used to
   // fill in the method body.
   MethodBuilder CreateMethod(const std::string& name, Prototype prototype);

  private:
   DexBuilder* const parent_;
   const TypeDescriptor type_descriptor_;
   ir::Class* const class_;
 };

 // Builds Dex files from scratch.
 class DexBuilder {
  public:
   DexBuilder();

   // Create an in-memory image of the DEX file that can either be loaded directly or written to a
   // file.
   slicer::MemView CreateImage();

   template <typename T>
   T* Alloc() {
     return dex_file_->Alloc<T>();
   }

   // Find the ir::String that matches the given string, creating it if it does not exist.
   ir::String* GetOrAddString(const std::string& string);
   // Create a new class of the given name.
   ClassBuilder MakeClass(const std::string& name);

   // Add a type for the given descriptor, or return the existing one if it already exists.
   // See the TypeDescriptor class for help generating these. GetOrAddType can be used to declare
   // imported classes.
   ir::Type* GetOrAddType(const std::string& descriptor);

   // Returns the method id for the method, creating it if it has not been created yet.
   const MethodDeclData& GetOrDeclareMethod(TypeDescriptor type, const std::string& name,
                                            Prototype prototype);

  private:
   // Looks up the ir::Proto* corresponding to this given prototype, or creates one if it does not
   // exist.
   ir::Proto* GetOrEncodeProto(Prototype prototype);

   std::shared_ptr<ir::DexFile> dex_file_;

   // allocator_ is needed to be able to encode the image.
   TrackingAllocator allocator_;

   // We'll need to allocate buffers for all of the encoded strings we create. This is where we store
   // all of them.
   std::vector<std::unique_ptr<uint8_t[]>> string_data_;

   // Keep track of what types we've defined so we can look them up later.
   std::unordered_map<std::string, ir::Type*> types_by_descriptor_;

   struct MethodDescriptor {
     TypeDescriptor type;
     std::string name;
     Prototype prototype;

     inline bool operator<(const MethodDescriptor& rhs) const {
       return std::make_tuple(type, name, prototype) <
              std::make_tuple(rhs.type, rhs.name, rhs.prototype);
     }
   };

   // Maps method declarations to their method index. This is needed to encode references to them.
   // When we go to actually write the DEX file, slicer will re-assign these after correctly sorting
   // the methods list.
   std::map<MethodDescriptor, MethodDeclData> method_id_map_;

   // Keep track of what strings we've defined so we can look them up later.
   std::unordered_map<std::string, ir::String*> strings_;

   // Keep track of already-encoded protos.
   std::map<Prototype, ir::Proto*> proto_map_;
 };

 template <typename... T>
 void MethodBuilder::BuildNew(Value target, TypeDescriptor type, Prototype constructor, T... args) {
   MethodDeclData constructor_data{dex_->GetOrDeclareMethod(type, "<init>", constructor)};
   // allocate the object
   ir::Type* type_def = dex_->GetOrAddType(type.descriptor());
   AddInstruction(
       Instruction::OpWithArgs(Instruction::Op::kNew, target, Value::Type(type_def->orig_index)));
   // call the constructor
   AddInstruction(Instruction::InvokeDirect(constructor_data.id, /*dest=*/{}, target, args...));
 };

 }  // namespace dex
 }  // namespace startop

 #endif  // DEX_BUILDER_H_
	/*
	* Copyright (C) 2018 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	#ifndef DEX_BUILDER_H_
	#define DEX_BUILDER_H_

	#include <forward_list>
	#include <map>
	#include <optional>
	#include <string>
	#include <unordered_map>
	#include <vector>

	#include "dex/dex_instruction.h"
	#include "slicer/dex_ir.h"
	#include "slicer/writer.h"

	namespace startop {
	namespace dex {

	// TODO: remove this once the dex generation code is complete.
	void WriteTestDexFile(const std::string& filename);

	//////////////////////////
	// Forward declarations //
	//////////////////////////
	class DexBuilder;

	// Our custom allocator for dex::Writer
	//
	// This keeps track of all allocations and ensures they are freed when
	// TrackingAllocator is destroyed. Pointers to memory allocated by this
	// allocator must not outlive the allocator.
	class TrackingAllocator : public ::dex::Writer::Allocator {
	public:
	virtual void* Allocate(size_t size);
	virtual void Free(void* ptr);

	private:
	std::unordered_map<void*, std::unique_ptr<uint8_t[]>> allocations_;
	};

	// Represents a DEX type descriptor.
	//
	// TODO: add a way to create a descriptor for a reference of a class type.
	class TypeDescriptor {
	public:
	// Named constructors for base type descriptors.
	static const TypeDescriptor Int();
	static const TypeDescriptor Void();

	// Creates a type descriptor from a fully-qualified class name. For example, it turns the class
	// name java.lang.Object into the descriptor Ljava/lang/Object.
	static TypeDescriptor FromClassname(const std::string& name);

	// Return the full descriptor, such as I or Ljava/lang/Object
	const std::string& descriptor() const { return descriptor_; }
	// Return the shorty descriptor, such as I or L
	std::string short_descriptor() const { return descriptor().substr(0, 1); }

	bool operator<(const TypeDescriptor& rhs) const { return descriptor_ < rhs.descriptor_; }

	private:
	explicit TypeDescriptor(std::string descriptor) : descriptor_{descriptor} {}

	const std::string descriptor_;
	};

	// Defines a function signature. For example, Prototype{TypeDescriptor::VOID, TypeDescriptor::Int}
	// represents the function type (Int) -> Void.
	class Prototype {
	public:
	template <typename... TypeDescriptors>
	explicit Prototype(TypeDescriptor return_type, TypeDescriptors... param_types)
	: return_type_{return_type}, param_types_{param_types...} {}

	// Encode this prototype into the dex file.
	ir::Proto* Encode(DexBuilder* dex) const;

	// Get the shorty descriptor, such as VII for (Int, Int) -> Void
	std::string Shorty() const;

	bool operator<(const Prototype& rhs) const {
	return std::make_tuple(return_type_, param_types_) <
	std::make_tuple(rhs.return_type_, rhs.param_types_);
	}

	private:
	const TypeDescriptor return_type_;
	const std::vector<TypeDescriptor> param_types_;
	};

	// Represents a DEX register or constant. We separate regular registers and parameters
	// because we will not know the real parameter id until after all instructions
	// have been generated.
	class Value {
	public:
	static constexpr Value Local(size_t id) { return Value{id, Kind::kLocalRegister}; }
	static constexpr Value Parameter(size_t id) { return Value{id, Kind::kParameter}; }
	static constexpr Value Immediate(size_t value) { return Value{value, Kind::kImmediate}; }
	static constexpr Value String(size_t value) { return Value{value, Kind::kString}; }
	static constexpr Value Label(size_t id) { return Value{id, Kind::kLabel}; }
	static constexpr Value Type(size_t id) { return Value{id, Kind::kType}; }

	bool is_register() const { return kind_ == Kind::kLocalRegister; }
	bool is_parameter() const { return kind_ == Kind::kParameter; }
	bool is_variable() const { return is_register() \|\| is_parameter(); }
	bool is_immediate() const { return kind_ == Kind::kImmediate; }
	bool is_string() const { return kind_ == Kind::kString; }
	bool is_label() const { return kind_ == Kind::kLabel; }
	bool is_type() const { return kind_ == Kind::kType; }

	size_t value() const { return value_; }

	private:
	enum class Kind { kLocalRegister, kParameter, kImmediate, kString, kLabel, kType };

	const size_t value_;
	const Kind kind_;

	constexpr Value(size_t value, Kind kind) : value_{value}, kind_{kind} {}
	};

	// A virtual instruction. We convert these to real instructions in MethodBuilder::Encode.
	// Virtual instructions are needed to keep track of information that is not known until all of the
	// code is generated. This information includes things like how many local registers are created and
	// branch target locations.
	class Instruction {
	public:
	// The operation performed by this instruction. These are virtual instructions that do not
	// correspond exactly to DEX instructions.
	enum class Op {
	kBindLabel,
	kBranchEqz,
	kBranchNEqz,
	kCheckCast,
	kInvokeDirect,
	kInvokeInterface,
	kInvokeStatic,
	kInvokeVirtual,
	kMove,
	kNew,
	kReturn,
	kReturnObject,
	};

	////////////////////////
	// Named Constructors //
	////////////////////////

	// For instructions with no return value and no arguments.
	static inline Instruction OpNoArgs(Op opcode) {
	return Instruction{opcode, /method_id/ 0, /dest/ {}};
	}
	// For most instructions, which take some number of arguments and have an optional return value.
	template <typename... T>
	static inline Instruction OpWithArgs(Op opcode, std::optional<const Value> dest, T... args) {
	return Instruction{opcode, /method_id=/0, /result_is_object=/false, dest, args...};
	}

	// A cast instruction. Basically, `(type)val`
	static inline Instruction Cast(Value val, Value type) {
	DCHECK(type.is_type());
	return OpWithArgs(Op::kCheckCast, val, type);
	}

	// For method calls.
	template <typename... T>
	static inline Instruction InvokeVirtual(size_t method_id, std::optional<const Value> dest,
	Value this_arg, T... args) {
	return Instruction{
	Op::kInvokeVirtual, method_id, /result_is_object=/false, dest, this_arg, args...};
	}
	// Returns an object
	template <typename... T>
	static inline Instruction InvokeVirtualObject(size_t method_id, std::optional<const Value> dest,
	Value this_arg, T... args) {
	return Instruction{
	Op::kInvokeVirtual, method_id, /result_is_object=/true, dest, this_arg, args...};
	}
	// For direct calls (basically, constructors).
	template <typename... T>
	static inline Instruction InvokeDirect(size_t method_id, std::optional<const Value> dest,
	Value this_arg, T... args) {
	return Instruction{
	Op::kInvokeDirect, method_id, /result_is_object=/false, dest, this_arg, args...};
	}
	// Returns an object
	template <typename... T>
	static inline Instruction InvokeDirectObject(size_t method_id, std::optional<const Value> dest,
	Value this_arg, T... args) {
	return Instruction{
	Op::kInvokeDirect, method_id, /result_is_object=/true, dest, this_arg, args...};
	}
	// For static calls.
	template <typename... T>
	static inline Instruction InvokeStatic(size_t method_id, std::optional<const Value> dest,
	T... args) {
	return Instruction{Op::kInvokeStatic, method_id, /result_is_object=/false, dest, args...};
	}
	// Returns an object
	template <typename... T>
	static inline Instruction InvokeStaticObject(size_t method_id, std::optional<const Value> dest,
	T... args) {
	return Instruction{Op::kInvokeStatic, method_id, /result_is_object=/true, dest, args...};
	}
	// For static calls.
	template <typename... T>
	static inline Instruction InvokeInterface(size_t method_id, std::optional<const Value> dest,
	T... args) {
	return Instruction{Op::kInvokeInterface, method_id, /result_is_object=/false, dest, args...};
	}

	///////////////
	// Accessors //
	///////////////

	Op opcode() const { return opcode_; }
	size_t method_id() const { return method_id_; }
	bool result_is_object() const { return result_is_object_; }
	const std::optional<const Value>& dest() const { return dest_; }
	const std::vector<const Value>& args() const { return args_; }

	private:
	inline Instruction(Op opcode, size_t method_id, std::optional<const Value> dest)
	: opcode_{opcode}, method_id_{method_id}, result_is_object_{false}, dest_{dest}, args_{} {}

	template <typename... T>
	inline constexpr Instruction(Op opcode, size_t method_id, bool result_is_object,
	std::optional<const Value> dest, T... args)
	: opcode_{opcode},
	method_id_{method_id},
	result_is_object_{result_is_object},
	dest_{dest},
	args_{args...} {}

	const Op opcode_;
	// The index of the method to invoke, for kInvokeVirtual and similar opcodes.
	const size_t method_id_{0};
	const bool result_is_object_;
	const std::optional<const Value> dest_;
	const std::vector<const Value> args_;
	};

	// Needed for CHECK_EQ, DCHECK_EQ, etc.
	std::ostream& operator<<(std::ostream& out, const Instruction::Op& opcode);

	// Keeps track of information needed to manipulate or call a method.
	struct MethodDeclData {
	size_t id;
	ir::MethodDecl* decl;
	};

	// Tools to help build methods and their bodies.
	class MethodBuilder {
	public:
	MethodBuilder(DexBuilder* dex, ir::Class* class_def, ir::MethodDecl* decl);

	// Encode the method into DEX format.
	ir::EncodedMethod* Encode();

	// Create a new register to be used to storing values. Note that these are not SSA registers, like
	// might be expected in similar code generators. This does no liveness tracking or anything, so
	// it's up to the caller to reuse registers as appropriate.
	Value MakeRegister();

	Value MakeLabel();

	/////////////////////////////////
	// Instruction builder methods //
	/////////////////////////////////

	void AddInstruction(Instruction instruction);

	// return-void
	void BuildReturn();
	void BuildReturn(Value src, bool is_object = false);
	// const/4
	void BuildConst4(Value target, int value);
	void BuildConstString(Value target, const std::string& value);
	template <typename... T>
	void BuildNew(Value target, TypeDescriptor type, Prototype constructor, T... args);

	// TODO: add builders for more instructions

	DexBuilder* dex_file() const { return dex_; }

	private:
	void EncodeInstructions();
	void EncodeInstruction(const Instruction& instruction);

	// Encodes a return instruction. For instructions with no return value, the opcode field is
	// ignored. Otherwise, this specifies which return instruction will be used (return,
	// return-object, etc.)
	void EncodeReturn(const Instruction& instruction, ::art::Instruction::Code opcode);

	void EncodeMove(const Instruction& instruction);
	void EncodeInvoke(const Instruction& instruction, ::art::Instruction::Code opcode);
	void EncodeBranch(art::Instruction::Code op, const Instruction& instruction);
	void EncodeNew(const Instruction& instruction);
	void EncodeCast(const Instruction& instruction);

	// Low-level instruction format encoding. See
	// https://source.android.com/devices/tech/dalvik/instruction-formats for documentation of
	// formats.

	inline void Encode10x(art::Instruction::Code opcode) {
	// 00\|op
	buffer_.push_back(opcode);
	}

	inline void Encode11x(art::Instruction::Code opcode, uint8_t a) {
	// aa\|op
	buffer_.push_back((a << 8) \| opcode);
	}

	inline void Encode11n(art::Instruction::Code opcode, uint8_t a, int8_t b) {
	// b\|a\|op

	// Make sure the fields are in bounds (4 bits for a, 4 bits for b).
	CHECK_LT(a, 16);
	CHECK_LE(-8, b);
	CHECK_LT(b, 8);

	buffer_.push_back(((b & 0xf) << 12) \| (a << 8) \| opcode);
	}

	inline void Encode21c(art::Instruction::Code opcode, uint8_t a, uint16_t b) {
	// aa\|op\|bbbb
	buffer_.push_back((a << 8) \| opcode);
	buffer_.push_back(b);
	}

	inline void Encode35c(art::Instruction::Code opcode, size_t a, uint16_t b, uint8_t c, uint8_t d,
	uint8_t e, uint8_t f, uint8_t g) {
	// a\|g\|op\|bbbb\|f\|e\|d\|c

	CHECK_LE(a, 5);
	CHECK_LT(c, 16);
	CHECK_LT(d, 16);
	CHECK_LT(e, 16);
	CHECK_LT(f, 16);
	CHECK_LT(g, 16);
	buffer_.push_back((a << 12) \| (g << 8) \| opcode);
	buffer_.push_back(b);
	buffer_.push_back((f << 12) \| (e << 8) \| (d << 4) \| c);
	}

	// Converts a register or parameter to its DEX register number.
	size_t RegisterValue(const Value& value) const;

	// Sets a label's address to the current position in the instruction buffer. If there are any
	// forward references to the label, this function will back-patch them.
	void BindLabel(const Value& label);

	// Returns the offset of the label relative to the given instruction offset. If the label is not
	// bound, a reference will be saved and it will automatically be patched when the label is bound.
	::dex::u2 LabelValue(const Value& label, size_t instruction_offset, size_t field_offset);

	DexBuilder* dex_;
	ir::Class* class_;
	ir::MethodDecl* decl_;

	// A list of the instructions we will eventually encode.
	std::vector<Instruction> instructions_;

	// A buffer to hold instructions that have been encoded.
	std::vector<::dex::u2> buffer_;

	// How many registers we've allocated
	size_t num_registers_{0};

	// Stores information needed to back-patch a label once it is bound. We need to know the start of
	// the instruction that refers to the label, and the offset to where the actual label value should
	// go.
	struct LabelReference {
	size_t instruction_offset;
	size_t field_offset;
	};

	struct LabelData {
	std::optional<size_t> bound_address;
	std::forward_list<LabelReference> references;
	};

	std::vector<LabelData> labels_;

	// During encoding, keep track of the largest number of arguments needed, so we can use it for our
	// outs count
	size_t max_args_{0};
	};

	// A helper to build class definitions.
	class ClassBuilder {
	public:
	ClassBuilder(DexBuilder* parent, const std::string& name, ir::Class* class_def);

	void set_source_file(const std::string& source);

	// Create a method with the given name and prototype. The returned MethodBuilder can be used to
	// fill in the method body.
	MethodBuilder CreateMethod(const std::string& name, Prototype prototype);

	private:
	DexBuilder* const parent_;
	const TypeDescriptor type_descriptor_;
	ir::Class* const class_;
	};

	// Builds Dex files from scratch.
	class DexBuilder {
	public:
	DexBuilder();

	// Create an in-memory image of the DEX file that can either be loaded directly or written to a
	// file.
	slicer::MemView CreateImage();

	template <typename T>
	T* Alloc() {
	return dex_file_->Alloc<T>();
	}

	// Find the ir::String that matches the given string, creating it if it does not exist.
	ir::String* GetOrAddString(const std::string& string);
	// Create a new class of the given name.
	ClassBuilder MakeClass(const std::string& name);

	// Add a type for the given descriptor, or return the existing one if it already exists.
	// See the TypeDescriptor class for help generating these. GetOrAddType can be used to declare
	// imported classes.
	ir::Type* GetOrAddType(const std::string& descriptor);

	// Returns the method id for the method, creating it if it has not been created yet.
	const MethodDeclData& GetOrDeclareMethod(TypeDescriptor type, const std::string& name,
	Prototype prototype);

	private:
	// Looks up the ir::Proto* corresponding to this given prototype, or creates one if it does not
	// exist.
	ir::Proto* GetOrEncodeProto(Prototype prototype);

	std::shared_ptr<ir::DexFile> dex_file_;

	// allocator_ is needed to be able to encode the image.
	TrackingAllocator allocator_;

	// We'll need to allocate buffers for all of the encoded strings we create. This is where we store
	// all of them.
	std::vector<std::unique_ptr<uint8_t[]>> string_data_;

	// Keep track of what types we've defined so we can look them up later.
	std::unordered_map<std::string, ir::Type*> types_by_descriptor_;

	struct MethodDescriptor {
	TypeDescriptor type;
	std::string name;
	Prototype prototype;

	inline bool operator<(const MethodDescriptor& rhs) const {
	return std::make_tuple(type, name, prototype) <
	std::make_tuple(rhs.type, rhs.name, rhs.prototype);
	}
	};

	// Maps method declarations to their method index. This is needed to encode references to them.
	// When we go to actually write the DEX file, slicer will re-assign these after correctly sorting
	// the methods list.
	std::map<MethodDescriptor, MethodDeclData> method_id_map_;

	// Keep track of what strings we've defined so we can look them up later.
	std::unordered_map<std::string, ir::String*> strings_;

	// Keep track of already-encoded protos.
	std::map<Prototype, ir::Proto*> proto_map_;
	};

	template <typename... T>
	void MethodBuilder::BuildNew(Value target, TypeDescriptor type, Prototype constructor, T... args) {
	MethodDeclData constructor_data{dex_->GetOrDeclareMethod(type, "<init>", constructor)};
	// allocate the object
	ir::Type* type_def = dex_->GetOrAddType(type.descriptor());
	AddInstruction(
	Instruction::OpWithArgs(Instruction::Op::kNew, target, Value::Type(type_def->orig_index)));
	// call the constructor
	AddInstruction(Instruction::InvokeDirect(constructor_data.id, /dest=/{}, target, args...));
	};

	} // namespace dex
	} // namespace startop

	#endif // DEX_BUILDER_H_