runtime/vm/code_patcher_x64.cc - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/globals.h"  // Needed here to get TARGET_ARCH_X64.
 #if defined(TARGET_ARCH_X64)

 #include "vm/code_patcher.h"
 #include "vm/cpu.h"
 #include "vm/dart_entry.h"
 #include "vm/instructions.h"
 #include "vm/object.h"
 #include "vm/object_store.h"
 #include "vm/raw_object.h"
 #include "vm/reverse_pc_lookup_cache.h"

 namespace dart {

 class UnoptimizedCall : public ValueObject {
  public:
   UnoptimizedCall(uword return_address, const Code& code)
       : object_pool_(ObjectPool::Handle(code.GetObjectPool())),
         code_index_(-1),
         argument_index_(-1) {
     uword pc = return_address;

     // callq [CODE_REG + entry_point_offset]
     static int16_t call_pattern[] = {
         0x41, 0xff, 0x54, 0x24, -1,
     };
     if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
       pc -= ARRAY_SIZE(call_pattern);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }

     // movq CODE_REG, [PP + offset]
     static int16_t load_code_disp8[] = {
         0x4d, 0x8b, 0x67, -1,  //
     };
     static int16_t load_code_disp32[] = {
         0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
       pc -= ARRAY_SIZE(load_code_disp8);
       code_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_code_disp32,
                               ARRAY_SIZE(load_code_disp32))) {
       pc -= ARRAY_SIZE(load_code_disp32);
       code_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(Object::Handle(object_pool_.ObjectAt(code_index_)).IsCode());

     // movq RBX, [PP + offset]
     static int16_t load_argument_disp8[] = {
         0x49, 0x8b, 0x5f, -1,  //
     };
     static int16_t load_argument_disp32[] = {
         0x49, 0x8b, 0x9f, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_argument_disp8,
                        ARRAY_SIZE(load_argument_disp8))) {
       pc -= ARRAY_SIZE(load_argument_disp8);
       argument_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_argument_disp32,
                               ARRAY_SIZE(load_argument_disp32))) {
       pc -= ARRAY_SIZE(load_argument_disp32);
       argument_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
   }

   intptr_t argument_index() const { return argument_index_; }

   CodePtr target() const {
     Code& code = Code::Handle();
     code ^= object_pool_.ObjectAt(code_index_);
     return code.ptr();
   }

   void set_target(const Code& target) const {
     object_pool_.SetObjectAt(code_index_, target);
     // No need to flush the instruction cache, since the code is not modified.
   }

  protected:
   const ObjectPool& object_pool_;
   intptr_t code_index_;
   intptr_t argument_index_;

  private:
   uword start_;
   DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedCall);
 };

 class NativeCall : public UnoptimizedCall {
  public:
   NativeCall(uword return_address, const Code& code)
       : UnoptimizedCall(return_address, code) {}

   NativeFunction native_function() const {
     return reinterpret_cast<NativeFunction>(
         object_pool_.RawValueAt(argument_index()));
   }

   void set_native_function(NativeFunction func) const {
     object_pool_.SetRawValueAt(argument_index(), reinterpret_cast<uword>(func));
   }

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(NativeCall);
 };

 class InstanceCall : public UnoptimizedCall {
  public:
   InstanceCall(uword return_address, const Code& code)
       : UnoptimizedCall(return_address, code) {
 #if defined(DEBUG)
     Object& test_data = Object::Handle(data());
     ASSERT(test_data.IsArray() || test_data.IsICData() ||
            test_data.IsMegamorphicCache());
     if (test_data.IsICData()) {
       ASSERT(ICData::Cast(test_data).NumArgsTested() > 0);
     }
 #endif  // DEBUG
   }

   ObjectPtr data() const { return object_pool_.ObjectAt(argument_index()); }
   void set_data(const Object& data) const {
     ASSERT(data.IsArray() || data.IsICData() || data.IsMegamorphicCache());
     object_pool_.SetObjectAt(argument_index(), data);
   }

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(InstanceCall);
 };

 class UnoptimizedStaticCall : public UnoptimizedCall {
  public:
   UnoptimizedStaticCall(uword return_address, const Code& caller_code)
       : UnoptimizedCall(return_address, caller_code) {
 #if defined(DEBUG)
     ICData& test_ic_data = ICData::Handle();
     test_ic_data ^= ic_data();
     ASSERT(test_ic_data.NumArgsTested() >= 0);
 #endif  // DEBUG
   }

   ObjectPtr ic_data() const { return object_pool_.ObjectAt(argument_index()); }

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedStaticCall);
 };

 // The expected pattern of a call where the target is loaded from
 // the object pool.
 class PoolPointerCall : public ValueObject {
  public:
   explicit PoolPointerCall(uword return_address, const Code& caller_code)
       : object_pool_(ObjectPool::Handle(caller_code.GetObjectPool())),
         code_index_(-1) {
     uword pc = return_address;

     // callq [CODE_REG + entry_point_offset]
     static int16_t call_pattern[] = {
         0x41, 0xff, 0x54, 0x24, -1,
     };
     if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
       pc -= ARRAY_SIZE(call_pattern);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }

     // movq CODE_REG, [PP + offset]
     static int16_t load_code_disp8[] = {
         0x4d, 0x8b, 0x67, -1,  //
     };
     static int16_t load_code_disp32[] = {
         0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
       pc -= ARRAY_SIZE(load_code_disp8);
       code_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_code_disp32,
                               ARRAY_SIZE(load_code_disp32))) {
       pc -= ARRAY_SIZE(load_code_disp32);
       code_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(Object::Handle(object_pool_.ObjectAt(code_index_)).IsCode());
   }

   CodePtr Target() const {
     Code& code = Code::Handle();
     code ^= object_pool_.ObjectAt(code_index_);
     return code.ptr();
   }

   void SetTarget(const Code& target) const {
     object_pool_.SetObjectAt(code_index_, target);
     // No need to flush the instruction cache, since the code is not modified.
   }

  protected:
   const ObjectPool& object_pool_;
   intptr_t code_index_;

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(PoolPointerCall);
 };

 // Instance call that can switch between a direct monomorphic call, an IC call,
 // and a megamorphic call.
 //   load guarded cid            load ICData             load MegamorphicCache
 //   load monomorphic target <-> load ICLookup stub  ->  load MMLookup stub
 //   call target.entry           call stub.entry         call stub.entry
 class SwitchableCallBase : public ValueObject {
  public:
   explicit SwitchableCallBase(const ObjectPool& object_pool)
       : object_pool_(object_pool), target_index_(-1), data_index_(-1) {}

   intptr_t data_index() const { return data_index_; }
   intptr_t target_index() const { return target_index_; }

   ObjectPtr data() const { return object_pool_.ObjectAt(data_index()); }

   void SetData(const Object& data) const {
     ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index())).IsCode());
     object_pool_.SetObjectAt(data_index(), data);
     // No need to flush the instruction cache, since the code is not modified.
   }

  protected:
   const ObjectPool& object_pool_;
   intptr_t target_index_;
   intptr_t data_index_;

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(SwitchableCallBase);
 };

 // See [SwitchableCallBase] for a switchable calls in general.
 //
 // The target slot is always a [Code] object: Either the code of the
 // monomorphic function or a stub code.
 class SwitchableCall : public SwitchableCallBase {
  public:
   SwitchableCall(uword return_address, const Code& caller_code)
       : SwitchableCallBase(ObjectPool::Handle(caller_code.GetObjectPool())) {
     ASSERT(caller_code.ContainsInstructionAt(return_address));
     uword pc = return_address;

     // callq RCX
     static int16_t call_pattern[] = {
         0xff, 0xd1,  //
     };
     if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
       pc -= ARRAY_SIZE(call_pattern);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }

     // movq RBX, [PP + offset]
     static int16_t load_data_disp8[] = {
         0x49, 0x8b, 0x5f, -1,  //
     };
     static int16_t load_data_disp32[] = {
         0x49, 0x8b, 0x9f, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_data_disp8, ARRAY_SIZE(load_data_disp8))) {
       pc -= ARRAY_SIZE(load_data_disp8);
       data_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_data_disp32,
                               ARRAY_SIZE(load_data_disp32))) {
       pc -= ARRAY_SIZE(load_data_disp32);
       data_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index_)).IsCode());

     // movq rcx, [CODE_REG + entrypoint_offset]
     static int16_t load_entry_pattern[] = {
         0x49, 0x8b, 0x4c, 0x24, -1,
     };
     if (MatchesPattern(pc, load_entry_pattern,
                        ARRAY_SIZE(load_entry_pattern))) {
       pc -= ARRAY_SIZE(load_entry_pattern);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }

     // movq CODE_REG, [PP + offset]
     static int16_t load_code_disp8[] = {
         0x4d, 0x8b, 0x67, -1,  //
     };
     static int16_t load_code_disp32[] = {
         0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
       pc -= ARRAY_SIZE(load_code_disp8);
       target_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_code_disp32,
                               ARRAY_SIZE(load_code_disp32))) {
       pc -= ARRAY_SIZE(load_code_disp32);
       target_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(Object::Handle(object_pool_.ObjectAt(target_index_)).IsCode());
   }

   void SetTarget(const Code& target) const {
     ASSERT(Object::Handle(object_pool_.ObjectAt(target_index())).IsCode());
     object_pool_.SetObjectAt(target_index(), target);
     // No need to flush the instruction cache, since the code is not modified.
   }

   uword target_entry() const {
     return Code::Handle(Code::RawCast(object_pool_.ObjectAt(target_index())))
         .MonomorphicEntryPoint();
   }
 };

 // See [SwitchableCallBase] for a switchable calls in general.
 //
 // The target slot is always a direct entrypoint address: Either the entry point
 // of the monomorphic function or a stub entry point.
 class BareSwitchableCall : public SwitchableCallBase {
  public:
   explicit BareSwitchableCall(uword return_address)
       : SwitchableCallBase(ObjectPool::Handle(
             IsolateGroup::Current()->object_store()->global_object_pool())) {
     uword pc = return_address;

     // callq RCX
     static int16_t call_pattern[] = {
         0xff, 0xd1,  //
     };
     if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
       pc -= ARRAY_SIZE(call_pattern);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }

     // movq RBX, [PP + offset]
     static int16_t load_data_disp8[] = {
         0x49, 0x8b, 0x5f, -1,  //
     };
     static int16_t load_data_disp32[] = {
         0x49, 0x8b, 0x9f, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_data_disp8, ARRAY_SIZE(load_data_disp8))) {
       pc -= ARRAY_SIZE(load_data_disp8);
       data_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_data_disp32,
                               ARRAY_SIZE(load_data_disp32))) {
       pc -= ARRAY_SIZE(load_data_disp32);
       data_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index_)).IsCode());

     // movq RCX, [PP + offset]
     static int16_t load_code_disp8[] = {
         0x49, 0x8b, 0x4f, -1,  //
     };
     static int16_t load_code_disp32[] = {
         0x49, 0x8b, 0x8f, -1, -1, -1, -1,
     };
     if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
       pc -= ARRAY_SIZE(load_code_disp8);
       target_index_ = IndexFromPPLoadDisp8(pc + 3);
     } else if (MatchesPattern(pc, load_code_disp32,
                               ARRAY_SIZE(load_code_disp32))) {
       pc -= ARRAY_SIZE(load_code_disp32);
       target_index_ = IndexFromPPLoadDisp32(pc + 3);
     } else {
       FATAL1("Failed to decode at %" Px, pc);
     }
     ASSERT(object_pool_.TypeAt(target_index_) ==
            ObjectPool::EntryType::kImmediate);
   }

   void SetTarget(const Code& target) const {
     ASSERT(object_pool_.TypeAt(target_index()) ==
            ObjectPool::EntryType::kImmediate);
     object_pool_.SetRawValueAt(target_index(), target.MonomorphicEntryPoint());
   }

   uword target_entry() const { return object_pool_.RawValueAt(target_index()); }
 };

 CodePtr CodePatcher::GetStaticCallTargetAt(uword return_address,
                                            const Code& code) {
   ASSERT(code.ContainsInstructionAt(return_address));
   PoolPointerCall call(return_address, code);
   return call.Target();
 }

 void CodePatcher::PatchStaticCallAt(uword return_address,
                                     const Code& code,
                                     const Code& new_target) {
   PatchPoolPointerCallAt(return_address, code, new_target);
 }

 void CodePatcher::PatchPoolPointerCallAt(uword return_address,
                                          const Code& code,
                                          const Code& new_target) {
   ASSERT(code.ContainsInstructionAt(return_address));
   PoolPointerCall call(return_address, code);
   call.SetTarget(new_target);
 }

 CodePtr CodePatcher::GetInstanceCallAt(uword return_address,
                                        const Code& caller_code,
                                        Object* data) {
   ASSERT(caller_code.ContainsInstructionAt(return_address));
   InstanceCall call(return_address, caller_code);
   if (data != NULL) {
     *data = call.data();
   }
   return call.target();
 }

 void CodePatcher::PatchInstanceCallAt(uword return_address,
                                       const Code& caller_code,
                                       const Object& data,
                                       const Code& target) {
   auto thread = Thread::Current();
   thread->isolate_group()->RunWithStoppedMutators([&]() {
     PatchInstanceCallAtWithMutatorsStopped(thread, return_address, caller_code,
                                            data, target);
   });
 }

 void CodePatcher::PatchInstanceCallAtWithMutatorsStopped(
     Thread* thread,
     uword return_address,
     const Code& caller_code,
     const Object& data,
     const Code& target) {
   ASSERT(caller_code.ContainsInstructionAt(return_address));
   InstanceCall call(return_address, caller_code);
   call.set_data(data);
   call.set_target(target);
 }

 void CodePatcher::InsertDeoptimizationCallAt(uword start) {
   UNREACHABLE();
 }

 FunctionPtr CodePatcher::GetUnoptimizedStaticCallAt(uword return_address,
                                                     const Code& caller_code,
                                                     ICData* ic_data_result) {
   ASSERT(caller_code.ContainsInstructionAt(return_address));
   UnoptimizedStaticCall static_call(return_address, caller_code);
   ICData& ic_data = ICData::Handle();
   ic_data ^= static_call.ic_data();
   if (ic_data_result != NULL) {
     *ic_data_result = ic_data.ptr();
   }
   return ic_data.GetTargetAt(0);
 }

 void CodePatcher::PatchSwitchableCallAt(uword return_address,
                                         const Code& caller_code,
                                         const Object& data,
                                         const Code& target) {
   auto thread = Thread::Current();
   // Ensure all threads are suspended as we update data and target pair.
   thread->isolate_group()->RunWithStoppedMutators([&]() {
     PatchSwitchableCallAtWithMutatorsStopped(thread, return_address,
                                              caller_code, data, target);
   });
 }

 void CodePatcher::PatchSwitchableCallAtWithMutatorsStopped(
     Thread* thread,
     uword return_address,
     const Code& caller_code,
     const Object& data,
     const Code& target) {
   if (FLAG_precompiled_mode) {
     BareSwitchableCall call(return_address);
     call.SetData(data);
     call.SetTarget(target);
   } else {
     SwitchableCall call(return_address, caller_code);
     call.SetData(data);
     call.SetTarget(target);
   }
 }

 uword CodePatcher::GetSwitchableCallTargetEntryAt(uword return_address,
                                                   const Code& caller_code) {
   if (FLAG_precompiled_mode) {
     BareSwitchableCall call(return_address);
     return call.target_entry();
   } else {
     SwitchableCall call(return_address, caller_code);
     return call.target_entry();
   }
 }

 ObjectPtr CodePatcher::GetSwitchableCallDataAt(uword return_address,
                                                const Code& caller_code) {
   if (FLAG_precompiled_mode) {
     BareSwitchableCall call(return_address);
     return call.data();
   } else {
     SwitchableCall call(return_address, caller_code);
     return call.data();
   }
 }

 void CodePatcher::PatchNativeCallAt(uword return_address,
                                     const Code& caller_code,
                                     NativeFunction target,
                                     const Code& trampoline) {
   Thread::Current()->isolate_group()->RunWithStoppedMutators([&]() {
     ASSERT(caller_code.ContainsInstructionAt(return_address));
     NativeCall call(return_address, caller_code);
     call.set_target(trampoline);
     call.set_native_function(target);
   });
 }

 CodePtr CodePatcher::GetNativeCallAt(uword return_address,
                                      const Code& caller_code,
                                      NativeFunction* target) {
   ASSERT(caller_code.ContainsInstructionAt(return_address));
   NativeCall call(return_address, caller_code);
   *target = call.native_function();
   return call.target();
 }

 }  // namespace dart

 #endif  // defined TARGET_ARCH_X64
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/globals.h" // Needed here to get TARGET_ARCH_X64.
	#if defined(TARGET_ARCH_X64)

	#include "vm/code_patcher.h"
	#include "vm/cpu.h"
	#include "vm/dart_entry.h"
	#include "vm/instructions.h"
	#include "vm/object.h"
	#include "vm/object_store.h"
	#include "vm/raw_object.h"
	#include "vm/reverse_pc_lookup_cache.h"

	namespace dart {

	class UnoptimizedCall : public ValueObject {
	public:
	UnoptimizedCall(uword return_address, const Code& code)
	: object_pool_(ObjectPool::Handle(code.GetObjectPool())),
	code_index_(-1),
	argument_index_(-1) {
	uword pc = return_address;

	// callq [CODE_REG + entry_point_offset]
	static int16_t call_pattern[] = {
	0x41, 0xff, 0x54, 0x24, -1,
	};
	if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
	pc -= ARRAY_SIZE(call_pattern);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}

	// movq CODE_REG, [PP + offset]
	static int16_t load_code_disp8[] = {
	0x4d, 0x8b, 0x67, -1, //
	};
	static int16_t load_code_disp32[] = {
	0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
	pc -= ARRAY_SIZE(load_code_disp8);
	code_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_code_disp32,
	ARRAY_SIZE(load_code_disp32))) {
	pc -= ARRAY_SIZE(load_code_disp32);
	code_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(Object::Handle(object_pool_.ObjectAt(code_index_)).IsCode());

	// movq RBX, [PP + offset]
	static int16_t load_argument_disp8[] = {
	0x49, 0x8b, 0x5f, -1, //
	};
	static int16_t load_argument_disp32[] = {
	0x49, 0x8b, 0x9f, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_argument_disp8,
	ARRAY_SIZE(load_argument_disp8))) {
	pc -= ARRAY_SIZE(load_argument_disp8);
	argument_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_argument_disp32,
	ARRAY_SIZE(load_argument_disp32))) {
	pc -= ARRAY_SIZE(load_argument_disp32);
	argument_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	}

	intptr_t argument_index() const { return argument_index_; }

	CodePtr target() const {
	Code& code = Code::Handle();
	code ^= object_pool_.ObjectAt(code_index_);
	return code.ptr();
	}

	void set_target(const Code& target) const {
	object_pool_.SetObjectAt(code_index_, target);
	// No need to flush the instruction cache, since the code is not modified.
	}

	protected:
	const ObjectPool& object_pool_;
	intptr_t code_index_;
	intptr_t argument_index_;

	private:
	uword start_;
	DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedCall);
	};

	class NativeCall : public UnoptimizedCall {
	public:
	NativeCall(uword return_address, const Code& code)
	: UnoptimizedCall(return_address, code) {}

	NativeFunction native_function() const {
	return reinterpret_cast<NativeFunction>(
	object_pool_.RawValueAt(argument_index()));
	}

	void set_native_function(NativeFunction func) const {
	object_pool_.SetRawValueAt(argument_index(), reinterpret_cast<uword>(func));
	}

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(NativeCall);
	};

	class InstanceCall : public UnoptimizedCall {
	public:
	InstanceCall(uword return_address, const Code& code)
	: UnoptimizedCall(return_address, code) {
	#if defined(DEBUG)
	Object& test_data = Object::Handle(data());
	ASSERT(test_data.IsArray() \|\| test_data.IsICData() \|\|
	test_data.IsMegamorphicCache());
	if (test_data.IsICData()) {
	ASSERT(ICData::Cast(test_data).NumArgsTested() > 0);
	}
	#endif // DEBUG
	}

	ObjectPtr data() const { return object_pool_.ObjectAt(argument_index()); }
	void set_data(const Object& data) const {
	ASSERT(data.IsArray() \|\| data.IsICData() \|\| data.IsMegamorphicCache());
	object_pool_.SetObjectAt(argument_index(), data);
	}

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(InstanceCall);
	};

	class UnoptimizedStaticCall : public UnoptimizedCall {
	public:
	UnoptimizedStaticCall(uword return_address, const Code& caller_code)
	: UnoptimizedCall(return_address, caller_code) {
	#if defined(DEBUG)
	ICData& test_ic_data = ICData::Handle();
	test_ic_data ^= ic_data();
	ASSERT(test_ic_data.NumArgsTested() >= 0);
	#endif // DEBUG
	}

	ObjectPtr ic_data() const { return object_pool_.ObjectAt(argument_index()); }

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedStaticCall);
	};

	// The expected pattern of a call where the target is loaded from
	// the object pool.
	class PoolPointerCall : public ValueObject {
	public:
	explicit PoolPointerCall(uword return_address, const Code& caller_code)
	: object_pool_(ObjectPool::Handle(caller_code.GetObjectPool())),
	code_index_(-1) {
	uword pc = return_address;

	// callq [CODE_REG + entry_point_offset]
	static int16_t call_pattern[] = {
	0x41, 0xff, 0x54, 0x24, -1,
	};
	if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
	pc -= ARRAY_SIZE(call_pattern);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}

	// movq CODE_REG, [PP + offset]
	static int16_t load_code_disp8[] = {
	0x4d, 0x8b, 0x67, -1, //
	};
	static int16_t load_code_disp32[] = {
	0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
	pc -= ARRAY_SIZE(load_code_disp8);
	code_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_code_disp32,
	ARRAY_SIZE(load_code_disp32))) {
	pc -= ARRAY_SIZE(load_code_disp32);
	code_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(Object::Handle(object_pool_.ObjectAt(code_index_)).IsCode());
	}

	CodePtr Target() const {
	Code& code = Code::Handle();
	code ^= object_pool_.ObjectAt(code_index_);
	return code.ptr();
	}

	void SetTarget(const Code& target) const {
	object_pool_.SetObjectAt(code_index_, target);
	// No need to flush the instruction cache, since the code is not modified.
	}

	protected:
	const ObjectPool& object_pool_;
	intptr_t code_index_;

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(PoolPointerCall);
	};

	// Instance call that can switch between a direct monomorphic call, an IC call,
	// and a megamorphic call.
	// load guarded cid load ICData load MegamorphicCache
	// load monomorphic target <-> load ICLookup stub -> load MMLookup stub
	// call target.entry call stub.entry call stub.entry
	class SwitchableCallBase : public ValueObject {
	public:
	explicit SwitchableCallBase(const ObjectPool& object_pool)
	: object_pool_(object_pool), target_index_(-1), data_index_(-1) {}

	intptr_t data_index() const { return data_index_; }
	intptr_t target_index() const { return target_index_; }

	ObjectPtr data() const { return object_pool_.ObjectAt(data_index()); }

	void SetData(const Object& data) const {
	ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index())).IsCode());
	object_pool_.SetObjectAt(data_index(), data);
	// No need to flush the instruction cache, since the code is not modified.
	}

	protected:
	const ObjectPool& object_pool_;
	intptr_t target_index_;
	intptr_t data_index_;

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(SwitchableCallBase);
	};

	// See [SwitchableCallBase] for a switchable calls in general.
	//
	// The target slot is always a [Code] object: Either the code of the
	// monomorphic function or a stub code.
	class SwitchableCall : public SwitchableCallBase {
	public:
	SwitchableCall(uword return_address, const Code& caller_code)
	: SwitchableCallBase(ObjectPool::Handle(caller_code.GetObjectPool())) {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	uword pc = return_address;

	// callq RCX
	static int16_t call_pattern[] = {
	0xff, 0xd1, //
	};
	if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
	pc -= ARRAY_SIZE(call_pattern);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}

	// movq RBX, [PP + offset]
	static int16_t load_data_disp8[] = {
	0x49, 0x8b, 0x5f, -1, //
	};
	static int16_t load_data_disp32[] = {
	0x49, 0x8b, 0x9f, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_data_disp8, ARRAY_SIZE(load_data_disp8))) {
	pc -= ARRAY_SIZE(load_data_disp8);
	data_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_data_disp32,
	ARRAY_SIZE(load_data_disp32))) {
	pc -= ARRAY_SIZE(load_data_disp32);
	data_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index_)).IsCode());

	// movq rcx, [CODE_REG + entrypoint_offset]
	static int16_t load_entry_pattern[] = {
	0x49, 0x8b, 0x4c, 0x24, -1,
	};
	if (MatchesPattern(pc, load_entry_pattern,
	ARRAY_SIZE(load_entry_pattern))) {
	pc -= ARRAY_SIZE(load_entry_pattern);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}

	// movq CODE_REG, [PP + offset]
	static int16_t load_code_disp8[] = {
	0x4d, 0x8b, 0x67, -1, //
	};
	static int16_t load_code_disp32[] = {
	0x4d, 0x8b, 0xa7, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
	pc -= ARRAY_SIZE(load_code_disp8);
	target_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_code_disp32,
	ARRAY_SIZE(load_code_disp32))) {
	pc -= ARRAY_SIZE(load_code_disp32);
	target_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(Object::Handle(object_pool_.ObjectAt(target_index_)).IsCode());
	}

	void SetTarget(const Code& target) const {
	ASSERT(Object::Handle(object_pool_.ObjectAt(target_index())).IsCode());
	object_pool_.SetObjectAt(target_index(), target);
	// No need to flush the instruction cache, since the code is not modified.
	}

	uword target_entry() const {
	return Code::Handle(Code::RawCast(object_pool_.ObjectAt(target_index())))
	.MonomorphicEntryPoint();
	}
	};

	// See [SwitchableCallBase] for a switchable calls in general.
	//
	// The target slot is always a direct entrypoint address: Either the entry point
	// of the monomorphic function or a stub entry point.
	class BareSwitchableCall : public SwitchableCallBase {
	public:
	explicit BareSwitchableCall(uword return_address)
	: SwitchableCallBase(ObjectPool::Handle(
	IsolateGroup::Current()->object_store()->global_object_pool())) {
	uword pc = return_address;

	// callq RCX
	static int16_t call_pattern[] = {
	0xff, 0xd1, //
	};
	if (MatchesPattern(pc, call_pattern, ARRAY_SIZE(call_pattern))) {
	pc -= ARRAY_SIZE(call_pattern);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}

	// movq RBX, [PP + offset]
	static int16_t load_data_disp8[] = {
	0x49, 0x8b, 0x5f, -1, //
	};
	static int16_t load_data_disp32[] = {
	0x49, 0x8b, 0x9f, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_data_disp8, ARRAY_SIZE(load_data_disp8))) {
	pc -= ARRAY_SIZE(load_data_disp8);
	data_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_data_disp32,
	ARRAY_SIZE(load_data_disp32))) {
	pc -= ARRAY_SIZE(load_data_disp32);
	data_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(!Object::Handle(object_pool_.ObjectAt(data_index_)).IsCode());

	// movq RCX, [PP + offset]
	static int16_t load_code_disp8[] = {
	0x49, 0x8b, 0x4f, -1, //
	};
	static int16_t load_code_disp32[] = {
	0x49, 0x8b, 0x8f, -1, -1, -1, -1,
	};
	if (MatchesPattern(pc, load_code_disp8, ARRAY_SIZE(load_code_disp8))) {
	pc -= ARRAY_SIZE(load_code_disp8);
	target_index_ = IndexFromPPLoadDisp8(pc + 3);
	} else if (MatchesPattern(pc, load_code_disp32,
	ARRAY_SIZE(load_code_disp32))) {
	pc -= ARRAY_SIZE(load_code_disp32);
	target_index_ = IndexFromPPLoadDisp32(pc + 3);
	} else {
	FATAL1("Failed to decode at %" Px, pc);
	}
	ASSERT(object_pool_.TypeAt(target_index_) ==
	ObjectPool::EntryType::kImmediate);
	}

	void SetTarget(const Code& target) const {
	ASSERT(object_pool_.TypeAt(target_index()) ==
	ObjectPool::EntryType::kImmediate);
	object_pool_.SetRawValueAt(target_index(), target.MonomorphicEntryPoint());
	}

	uword target_entry() const { return object_pool_.RawValueAt(target_index()); }
	};

	CodePtr CodePatcher::GetStaticCallTargetAt(uword return_address,
	const Code& code) {
	ASSERT(code.ContainsInstructionAt(return_address));
	PoolPointerCall call(return_address, code);
	return call.Target();
	}

	void CodePatcher::PatchStaticCallAt(uword return_address,
	const Code& code,
	const Code& new_target) {
	PatchPoolPointerCallAt(return_address, code, new_target);
	}

	void CodePatcher::PatchPoolPointerCallAt(uword return_address,
	const Code& code,
	const Code& new_target) {
	ASSERT(code.ContainsInstructionAt(return_address));
	PoolPointerCall call(return_address, code);
	call.SetTarget(new_target);
	}

	CodePtr CodePatcher::GetInstanceCallAt(uword return_address,
	const Code& caller_code,
	Object* data) {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	InstanceCall call(return_address, caller_code);
	if (data != NULL) {
	*data = call.data();
	}
	return call.target();
	}

	void CodePatcher::PatchInstanceCallAt(uword return_address,
	const Code& caller_code,
	const Object& data,
	const Code& target) {
	auto thread = Thread::Current();
	thread->isolate_group()->RunWithStoppedMutators([&]() {
	PatchInstanceCallAtWithMutatorsStopped(thread, return_address, caller_code,
	data, target);
	});
	}

	void CodePatcher::PatchInstanceCallAtWithMutatorsStopped(
	Thread* thread,
	uword return_address,
	const Code& caller_code,
	const Object& data,
	const Code& target) {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	InstanceCall call(return_address, caller_code);
	call.set_data(data);
	call.set_target(target);
	}

	void CodePatcher::InsertDeoptimizationCallAt(uword start) {
	UNREACHABLE();
	}

	FunctionPtr CodePatcher::GetUnoptimizedStaticCallAt(uword return_address,
	const Code& caller_code,
	ICData* ic_data_result) {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	UnoptimizedStaticCall static_call(return_address, caller_code);
	ICData& ic_data = ICData::Handle();
	ic_data ^= static_call.ic_data();
	if (ic_data_result != NULL) {
	*ic_data_result = ic_data.ptr();
	}
	return ic_data.GetTargetAt(0);
	}

	void CodePatcher::PatchSwitchableCallAt(uword return_address,
	const Code& caller_code,
	const Object& data,
	const Code& target) {
	auto thread = Thread::Current();
	// Ensure all threads are suspended as we update data and target pair.
	thread->isolate_group()->RunWithStoppedMutators([&]() {
	PatchSwitchableCallAtWithMutatorsStopped(thread, return_address,
	caller_code, data, target);
	});
	}

	void CodePatcher::PatchSwitchableCallAtWithMutatorsStopped(
	Thread* thread,
	uword return_address,
	const Code& caller_code,
	const Object& data,
	const Code& target) {
	if (FLAG_precompiled_mode) {
	BareSwitchableCall call(return_address);
	call.SetData(data);
	call.SetTarget(target);
	} else {
	SwitchableCall call(return_address, caller_code);
	call.SetData(data);
	call.SetTarget(target);
	}
	}

	uword CodePatcher::GetSwitchableCallTargetEntryAt(uword return_address,
	const Code& caller_code) {
	if (FLAG_precompiled_mode) {
	BareSwitchableCall call(return_address);
	return call.target_entry();
	} else {
	SwitchableCall call(return_address, caller_code);
	return call.target_entry();
	}
	}

	ObjectPtr CodePatcher::GetSwitchableCallDataAt(uword return_address,
	const Code& caller_code) {
	if (FLAG_precompiled_mode) {
	BareSwitchableCall call(return_address);
	return call.data();
	} else {
	SwitchableCall call(return_address, caller_code);
	return call.data();
	}
	}

	void CodePatcher::PatchNativeCallAt(uword return_address,
	const Code& caller_code,
	NativeFunction target,
	const Code& trampoline) {
	Thread::Current()->isolate_group()->RunWithStoppedMutators([&]() {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	NativeCall call(return_address, caller_code);
	call.set_target(trampoline);
	call.set_native_function(target);
	});
	}

	CodePtr CodePatcher::GetNativeCallAt(uword return_address,
	const Code& caller_code,
	NativeFunction* target) {
	ASSERT(caller_code.ContainsInstructionAt(return_address));
	NativeCall call(return_address, caller_code);
	*target = call.native_function();
	return call.target();
	}

	} // namespace dart

	#endif // defined TARGET_ARCH_X64