dart/runtime/vm/code_patcher_ia32.cc - external/dart - 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_IA32.
 #if defined(TARGET_ARCH_IA32)

 #include "vm/assembler.h"
 #include "vm/code_patcher.h"
 #include "vm/cpu.h"
 #include "vm/dart_entry.h"
 #include "vm/flow_graph_compiler.h"
 #include "vm/instructions.h"
 #include "vm/object.h"
 #include "vm/raw_object.h"

 namespace dart {

 // The expected pattern of a Dart unoptimized call (static and instance):
 //  mov ECX, ic-data
 //  call target_address (stub)
 //  <- return address
 class UnoptimizedCall : public ValueObject {
  public:
   explicit UnoptimizedCall(uword return_address)
       : start_(return_address - (kNumInstructions * kInstructionSize)) {
     ASSERT(IsValid(return_address));
     ASSERT(kInstructionSize == Assembler::kCallExternalLabelSize);
   }

   static bool IsValid(uword return_address) {
     uint8_t* code_bytes =
         reinterpret_cast<uint8_t*>(
             return_address - (kNumInstructions * kInstructionSize));
     return (code_bytes[0] == 0xB9) &&
            (code_bytes[1 * kInstructionSize] == 0xE8);
   }

   uword target() const {
     const uword offset = *reinterpret_cast<uword*>(call_address() + 1);
     return return_address() + offset;
   }

   void set_target(uword target) const {
     uword* target_addr = reinterpret_cast<uword*>(call_address() + 1);
     uword offset = target - return_address();
     *target_addr = offset;
     CPU::FlushICache(call_address(), kInstructionSize);
   }

   RawObject* ic_data() const {
     return *reinterpret_cast<RawObject**>(start_ + 1);
   }

   static const int kNumInstructions = 2;
   static const int kInstructionSize = 5;  // All instructions have same length.

  private:
   uword return_address() const {
     return start_ + kNumInstructions * kInstructionSize;
   }

   uword call_address() const {
     return start_ + 1 * kInstructionSize;
   }

   uword start_;
   DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedCall);
 };


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

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(InstanceCall);
 };


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

  private:
   DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedStaticCall);
 };


 // The expected pattern of a dart static call:
 //  mov EDX, arguments_descriptor_array (optional in polymorphic calls)
 //  call target_address
 //  <- return address
 class StaticCall : public ValueObject {
  public:
   explicit StaticCall(uword return_address)
       : start_(return_address - (kNumInstructions * kInstructionSize)) {
     ASSERT(IsValid(return_address));
     ASSERT(kInstructionSize == Assembler::kCallExternalLabelSize);
   }

   static bool IsValid(uword return_address) {
     uint8_t* code_bytes =
         reinterpret_cast<uint8_t*>(
             return_address - (kNumInstructions * kInstructionSize));
     return (code_bytes[0] == 0xE8);
   }

   uword target() const {
     const uword offset = *reinterpret_cast<uword*>(call_address() + 1);
     return return_address() + offset;
   }

   void set_target(uword target) const {
     uword* target_addr = reinterpret_cast<uword*>(call_address() + 1);
     uword offset = target - return_address();
     *target_addr = offset;
     CPU::FlushICache(call_address(), kInstructionSize);
   }

   static const int kNumInstructions = 1;
   static const int kInstructionSize = 5;  // All instructions have same length.

  private:
   uword return_address() const {
     return start_ + kNumInstructions * kInstructionSize;
   }

   uword call_address() const {
     return start_;
   }

   uword start_;

   DISALLOW_IMPLICIT_CONSTRUCTORS(StaticCall);
 };


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


 void CodePatcher::PatchStaticCallAt(uword return_address,
                                     const Code& code,
                                     uword new_target) {
   ASSERT(code.ContainsInstructionAt(return_address));
   StaticCall call(return_address);
   call.set_target(new_target);
 }


 void CodePatcher::PatchInstanceCallAt(uword return_address,
                                       const Code& code,
                                       uword new_target) {
   ASSERT(code.ContainsInstructionAt(return_address));
   InstanceCall call(return_address);
   call.set_target(new_target);
 }


 int32_t CodePatcher::GetPoolOffsetAt(uword return_address) {
   UNREACHABLE();
   return 0;
 }


 void CodePatcher::SetPoolOffsetAt(uword return_address, int32_t offset) {
   UNREACHABLE();
 }


 void CodePatcher::InsertCallAt(uword start, uword target) {
   // The inserted call should not overlap the lazy deopt jump code.
   ASSERT(start + CallPattern::InstructionLength() <= target);
   *reinterpret_cast<uint8_t*>(start) = 0xE8;
   CallPattern call(start);
   call.SetTargetAddress(target);
   CPU::FlushICache(start, CallPattern::InstructionLength());
 }


 uword CodePatcher::GetInstanceCallAt(
     uword return_address, const Code& code, ICData* ic_data) {
   ASSERT(code.ContainsInstructionAt(return_address));
   InstanceCall call(return_address);
   if (ic_data != NULL) {
     *ic_data ^= call.ic_data();
   }
   return call.target();
 }


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


 intptr_t CodePatcher::InstanceCallSizeInBytes() {
   return InstanceCall::kNumInstructions * InstanceCall::kInstructionSize;
 }


 // The expected code pattern of an edge counter in unoptimized code:
 //  b8 imm32    mov EAX, immediate
 class EdgeCounter : public ValueObject {
  public:
   EdgeCounter(uword pc, const Code& ignored)
       : end_(pc - FlowGraphCompiler::EdgeCounterIncrementSizeInBytes()) {
     ASSERT(IsValid(end_));
   }

   static bool IsValid(uword end) {
     return (*reinterpret_cast<uint8_t*>(end - 5) == 0xb8);
   }

   RawObject* edge_counter() const {
     return *reinterpret_cast<RawObject**>(end_ - 4);
   }

  private:
   uword end_;
 };


 RawObject* CodePatcher::GetEdgeCounterAt(uword pc, const Code& code) {
   ASSERT(code.ContainsInstructionAt(pc));
   EdgeCounter counter(pc, code);
   return counter.edge_counter();
 }

 }  // namespace dart

 #endif  // defined TARGET_ARCH_IA32
	// 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_IA32.
	#if defined(TARGET_ARCH_IA32)

	#include "vm/assembler.h"
	#include "vm/code_patcher.h"
	#include "vm/cpu.h"
	#include "vm/dart_entry.h"
	#include "vm/flow_graph_compiler.h"
	#include "vm/instructions.h"
	#include "vm/object.h"
	#include "vm/raw_object.h"

	namespace dart {

	// The expected pattern of a Dart unoptimized call (static and instance):
	// mov ECX, ic-data
	// call target_address (stub)
	// <- return address
	class UnoptimizedCall : public ValueObject {
	public:
	explicit UnoptimizedCall(uword return_address)
	: start_(return_address - (kNumInstructions * kInstructionSize)) {
	ASSERT(IsValid(return_address));
	ASSERT(kInstructionSize == Assembler::kCallExternalLabelSize);
	}

	static bool IsValid(uword return_address) {
	uint8_t* code_bytes =
	reinterpret_cast<uint8_t*>(
	return_address - (kNumInstructions * kInstructionSize));
	return (code_bytes[0] == 0xB9) &&
	(code_bytes[1 * kInstructionSize] == 0xE8);
	}

	uword target() const {
	const uword offset = reinterpret_cast<uword>(call_address() + 1);
	return return_address() + offset;
	}

	void set_target(uword target) const {
	uword* target_addr = reinterpret_cast<uword*>(call_address() + 1);
	uword offset = target - return_address();
	*target_addr = offset;
	CPU::FlushICache(call_address(), kInstructionSize);
	}

	RawObject* ic_data() const {
	return reinterpret_cast<RawObject*>(start_ + 1);
	}

	static const int kNumInstructions = 2;
	static const int kInstructionSize = 5; // All instructions have same length.

	private:
	uword return_address() const {
	return start_ + kNumInstructions * kInstructionSize;
	}

	uword call_address() const {
	return start_ + 1 * kInstructionSize;
	}

	uword start_;
	DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedCall);
	};


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

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(InstanceCall);
	};


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

	private:
	DISALLOW_IMPLICIT_CONSTRUCTORS(UnoptimizedStaticCall);
	};


	// The expected pattern of a dart static call:
	// mov EDX, arguments_descriptor_array (optional in polymorphic calls)
	// call target_address
	// <- return address
	class StaticCall : public ValueObject {
	public:
	explicit StaticCall(uword return_address)
	: start_(return_address - (kNumInstructions * kInstructionSize)) {
	ASSERT(IsValid(return_address));
	ASSERT(kInstructionSize == Assembler::kCallExternalLabelSize);
	}

	static bool IsValid(uword return_address) {
	uint8_t* code_bytes =
	reinterpret_cast<uint8_t*>(
	return_address - (kNumInstructions * kInstructionSize));
	return (code_bytes[0] == 0xE8);
	}

	uword target() const {
	const uword offset = reinterpret_cast<uword>(call_address() + 1);
	return return_address() + offset;
	}

	void set_target(uword target) const {
	uword* target_addr = reinterpret_cast<uword*>(call_address() + 1);
	uword offset = target - return_address();
	*target_addr = offset;
	CPU::FlushICache(call_address(), kInstructionSize);
	}

	static const int kNumInstructions = 1;
	static const int kInstructionSize = 5; // All instructions have same length.

	private:
	uword return_address() const {
	return start_ + kNumInstructions * kInstructionSize;
	}

	uword call_address() const {
	return start_;
	}

	uword start_;

	DISALLOW_IMPLICIT_CONSTRUCTORS(StaticCall);
	};


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


	void CodePatcher::PatchStaticCallAt(uword return_address,
	const Code& code,
	uword new_target) {
	ASSERT(code.ContainsInstructionAt(return_address));
	StaticCall call(return_address);
	call.set_target(new_target);
	}


	void CodePatcher::PatchInstanceCallAt(uword return_address,
	const Code& code,
	uword new_target) {
	ASSERT(code.ContainsInstructionAt(return_address));
	InstanceCall call(return_address);
	call.set_target(new_target);
	}


	int32_t CodePatcher::GetPoolOffsetAt(uword return_address) {
	UNREACHABLE();
	return 0;
	}


	void CodePatcher::SetPoolOffsetAt(uword return_address, int32_t offset) {
	UNREACHABLE();
	}


	void CodePatcher::InsertCallAt(uword start, uword target) {
	// The inserted call should not overlap the lazy deopt jump code.
	ASSERT(start + CallPattern::InstructionLength() <= target);
	reinterpret_cast<uint8_t>(start) = 0xE8;
	CallPattern call(start);
	call.SetTargetAddress(target);
	CPU::FlushICache(start, CallPattern::InstructionLength());
	}


	uword CodePatcher::GetInstanceCallAt(
	uword return_address, const Code& code, ICData* ic_data) {
	ASSERT(code.ContainsInstructionAt(return_address));
	InstanceCall call(return_address);
	if (ic_data != NULL) {
	*ic_data ^= call.ic_data();
	}
	return call.target();
	}


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


	intptr_t CodePatcher::InstanceCallSizeInBytes() {
	return InstanceCall::kNumInstructions * InstanceCall::kInstructionSize;
	}


	// The expected code pattern of an edge counter in unoptimized code:
	// b8 imm32 mov EAX, immediate
	class EdgeCounter : public ValueObject {
	public:
	EdgeCounter(uword pc, const Code& ignored)
	: end_(pc - FlowGraphCompiler::EdgeCounterIncrementSizeInBytes()) {
	ASSERT(IsValid(end_));
	}

	static bool IsValid(uword end) {
	return (reinterpret_cast<uint8_t>(end - 5) == 0xb8);
	}

	RawObject* edge_counter() const {
	return reinterpret_cast<RawObject*>(end_ - 4);
	}

	private:
	uword end_;
	};


	RawObject* CodePatcher::GetEdgeCounterAt(uword pc, const Code& code) {
	ASSERT(code.ContainsInstructionAt(pc));
	EdgeCounter counter(pc, code);
	return counter.edge_counter();
	}

	} // namespace dart

	#endif // defined TARGET_ARCH_IA32