runtime/vm/instructions_x64.h - 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.
 // Classes that describe assembly patterns as used by inline caches.

 #ifndef RUNTIME_VM_INSTRUCTIONS_X64_H_
 #define RUNTIME_VM_INSTRUCTIONS_X64_H_

 #ifndef RUNTIME_VM_INSTRUCTIONS_H_
 #error "Do not include instructions_x64.h directly; use instructions.h instead."
 #endif

 #include "platform/unaligned.h"
 #include "vm/allocation.h"

 namespace dart {

 intptr_t IndexFromPPLoadDisp8(uword start);
 intptr_t IndexFromPPLoadDisp32(uword start);

 // Template class for all instruction pattern classes.
 // P has to specify a static pattern and a pattern length method.
 template <class P>
 class InstructionPattern : public ValueObject {
  public:
   explicit InstructionPattern(uword pc) : start_(pc) { ASSERT(pc != 0); }

   // Call to check if the instruction pattern at 'pc' match the instruction.
   // 'P::pattern()' returns the expected byte pattern in form of an integer
   // array with length of 'P::pattern_length_in_bytes()'. A '-1' element means
   // 'any byte'.
   bool IsValid() const {
     return TestBytesWith(P::pattern(), P::pattern_length_in_bytes());
   }

  protected:
   uword start() const { return start_; }

  private:
   // Returns true if the 'num_bytes' bytes at 'start_' correspond to
   // array of integers 'data'. 'data' elements are either a byte or -1, which
   // represents any byte.
   bool TestBytesWith(const int* data, int num_bytes) const {
     ASSERT(data != NULL);
     const uint8_t* byte_array = reinterpret_cast<const uint8_t*>(start_);
     for (int i = 0; i < num_bytes; i++) {
       // Skip comparison for data[i] < 0.
       if ((data[i] >= 0) && (byte_array[i] != (0xFF & data[i]))) {
         return false;
       }
     }
     return true;
   }

   const uword start_;

   DISALLOW_COPY_AND_ASSIGN(InstructionPattern);
 };

 class ReturnPattern : public InstructionPattern<ReturnPattern> {
  public:
   explicit ReturnPattern(uword pc) : InstructionPattern(pc) {}

   static const int* pattern() {
     static const int kReturnPattern[kLengthInBytes] = {0xC3};
     return kReturnPattern;
   }

   static int pattern_length_in_bytes() { return kLengthInBytes; }

  private:
   static const int kLengthInBytes = 1;
 };

 // push rbp
 // mov rbp, rsp
 class ProloguePattern : public InstructionPattern<ProloguePattern> {
  public:
   explicit ProloguePattern(uword pc) : InstructionPattern(pc) {}

   static const int* pattern() {
     static const int kProloguePattern[kLengthInBytes] = {0x55, 0x48, 0x89,
                                                          0xe5};
     return kProloguePattern;
   }

   static int pattern_length_in_bytes() { return kLengthInBytes; }

  private:
   static const int kLengthInBytes = 4;
 };

 // mov rbp, rsp
 class SetFramePointerPattern
     : public InstructionPattern<SetFramePointerPattern> {
  public:
   explicit SetFramePointerPattern(uword pc) : InstructionPattern(pc) {}

   static const int* pattern() {
     static const int kFramePointerPattern[kLengthInBytes] = {0x48, 0x89, 0xe5};
     return kFramePointerPattern;
   }

   static int pattern_length_in_bytes() { return kLengthInBytes; }

  private:
   static const int kLengthInBytes = 3;
 };

 // callq *[rip+offset]
 class PcRelativeCallPattern : public InstructionPattern<PcRelativeCallPattern> {
  public:
   static constexpr intptr_t kLowerCallingRange = -(DART_UINT64_C(1) << 31);
   static constexpr intptr_t kUpperCallingRange = (DART_UINT64_C(1) << 31) - 1;

   explicit PcRelativeCallPattern(uword pc) : InstructionPattern(pc) {}

   int32_t distance() {
     return LoadUnaligned(reinterpret_cast<int32_t*>(start() + 1)) +
            kLengthInBytes;
   }

   void set_distance(int32_t distance) {
     // [distance] is relative to the start of the instruction, x64 considers the
     // offset relative to next PC.
     StoreUnaligned(reinterpret_cast<int32_t*>(start() + 1),
                    distance - kLengthInBytes);
   }

   static const int* pattern() {
     static const int kPattern[kLengthInBytes] = {0xe8, -1, -1, -1, -1};
     return kPattern;
   }

   static int pattern_length_in_bytes() { return kLengthInBytes; }

   static const int kLengthInBytes = 5;
 };

 // Instruction pattern for a tail call to a signed 32-bit PC-relative offset
 //
 // The AOT compiler can emit PC-relative calls. If the destination of such a
 // call is not in range for the "bl.<cond> <offset>" instruction, the AOT
 // compiler will emit a trampoline which is in range. That trampoline will
 // then tail-call to the final destination (also via PC-relative offset, but it
 // supports a full signed 32-bit offset).
 //
 // The pattern of the trampoline looks like:
 //
 //     jmp $rip + <offset>
 //
 // (Strictly speaking the pc-relative call distance on X64 is big enough, but
 // for making AOT relocation code (i.e. relocation.cc) platform independent and
 // allow testing of trampolines on X64 we have it nonetheless)
 class PcRelativeTrampolineJumpPattern : public ValueObject {
  public:
   static const int kLengthInBytes = 5;

   explicit PcRelativeTrampolineJumpPattern(uword pattern_start)
       : pattern_start_(pattern_start) {}

   void Initialize() {
     uint8_t* pattern = reinterpret_cast<uint8_t*>(pattern_start_);
     pattern[0] = 0xe9;
   }

   int32_t distance() {
     return LoadUnaligned(reinterpret_cast<int32_t*>(pattern_start_ + 1)) +
            kLengthInBytes;
   }

   void set_distance(intptr_t distance) {
     // [distance] is relative to the start of the instruction, x64 considers the
     // offset relative to next PC.
     StoreUnaligned(reinterpret_cast<int32_t*>(pattern_start_ + 1),
                    static_cast<int32_t>(distance - kLengthInBytes));
   }

   bool IsValid() const {
     uint8_t* pattern = reinterpret_cast<uint8_t*>(pattern_start_);
     return pattern[0] == 0xe9;
   }

  private:
   uword pattern_start_;
 };

 class PcRelativeTailCallPattern : public PcRelativeTrampolineJumpPattern {
  public:
   static constexpr intptr_t kLowerCallingRange = -(DART_INT64_C(1) << 31) + kLengthInBytes;
   static constexpr intptr_t kUpperCallingRange = (DART_INT64_C(1) << 31) - 1;

   explicit PcRelativeTailCallPattern(uword pc)
       : PcRelativeTrampolineJumpPattern(pc) {}
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_INSTRUCTIONS_X64_H_
	// 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.
	// Classes that describe assembly patterns as used by inline caches.

	#ifndef RUNTIME_VM_INSTRUCTIONS_X64_H_
	#define RUNTIME_VM_INSTRUCTIONS_X64_H_

	#ifndef RUNTIME_VM_INSTRUCTIONS_H_
	#error "Do not include instructions_x64.h directly; use instructions.h instead."
	#endif

	#include "platform/unaligned.h"
	#include "vm/allocation.h"

	namespace dart {

	intptr_t IndexFromPPLoadDisp8(uword start);
	intptr_t IndexFromPPLoadDisp32(uword start);

	// Template class for all instruction pattern classes.
	// P has to specify a static pattern and a pattern length method.
	template <class P>
	class InstructionPattern : public ValueObject {
	public:
	explicit InstructionPattern(uword pc) : start_(pc) { ASSERT(pc != 0); }

	// Call to check if the instruction pattern at 'pc' match the instruction.
	// 'P::pattern()' returns the expected byte pattern in form of an integer
	// array with length of 'P::pattern_length_in_bytes()'. A '-1' element means
	// 'any byte'.
	bool IsValid() const {
	return TestBytesWith(P::pattern(), P::pattern_length_in_bytes());
	}

	protected:
	uword start() const { return start_; }

	private:
	// Returns true if the 'num_bytes' bytes at 'start_' correspond to
	// array of integers 'data'. 'data' elements are either a byte or -1, which
	// represents any byte.
	bool TestBytesWith(const int* data, int num_bytes) const {
	ASSERT(data != NULL);
	const uint8_t* byte_array = reinterpret_cast<const uint8_t*>(start_);
	for (int i = 0; i < num_bytes; i++) {
	// Skip comparison for data[i] < 0.
	if ((data[i] >= 0) && (byte_array[i] != (0xFF & data[i]))) {
	return false;
	}
	}
	return true;
	}

	const uword start_;

	DISALLOW_COPY_AND_ASSIGN(InstructionPattern);
	};

	class ReturnPattern : public InstructionPattern<ReturnPattern> {
	public:
	explicit ReturnPattern(uword pc) : InstructionPattern(pc) {}

	static const int* pattern() {
	static const int kReturnPattern[kLengthInBytes] = {0xC3};
	return kReturnPattern;
	}

	static int pattern_length_in_bytes() { return kLengthInBytes; }

	private:
	static const int kLengthInBytes = 1;
	};

	// push rbp
	// mov rbp, rsp
	class ProloguePattern : public InstructionPattern<ProloguePattern> {
	public:
	explicit ProloguePattern(uword pc) : InstructionPattern(pc) {}

	static const int* pattern() {
	static const int kProloguePattern[kLengthInBytes] = {0x55, 0x48, 0x89,
	0xe5};
	return kProloguePattern;
	}

	static int pattern_length_in_bytes() { return kLengthInBytes; }

	private:
	static const int kLengthInBytes = 4;
	};

	// mov rbp, rsp
	class SetFramePointerPattern
	: public InstructionPattern<SetFramePointerPattern> {
	public:
	explicit SetFramePointerPattern(uword pc) : InstructionPattern(pc) {}

	static const int* pattern() {
	static const int kFramePointerPattern[kLengthInBytes] = {0x48, 0x89, 0xe5};
	return kFramePointerPattern;
	}

	static int pattern_length_in_bytes() { return kLengthInBytes; }

	private:
	static const int kLengthInBytes = 3;
	};

	// callq *[rip+offset]
	class PcRelativeCallPattern : public InstructionPattern<PcRelativeCallPattern> {
	public:
	static constexpr intptr_t kLowerCallingRange = -(DART_UINT64_C(1) << 31);
	static constexpr intptr_t kUpperCallingRange = (DART_UINT64_C(1) << 31) - 1;

	explicit PcRelativeCallPattern(uword pc) : InstructionPattern(pc) {}

	int32_t distance() {
	return LoadUnaligned(reinterpret_cast<int32_t*>(start() + 1)) +
	kLengthInBytes;
	}

	void set_distance(int32_t distance) {
	// [distance] is relative to the start of the instruction, x64 considers the
	// offset relative to next PC.
	StoreUnaligned(reinterpret_cast<int32_t*>(start() + 1),
	distance - kLengthInBytes);
	}

	static const int* pattern() {
	static const int kPattern[kLengthInBytes] = {0xe8, -1, -1, -1, -1};
	return kPattern;
	}

	static int pattern_length_in_bytes() { return kLengthInBytes; }

	static const int kLengthInBytes = 5;
	};

	// Instruction pattern for a tail call to a signed 32-bit PC-relative offset
	//
	// The AOT compiler can emit PC-relative calls. If the destination of such a
	// call is not in range for the "bl.<cond> <offset>" instruction, the AOT
	// compiler will emit a trampoline which is in range. That trampoline will
	// then tail-call to the final destination (also via PC-relative offset, but it
	// supports a full signed 32-bit offset).
	//
	// The pattern of the trampoline looks like:
	//
	// jmp $rip + <offset>
	//
	// (Strictly speaking the pc-relative call distance on X64 is big enough, but
	// for making AOT relocation code (i.e. relocation.cc) platform independent and
	// allow testing of trampolines on X64 we have it nonetheless)
	class PcRelativeTrampolineJumpPattern : public ValueObject {
	public:
	static const int kLengthInBytes = 5;

	explicit PcRelativeTrampolineJumpPattern(uword pattern_start)
	: pattern_start_(pattern_start) {}

	void Initialize() {
	uint8_t* pattern = reinterpret_cast<uint8_t*>(pattern_start_);
	pattern[0] = 0xe9;
	}

	int32_t distance() {
	return LoadUnaligned(reinterpret_cast<int32_t*>(pattern_start_ + 1)) +
	kLengthInBytes;
	}

	void set_distance(intptr_t distance) {
	// [distance] is relative to the start of the instruction, x64 considers the
	// offset relative to next PC.
	StoreUnaligned(reinterpret_cast<int32_t*>(pattern_start_ + 1),
	static_cast<int32_t>(distance - kLengthInBytes));
	}

	bool IsValid() const {
	uint8_t* pattern = reinterpret_cast<uint8_t*>(pattern_start_);
	return pattern[0] == 0xe9;
	}

	private:
	uword pattern_start_;
	};

	class PcRelativeTailCallPattern : public PcRelativeTrampolineJumpPattern {
	public:
	static constexpr intptr_t kLowerCallingRange = -(DART_INT64_C(1) << 31) + kLengthInBytes;
	static constexpr intptr_t kUpperCallingRange = (DART_INT64_C(1) << 31) - 1;

	explicit PcRelativeTailCallPattern(uword pc)
	: PcRelativeTrampolineJumpPattern(pc) {}
	};

	} // namespace dart

	#endif // RUNTIME_VM_INSTRUCTIONS_X64_H_