runtime/vm/interpreter.h - sdk.git - Git at Google

 // Copyright (c) 2018, 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.

 #ifndef RUNTIME_VM_INTERPRETER_H_
 #define RUNTIME_VM_INTERPRETER_H_

 #include "vm/globals.h"
 #if !defined(DART_PRECOMPILED_RUNTIME)

 #include "vm/compiler/method_recognizer.h"
 #include "vm/constants_kbc.h"
 #include "vm/tagged_pointer.h"

 namespace dart {

 class Array;
 class Code;
 class InterpreterSetjmpBuffer;
 class Isolate;
 class ObjectPointerVisitor;
 class Thread;

 class LookupCache : public ValueObject {
  public:
   LookupCache() {
     ASSERT(Utils::IsPowerOfTwo(sizeof(Entry)));
     ASSERT(Utils::IsPowerOfTwo(sizeof(kNumEntries)));
     Clear();
   }

   void Clear();
   bool Lookup(intptr_t receiver_cid,
               StringPtr function_name,
               ArrayPtr arguments_descriptor,
               FunctionPtr* target) const;
   void Insert(intptr_t receiver_cid,
               StringPtr function_name,
               ArrayPtr arguments_descriptor,
               FunctionPtr target);

  private:
   struct Entry {
     intptr_t receiver_cid;
     StringPtr function_name;
     ArrayPtr arguments_descriptor;
     FunctionPtr target;
   };

   static const intptr_t kNumEntries = 1024;
   static const intptr_t kTableMask = kNumEntries - 1;

   Entry entries_[kNumEntries];
 };

 // Interpreter intrinsic handler. It is invoked on entry to the intrinsified
 // function via Intrinsic bytecode before the frame is setup.
 // If the handler returns true then Intrinsic bytecode works as a return
 // instruction returning the value in result. Otherwise interpreter proceeds to
 // execute the body of the function.
 typedef bool (*IntrinsicHandler)(Thread* thread,
                                  ObjectPtr* FP,
                                  ObjectPtr* result);

 class Interpreter {
  public:
   static const uword kInterpreterStackUnderflowSize = 0x80;
   // The entry frame pc marker must be non-zero (a valid exception handler pc).
   static const word kEntryFramePcMarker = -1;

   Interpreter();
   ~Interpreter();

   // The currently executing Interpreter instance, which is associated to the
   // current isolate
   static Interpreter* Current();

   // Low address (KBC stack grows up).
   uword stack_base() const { return stack_base_; }
   // Limit for StackOverflowError.
   uword overflow_stack_limit() const { return overflow_stack_limit_; }
   // High address (KBC stack grows up).
   uword stack_limit() const { return stack_limit_; }

   // Returns true if the interpreter's stack contains the given frame.
   // TODO(regis): We should rely on a new thread vm_tag to identify an
   // interpreter frame and not need this HasFrame() method.
   bool HasFrame(uword frame) const {
     return frame >= stack_base() && frame < stack_limit();
   }

   // Identify an entry frame by looking at its pc marker value.
   static bool IsEntryFrameMarker(const KBCInstr* pc) {
     return reinterpret_cast<word>(pc) == kEntryFramePcMarker;
   }

   ObjectPtr Call(const Function& function,
                  const Array& arguments_descriptor,
                  const Array& arguments,
                  Thread* thread);

   ObjectPtr Call(FunctionPtr function,
                  ArrayPtr argdesc,
                  intptr_t argc,
                  ObjectPtr const* argv,
                  Thread* thread);

   void JumpToFrame(uword pc, uword sp, uword fp, Thread* thread);

   uword get_sp() const { return reinterpret_cast<uword>(fp_); }  // Yes, fp_.
   uword get_fp() const { return reinterpret_cast<uword>(fp_); }
   uword get_pc() const { return reinterpret_cast<uword>(pc_); }

   void Unexit(Thread* thread);

   void VisitObjectPointers(ObjectPointerVisitor* visitor);
   void ClearLookupCache() { lookup_cache_.Clear(); }

 #ifndef PRODUCT
   void set_is_debugging(bool value) { is_debugging_ = value; }
   bool is_debugging() const { return is_debugging_; }
 #endif  // !PRODUCT

  private:
   uintptr_t* stack_;
   uword stack_base_;
   uword overflow_stack_limit_;
   uword stack_limit_;

   ObjectPtr* volatile fp_;
   const KBCInstr* volatile pc_;
   DEBUG_ONLY(uint64_t icount_;)

   InterpreterSetjmpBuffer* last_setjmp_buffer_;

   ObjectPoolPtr pp_;  // Pool Pointer.
   ArrayPtr argdesc_;  // Arguments Descriptor: used to pass information between
                       // call instruction and the function entry.
   ObjectPtr special_[KernelBytecode::kSpecialIndexCount];

   LookupCache lookup_cache_;

   void Exit(Thread* thread,
             ObjectPtr* base,
             ObjectPtr* exit_frame,
             const KBCInstr* pc);

   bool Invoke(Thread* thread,
               ObjectPtr* call_base,
               ObjectPtr* call_top,
               const KBCInstr** pc,
               ObjectPtr** FP,
               ObjectPtr** SP);

   bool InvokeCompiled(Thread* thread,
                       FunctionPtr function,
                       ObjectPtr* call_base,
                       ObjectPtr* call_top,
                       const KBCInstr** pc,
                       ObjectPtr** FP,
                       ObjectPtr** SP);

   bool InvokeBytecode(Thread* thread,
                       FunctionPtr function,
                       ObjectPtr* call_base,
                       ObjectPtr* call_top,
                       const KBCInstr** pc,
                       ObjectPtr** FP,
                       ObjectPtr** SP);

   bool InstanceCall(Thread* thread,
                     StringPtr target_name,
                     ObjectPtr* call_base,
                     ObjectPtr* call_top,
                     const KBCInstr** pc,
                     ObjectPtr** FP,
                     ObjectPtr** SP);

   bool CopyParameters(Thread* thread,
                       const KBCInstr** pc,
                       ObjectPtr** FP,
                       ObjectPtr** SP,
                       const intptr_t num_fixed_params,
                       const intptr_t num_opt_pos_params,
                       const intptr_t num_opt_named_params);

   bool AssertAssignable(Thread* thread,
                         const KBCInstr* pc,
                         ObjectPtr* FP,
                         ObjectPtr* call_top,
                         ObjectPtr* args,
                         SubtypeTestCachePtr cache);
   template <bool is_getter>
   bool AssertAssignableField(Thread* thread,
                              const KBCInstr* pc,
                              ObjectPtr* FP,
                              ObjectPtr* SP,
                              InstancePtr instance,
                              FieldPtr field,
                              InstancePtr value);

   bool AllocateMint(Thread* thread,
                     int64_t value,
                     const KBCInstr* pc,
                     ObjectPtr* FP,
                     ObjectPtr* SP);
   bool AllocateDouble(Thread* thread,
                       double value,
                       const KBCInstr* pc,
                       ObjectPtr* FP,
                       ObjectPtr* SP);
   bool AllocateFloat32x4(Thread* thread,
                          simd128_value_t value,
                          const KBCInstr* pc,
                          ObjectPtr* FP,
                          ObjectPtr* SP);
   bool AllocateFloat64x2(Thread* thread,
                          simd128_value_t value,
                          const KBCInstr* pc,
                          ObjectPtr* FP,
                          ObjectPtr* SP);
   bool AllocateArray(Thread* thread,
                      TypeArgumentsPtr type_args,
                      ObjectPtr length,
                      const KBCInstr* pc,
                      ObjectPtr* FP,
                      ObjectPtr* SP);
   bool AllocateContext(Thread* thread,
                        intptr_t num_variables,
                        const KBCInstr* pc,
                        ObjectPtr* FP,
                        ObjectPtr* SP);
   bool AllocateClosure(Thread* thread,
                        const KBCInstr* pc,
                        ObjectPtr* FP,
                        ObjectPtr* SP);

 #if defined(DEBUG)
   // Returns true if tracing of executed instructions is enabled.
   bool IsTracingExecution() const;

   // Prints bytecode instruction at given pc for instruction tracing.
   void TraceInstruction(const KBCInstr* pc) const;

   bool IsWritingTraceFile() const;
   void FlushTraceBuffer();
   void WriteInstructionToTrace(const KBCInstr* pc);

   void* trace_file_;
   uint64_t trace_file_bytes_written_;

   static const intptr_t kTraceBufferSizeInBytes = 10 * KB;
   static const intptr_t kTraceBufferInstrs =
       kTraceBufferSizeInBytes / sizeof(KBCInstr);
   KBCInstr* trace_buffer_;
   intptr_t trace_buffer_idx_;
 #endif  // defined(DEBUG)

   // Longjmp support for exceptions.
   InterpreterSetjmpBuffer* last_setjmp_buffer() { return last_setjmp_buffer_; }
   void set_last_setjmp_buffer(InterpreterSetjmpBuffer* buffer) {
     last_setjmp_buffer_ = buffer;
   }

 #ifndef PRODUCT
   bool is_debugging_ = false;
 #endif  // !PRODUCT

   bool supports_unboxed_doubles_;
   bool supports_unboxed_simd128_;

   friend class InterpreterSetjmpBuffer;

   DISALLOW_COPY_AND_ASSIGN(Interpreter);
 };

 }  // namespace dart

 #endif  // !defined(DART_PRECOMPILED_RUNTIME)

 #endif  // RUNTIME_VM_INTERPRETER_H_
	// Copyright (c) 2018, 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.

	#ifndef RUNTIME_VM_INTERPRETER_H_
	#define RUNTIME_VM_INTERPRETER_H_

	#include "vm/globals.h"
	#if !defined(DART_PRECOMPILED_RUNTIME)

	#include "vm/compiler/method_recognizer.h"
	#include "vm/constants_kbc.h"
	#include "vm/tagged_pointer.h"

	namespace dart {

	class Array;
	class Code;
	class InterpreterSetjmpBuffer;
	class Isolate;
	class ObjectPointerVisitor;
	class Thread;

	class LookupCache : public ValueObject {
	public:
	LookupCache() {
	ASSERT(Utils::IsPowerOfTwo(sizeof(Entry)));
	ASSERT(Utils::IsPowerOfTwo(sizeof(kNumEntries)));
	Clear();
	}

	void Clear();
	bool Lookup(intptr_t receiver_cid,
	StringPtr function_name,
	ArrayPtr arguments_descriptor,
	FunctionPtr* target) const;
	void Insert(intptr_t receiver_cid,
	StringPtr function_name,
	ArrayPtr arguments_descriptor,
	FunctionPtr target);

	private:
	struct Entry {
	intptr_t receiver_cid;
	StringPtr function_name;
	ArrayPtr arguments_descriptor;
	FunctionPtr target;
	};

	static const intptr_t kNumEntries = 1024;
	static const intptr_t kTableMask = kNumEntries - 1;

	Entry entries_[kNumEntries];
	};

	// Interpreter intrinsic handler. It is invoked on entry to the intrinsified
	// function via Intrinsic bytecode before the frame is setup.
	// If the handler returns true then Intrinsic bytecode works as a return
	// instruction returning the value in result. Otherwise interpreter proceeds to
	// execute the body of the function.
	typedef bool (IntrinsicHandler)(Thread thread,
	ObjectPtr* FP,
	ObjectPtr* result);

	class Interpreter {
	public:
	static const uword kInterpreterStackUnderflowSize = 0x80;
	// The entry frame pc marker must be non-zero (a valid exception handler pc).
	static const word kEntryFramePcMarker = -1;

	Interpreter();
	~Interpreter();

	// The currently executing Interpreter instance, which is associated to the
	// current isolate
	static Interpreter* Current();

	// Low address (KBC stack grows up).
	uword stack_base() const { return stack_base_; }
	// Limit for StackOverflowError.
	uword overflow_stack_limit() const { return overflow_stack_limit_; }
	// High address (KBC stack grows up).
	uword stack_limit() const { return stack_limit_; }

	// Returns true if the interpreter's stack contains the given frame.
	// TODO(regis): We should rely on a new thread vm_tag to identify an
	// interpreter frame and not need this HasFrame() method.
	bool HasFrame(uword frame) const {
	return frame >= stack_base() && frame < stack_limit();
	}

	// Identify an entry frame by looking at its pc marker value.
	static bool IsEntryFrameMarker(const KBCInstr* pc) {
	return reinterpret_cast<word>(pc) == kEntryFramePcMarker;
	}

	ObjectPtr Call(const Function& function,
	const Array& arguments_descriptor,
	const Array& arguments,
	Thread* thread);

	ObjectPtr Call(FunctionPtr function,
	ArrayPtr argdesc,
	intptr_t argc,
	ObjectPtr const* argv,
	Thread* thread);

	void JumpToFrame(uword pc, uword sp, uword fp, Thread* thread);

	uword get_sp() const { return reinterpret_cast<uword>(fp_); } // Yes, fp_.
	uword get_fp() const { return reinterpret_cast<uword>(fp_); }
	uword get_pc() const { return reinterpret_cast<uword>(pc_); }

	void Unexit(Thread* thread);

	void VisitObjectPointers(ObjectPointerVisitor* visitor);
	void ClearLookupCache() { lookup_cache_.Clear(); }

	#ifndef PRODUCT
	void set_is_debugging(bool value) { is_debugging_ = value; }
	bool is_debugging() const { return is_debugging_; }
	#endif // !PRODUCT

	private:
	uintptr_t* stack_;
	uword stack_base_;
	uword overflow_stack_limit_;
	uword stack_limit_;

	ObjectPtr* volatile fp_;
	const KBCInstr* volatile pc_;
	DEBUG_ONLY(uint64_t icount_;)

	InterpreterSetjmpBuffer* last_setjmp_buffer_;

	ObjectPoolPtr pp_; // Pool Pointer.
	ArrayPtr argdesc_; // Arguments Descriptor: used to pass information between
	// call instruction and the function entry.
	ObjectPtr special_[KernelBytecode::kSpecialIndexCount];

	LookupCache lookup_cache_;

	void Exit(Thread* thread,
	ObjectPtr* base,
	ObjectPtr* exit_frame,
	const KBCInstr* pc);

	bool Invoke(Thread* thread,
	ObjectPtr* call_base,
	ObjectPtr* call_top,
	const KBCInstr** pc,
	ObjectPtr** FP,
	ObjectPtr** SP);

	bool InvokeCompiled(Thread* thread,
	FunctionPtr function,
	ObjectPtr* call_base,
	ObjectPtr* call_top,
	const KBCInstr** pc,
	ObjectPtr** FP,
	ObjectPtr** SP);

	bool InvokeBytecode(Thread* thread,
	FunctionPtr function,
	ObjectPtr* call_base,
	ObjectPtr* call_top,
	const KBCInstr** pc,
	ObjectPtr** FP,
	ObjectPtr** SP);

	bool InstanceCall(Thread* thread,
	StringPtr target_name,
	ObjectPtr* call_base,
	ObjectPtr* call_top,
	const KBCInstr** pc,
	ObjectPtr** FP,
	ObjectPtr** SP);

	bool CopyParameters(Thread* thread,
	const KBCInstr** pc,
	ObjectPtr** FP,
	ObjectPtr** SP,
	const intptr_t num_fixed_params,
	const intptr_t num_opt_pos_params,
	const intptr_t num_opt_named_params);

	bool AssertAssignable(Thread* thread,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* call_top,
	ObjectPtr* args,
	SubtypeTestCachePtr cache);
	template <bool is_getter>
	bool AssertAssignableField(Thread* thread,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP,
	InstancePtr instance,
	FieldPtr field,
	InstancePtr value);

	bool AllocateMint(Thread* thread,
	int64_t value,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateDouble(Thread* thread,
	double value,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateFloat32x4(Thread* thread,
	simd128_value_t value,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateFloat64x2(Thread* thread,
	simd128_value_t value,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateArray(Thread* thread,
	TypeArgumentsPtr type_args,
	ObjectPtr length,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateContext(Thread* thread,
	intptr_t num_variables,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);
	bool AllocateClosure(Thread* thread,
	const KBCInstr* pc,
	ObjectPtr* FP,
	ObjectPtr* SP);

	#if defined(DEBUG)
	// Returns true if tracing of executed instructions is enabled.
	bool IsTracingExecution() const;

	// Prints bytecode instruction at given pc for instruction tracing.
	void TraceInstruction(const KBCInstr* pc) const;

	bool IsWritingTraceFile() const;
	void FlushTraceBuffer();
	void WriteInstructionToTrace(const KBCInstr* pc);

	void* trace_file_;
	uint64_t trace_file_bytes_written_;

	static const intptr_t kTraceBufferSizeInBytes = 10 * KB;
	static const intptr_t kTraceBufferInstrs =
	kTraceBufferSizeInBytes / sizeof(KBCInstr);
	KBCInstr* trace_buffer_;
	intptr_t trace_buffer_idx_;
	#endif // defined(DEBUG)

	// Longjmp support for exceptions.
	InterpreterSetjmpBuffer* last_setjmp_buffer() { return last_setjmp_buffer_; }
	void set_last_setjmp_buffer(InterpreterSetjmpBuffer* buffer) {
	last_setjmp_buffer_ = buffer;
	}

	#ifndef PRODUCT
	bool is_debugging_ = false;
	#endif // !PRODUCT

	bool supports_unboxed_doubles_;
	bool supports_unboxed_simd128_;

	friend class InterpreterSetjmpBuffer;

	DISALLOW_COPY_AND_ASSIGN(Interpreter);
	};

	} // namespace dart

	#endif // !defined(DART_PRECOMPILED_RUNTIME)

	#endif // RUNTIME_VM_INTERPRETER_H_