runtime/lib/integers.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/bootstrap_natives.h"

 #include "include/dart_api.h"
 #include "vm/dart_entry.h"
 #include "vm/dart_api_impl.h"
 #include "vm/exceptions.h"
 #include "vm/isolate.h"
 #include "vm/native_entry.h"
 #include "vm/object.h"
 #include "vm/object_store.h"
 #include "vm/symbols.h"

 namespace dart {

 DEFINE_FLAG(bool, trace_intrinsified_natives, false,
     "Report if any of the intrinsified natives are called");

 // Smi natives.

 // Returns false if integer is in wrong representation, e.g., as is a Bigint
 // when it could have been a Smi.
 static bool CheckInteger(const Integer& i) {
   if (i.IsBigint()) {
     const Bigint& bigint = Bigint::Cast(i);
     return !bigint.FitsIntoSmi() && !bigint.FitsIntoInt64();
   }
   if (i.IsMint()) {
     const Mint& mint = Mint::Cast(i);
     return !Smi::IsValid(mint.value());
   }
   return true;
 }


 DEFINE_NATIVE_ENTRY(Integer_bitAndFromInteger, 2) {
   const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right));
   ASSERT(CheckInteger(left));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_bitAndFromInteger %s & %s\n",
         right.ToCString(), left.ToCString());
   }
   const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_AND, right));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_bitOrFromInteger, 2) {
   const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right));
   ASSERT(CheckInteger(left));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_bitOrFromInteger %s | %s\n",
         left.ToCString(), right.ToCString());
   }
   const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_OR, right));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_bitXorFromInteger, 2) {
   const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right));
   ASSERT(CheckInteger(left));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_bitXorFromInteger %s ^ %s\n",
         left.ToCString(), right.ToCString());
   }
   const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_XOR, right));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_addFromInteger, 2) {
   const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right_int));
   ASSERT(CheckInteger(left_int));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_addFromInteger %s + %s\n",
         left_int.ToCString(), right_int.ToCString());
   }
   const Integer& result =
       Integer::Handle(left_int.ArithmeticOp(Token::kADD, right_int));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_subFromInteger, 2) {
   const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right_int));
   ASSERT(CheckInteger(left_int));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_subFromInteger %s - %s\n",
         left_int.ToCString(), right_int.ToCString());
   }
   const Integer& result =
       Integer::Handle(left_int.ArithmeticOp(Token::kSUB, right_int));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_mulFromInteger, 2) {
   const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right_int));
   ASSERT(CheckInteger(left_int));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_mulFromInteger %s * %s\n",
         left_int.ToCString(), right_int.ToCString());
   }
   const Integer& result =
       Integer::Handle(left_int.ArithmeticOp(Token::kMUL, right_int));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_truncDivFromInteger, 2) {
   const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right_int));
   ASSERT(CheckInteger(left_int));
   ASSERT(!right_int.IsZero());
   const Integer& result =
       Integer::Handle(left_int.ArithmeticOp(Token::kTRUNCDIV, right_int));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_moduloFromInteger, 2) {
   const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right_int));
   ASSERT(CheckInteger(right_int));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_moduloFromInteger %s mod %s\n",
         left_int.ToCString(), right_int.ToCString());
   }
   if (right_int.IsZero()) {
     // Should have been caught before calling into runtime.
     UNIMPLEMENTED();
   }
   const Integer& result =
       Integer::Handle(left_int.ArithmeticOp(Token::kMOD, right_int));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Integer_greaterThanFromInteger, 2) {
   const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(right));
   ASSERT(CheckInteger(left));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_greaterThanFromInteger %s > %s\n",
         left.ToCString(), right.ToCString());
   }
   return Bool::Get(left.CompareWith(right) == 1).raw();
 }


 DEFINE_NATIVE_ENTRY(Integer_equalToInteger, 2) {
   const Integer& left = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, right, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(left));
   ASSERT(CheckInteger(right));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Integer_equalToInteger %s == %s\n",
         left.ToCString(), right.ToCString());
   }
   return Bool::Get(left.CompareWith(right) == 0).raw();
 }


 static RawInteger* ParseInteger(const String& value) {
   // Used by both Integer_parse and Integer_fromEnvironment.
   if (value.IsOneByteString()) {
     // Quick conversion for unpadded integers in strings.
     const intptr_t len = value.Length();
     if (len > 0) {
       const char* cstr = value.ToCString();
       ASSERT(cstr != NULL);
       char* p_end = NULL;
       const int64_t int_value = strtoll(cstr, &p_end, 10);
       if (p_end == (cstr + len)) {
         if ((int_value != LLONG_MIN) && (int_value != LLONG_MAX)) {
           return Integer::New(int_value);
         }
       }
     }
   }

   Scanner scanner(value, Symbols::Empty());
   const Scanner::GrowableTokenStream& tokens = scanner.GetStream();
   const String* int_string;
   bool is_positive;
   if (Scanner::IsValidLiteral(tokens,
                              Token::kINTEGER,
                              &is_positive,
                              &int_string)) {
     if (is_positive) {
       return Integer::New(*int_string);
     }
     String& temp = String::Handle();
     temp = String::Concat(Symbols::Dash(), *int_string);
     return Integer::New(temp);
   }

   return Integer::null();
 }


 DEFINE_NATIVE_ENTRY(Integer_parse, 1) {
   GET_NON_NULL_NATIVE_ARGUMENT(String, value, arguments->NativeArgAt(0));
   return ParseInteger(value);
 }


 DEFINE_NATIVE_ENTRY(Integer_fromEnvironment, 3) {
   GET_NON_NULL_NATIVE_ARGUMENT(String, name, arguments->NativeArgAt(1));
   GET_NATIVE_ARGUMENT(Integer, default_value, arguments->NativeArgAt(2));
   // Call the embedder to supply us with the environment.
   const String& env_value =
       String::Handle(Api::CallEnvironmentCallback(isolate, name));
   if (!env_value.IsNull()) {
     const Integer& result = Integer::Handle(ParseInteger(env_value));
     if (!result.IsNull()) {
       if (result.IsSmi()) {
         return result.raw();
       }
       return result.CheckAndCanonicalize(NULL);
     }
   }
   return default_value.raw();
 }


 // Passing true for 'silent' prevents throwing JavascriptIntegerOverflow.
 static RawInteger* ShiftOperationHelper(Token::Kind kind,
                                         const Integer& value,
                                         const Smi& amount,
                                         const bool silent = false) {
   if (amount.Value() < 0) {
     Exceptions::ThrowArgumentError(amount);
   }
   if (value.IsSmi()) {
     const Smi& smi_value = Smi::Cast(value);
     return smi_value.ShiftOp(kind, amount, silent);
   }
   if (value.IsMint()) {
     const int64_t mint_value = value.AsInt64Value();
     const int count = Utils::HighestBit(mint_value);
     intptr_t shift_count = amount.Value();
     if (kind == Token::kSHR) {
       shift_count = -shift_count;
     }
     if ((count + shift_count) < Mint::kBits) {
       switch (kind) {
         case Token::kSHL:
           return Integer::New(mint_value << shift_count, Heap::kNew, silent);
         case Token::kSHR:
           return Integer::New(mint_value >> -shift_count, Heap::kNew, silent);
         default:
           UNIMPLEMENTED();
       }
     } else {
       // Overflow in shift, use Bigints
       return Integer::null();
     }
   } else {
     ASSERT(value.IsBigint());
   }
   return Integer::null();
 }


 DEFINE_NATIVE_ENTRY(Integer_leftShiftWithMask32, 3) {
   const Integer& value = Integer::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, shift_count, arguments->NativeArgAt(1));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(2));
   ASSERT(CheckInteger(value));
   ASSERT(CheckInteger(shift_count));
   ASSERT(CheckInteger(mask));
   if (!shift_count.IsSmi()) {
     // Shift count is too large..
     const Instance& exception =
         Instance::Handle(isolate->object_store()->out_of_memory());
     Exceptions::Throw(isolate, exception);
   }
   const Smi& smi_shift_count = Smi::Cast(shift_count);
   const Integer& shift_result = Integer::Handle(
       ShiftOperationHelper(Token::kSHL, value, smi_shift_count, true));
   const Integer& result =
       Integer::Handle(shift_result.BitOp(Token::kBIT_AND, mask));
   return result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Smi_shrFromInt, 2) {
   const Smi& amount = Smi::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, value, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(amount));
   ASSERT(CheckInteger(value));
   const Integer& result = Integer::Handle(
       ShiftOperationHelper(Token::kSHR, value, amount));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Smi_shlFromInt, 2) {
   const Smi& amount = Smi::CheckedHandle(arguments->NativeArgAt(0));
   GET_NON_NULL_NATIVE_ARGUMENT(Integer, value, arguments->NativeArgAt(1));
   ASSERT(CheckInteger(amount));
   ASSERT(CheckInteger(value));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Smi_shlFromInt: %s << %s\n",
         value.ToCString(), amount.ToCString());
   }
   const Integer& result = Integer::Handle(
       ShiftOperationHelper(Token::kSHL, value, amount));
   // A null result indicates that a bigint operation is required.
   return result.IsNull() ? result.raw() : result.AsValidInteger();
 }


 DEFINE_NATIVE_ENTRY(Smi_bitNegate, 1) {
   const Smi& operand = Smi::CheckedHandle(arguments->NativeArgAt(0));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Smi_bitNegate: %s\n", operand.ToCString());
   }
   intptr_t result = ~operand.Value();
   ASSERT(Smi::IsValid(result));
   return Smi::New(result);
 }


 DEFINE_NATIVE_ENTRY(Smi_bitLength, 1) {
   const Smi& operand = Smi::CheckedHandle(arguments->NativeArgAt(0));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Smi_bitLength: %s\n", operand.ToCString());
   }
   int64_t value = operand.AsInt64Value();
   intptr_t result = Utils::BitLength(value);
   ASSERT(Smi::IsValid(result));
   return Smi::New(result);
 }


 // Mint natives.

 DEFINE_NATIVE_ENTRY(Mint_bitNegate, 1) {
   const Mint& operand = Mint::CheckedHandle(arguments->NativeArgAt(0));
   ASSERT(CheckInteger(operand));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Mint_bitNegate: %s\n", operand.ToCString());
   }
   int64_t result = ~operand.value();
   return Integer::New(result);
 }


 DEFINE_NATIVE_ENTRY(Mint_bitLength, 1) {
   const Mint& operand = Mint::CheckedHandle(arguments->NativeArgAt(0));
   ASSERT(CheckInteger(operand));
   if (FLAG_trace_intrinsified_natives) {
     OS::Print("Mint_bitLength: %s\n", operand.ToCString());
   }
   int64_t value = operand.AsInt64Value();
   intptr_t result = Utils::BitLength(value);
   ASSERT(Smi::IsValid(result));
   return Smi::New(result);
 }


 DEFINE_NATIVE_ENTRY(Mint_shlFromInt, 2) {
   // Use the preallocated out of memory exception to avoid calling
   // into dart code or allocating any code.
   const Instance& exception =
       Instance::Handle(isolate->object_store()->out_of_memory());
   Exceptions::Throw(isolate, exception);
   UNREACHABLE();
   return 0;
 }


 // Bigint natives.

 DEFINE_NATIVE_ENTRY(Bigint_getNeg, 1) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   return bigint.neg();
 }


 DEFINE_NATIVE_ENTRY(Bigint_setNeg, 2) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   const Bool& neg = Bool::CheckedHandle(arguments->NativeArgAt(1));
   bigint.set_neg(neg);
   return Object::null();
 }


 DEFINE_NATIVE_ENTRY(Bigint_getUsed, 1) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   return bigint.used();
 }


 DEFINE_NATIVE_ENTRY(Bigint_setUsed, 2) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   const Smi& used = Smi::CheckedHandle(arguments->NativeArgAt(1));
   bigint.set_used(used);
   return Object::null();
 }


 DEFINE_NATIVE_ENTRY(Bigint_getDigits, 1) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   return bigint.digits();
 }


 DEFINE_NATIVE_ENTRY(Bigint_setDigits, 2) {
   const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
   const TypedData& digits = TypedData::CheckedHandle(arguments->NativeArgAt(1));
   bigint.set_digits(digits);
   return Object::null();
 }


 DEFINE_NATIVE_ENTRY(Bigint_allocate, 1) {
   // Argument is null type arguments, since class Bigint is not parameterized.
   return Bigint::New();
 }

 }  // namespace dart
	// 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/bootstrap_natives.h"

	#include "include/dart_api.h"
	#include "vm/dart_entry.h"
	#include "vm/dart_api_impl.h"
	#include "vm/exceptions.h"
	#include "vm/isolate.h"
	#include "vm/native_entry.h"
	#include "vm/object.h"
	#include "vm/object_store.h"
	#include "vm/symbols.h"

	namespace dart {

	DEFINE_FLAG(bool, trace_intrinsified_natives, false,
	"Report if any of the intrinsified natives are called");

	// Smi natives.

	// Returns false if integer is in wrong representation, e.g., as is a Bigint
	// when it could have been a Smi.
	static bool CheckInteger(const Integer& i) {
	if (i.IsBigint()) {
	const Bigint& bigint = Bigint::Cast(i);
	return !bigint.FitsIntoSmi() && !bigint.FitsIntoInt64();
	}
	if (i.IsMint()) {
	const Mint& mint = Mint::Cast(i);
	return !Smi::IsValid(mint.value());
	}
	return true;
	}


	DEFINE_NATIVE_ENTRY(Integer_bitAndFromInteger, 2) {
	const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right));
	ASSERT(CheckInteger(left));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_bitAndFromInteger %s & %s\n",
	right.ToCString(), left.ToCString());
	}
	const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_AND, right));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_bitOrFromInteger, 2) {
	const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right));
	ASSERT(CheckInteger(left));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_bitOrFromInteger %s \| %s\n",
	left.ToCString(), right.ToCString());
	}
	const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_OR, right));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_bitXorFromInteger, 2) {
	const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right));
	ASSERT(CheckInteger(left));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_bitXorFromInteger %s ^ %s\n",
	left.ToCString(), right.ToCString());
	}
	const Integer& result = Integer::Handle(left.BitOp(Token::kBIT_XOR, right));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_addFromInteger, 2) {
	const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right_int));
	ASSERT(CheckInteger(left_int));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_addFromInteger %s + %s\n",
	left_int.ToCString(), right_int.ToCString());
	}
	const Integer& result =
	Integer::Handle(left_int.ArithmeticOp(Token::kADD, right_int));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_subFromInteger, 2) {
	const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right_int));
	ASSERT(CheckInteger(left_int));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_subFromInteger %s - %s\n",
	left_int.ToCString(), right_int.ToCString());
	}
	const Integer& result =
	Integer::Handle(left_int.ArithmeticOp(Token::kSUB, right_int));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_mulFromInteger, 2) {
	const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right_int));
	ASSERT(CheckInteger(left_int));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_mulFromInteger %s * %s\n",
	left_int.ToCString(), right_int.ToCString());
	}
	const Integer& result =
	Integer::Handle(left_int.ArithmeticOp(Token::kMUL, right_int));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_truncDivFromInteger, 2) {
	const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right_int));
	ASSERT(CheckInteger(left_int));
	ASSERT(!right_int.IsZero());
	const Integer& result =
	Integer::Handle(left_int.ArithmeticOp(Token::kTRUNCDIV, right_int));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_moduloFromInteger, 2) {
	const Integer& right_int = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left_int, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right_int));
	ASSERT(CheckInteger(right_int));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_moduloFromInteger %s mod %s\n",
	left_int.ToCString(), right_int.ToCString());
	}
	if (right_int.IsZero()) {
	// Should have been caught before calling into runtime.
	UNIMPLEMENTED();
	}
	const Integer& result =
	Integer::Handle(left_int.ArithmeticOp(Token::kMOD, right_int));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Integer_greaterThanFromInteger, 2) {
	const Integer& right = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, left, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(right));
	ASSERT(CheckInteger(left));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_greaterThanFromInteger %s > %s\n",
	left.ToCString(), right.ToCString());
	}
	return Bool::Get(left.CompareWith(right) == 1).raw();
	}


	DEFINE_NATIVE_ENTRY(Integer_equalToInteger, 2) {
	const Integer& left = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, right, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(left));
	ASSERT(CheckInteger(right));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Integer_equalToInteger %s == %s\n",
	left.ToCString(), right.ToCString());
	}
	return Bool::Get(left.CompareWith(right) == 0).raw();
	}


	static RawInteger* ParseInteger(const String& value) {
	// Used by both Integer_parse and Integer_fromEnvironment.
	if (value.IsOneByteString()) {
	// Quick conversion for unpadded integers in strings.
	const intptr_t len = value.Length();
	if (len > 0) {
	const char* cstr = value.ToCString();
	ASSERT(cstr != NULL);
	char* p_end = NULL;
	const int64_t int_value = strtoll(cstr, &p_end, 10);
	if (p_end == (cstr + len)) {
	if ((int_value != LLONG_MIN) && (int_value != LLONG_MAX)) {
	return Integer::New(int_value);
	}
	}
	}
	}

	Scanner scanner(value, Symbols::Empty());
	const Scanner::GrowableTokenStream& tokens = scanner.GetStream();
	const String* int_string;
	bool is_positive;
	if (Scanner::IsValidLiteral(tokens,
	Token::kINTEGER,
	&is_positive,
	&int_string)) {
	if (is_positive) {
	return Integer::New(*int_string);
	}
	String& temp = String::Handle();
	temp = String::Concat(Symbols::Dash(), *int_string);
	return Integer::New(temp);
	}

	return Integer::null();
	}


	DEFINE_NATIVE_ENTRY(Integer_parse, 1) {
	GET_NON_NULL_NATIVE_ARGUMENT(String, value, arguments->NativeArgAt(0));
	return ParseInteger(value);
	}


	DEFINE_NATIVE_ENTRY(Integer_fromEnvironment, 3) {
	GET_NON_NULL_NATIVE_ARGUMENT(String, name, arguments->NativeArgAt(1));
	GET_NATIVE_ARGUMENT(Integer, default_value, arguments->NativeArgAt(2));
	// Call the embedder to supply us with the environment.
	const String& env_value =
	String::Handle(Api::CallEnvironmentCallback(isolate, name));
	if (!env_value.IsNull()) {
	const Integer& result = Integer::Handle(ParseInteger(env_value));
	if (!result.IsNull()) {
	if (result.IsSmi()) {
	return result.raw();
	}
	return result.CheckAndCanonicalize(NULL);
	}
	}
	return default_value.raw();
	}


	// Passing true for 'silent' prevents throwing JavascriptIntegerOverflow.
	static RawInteger* ShiftOperationHelper(Token::Kind kind,
	const Integer& value,
	const Smi& amount,
	const bool silent = false) {
	if (amount.Value() < 0) {
	Exceptions::ThrowArgumentError(amount);
	}
	if (value.IsSmi()) {
	const Smi& smi_value = Smi::Cast(value);
	return smi_value.ShiftOp(kind, amount, silent);
	}
	if (value.IsMint()) {
	const int64_t mint_value = value.AsInt64Value();
	const int count = Utils::HighestBit(mint_value);
	intptr_t shift_count = amount.Value();
	if (kind == Token::kSHR) {
	shift_count = -shift_count;
	}
	if ((count + shift_count) < Mint::kBits) {
	switch (kind) {
	case Token::kSHL:
	return Integer::New(mint_value << shift_count, Heap::kNew, silent);
	case Token::kSHR:
	return Integer::New(mint_value >> -shift_count, Heap::kNew, silent);
	default:
	UNIMPLEMENTED();
	}
	} else {
	// Overflow in shift, use Bigints
	return Integer::null();
	}
	} else {
	ASSERT(value.IsBigint());
	}
	return Integer::null();
	}


	DEFINE_NATIVE_ENTRY(Integer_leftShiftWithMask32, 3) {
	const Integer& value = Integer::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, shift_count, arguments->NativeArgAt(1));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(2));
	ASSERT(CheckInteger(value));
	ASSERT(CheckInteger(shift_count));
	ASSERT(CheckInteger(mask));
	if (!shift_count.IsSmi()) {
	// Shift count is too large..
	const Instance& exception =
	Instance::Handle(isolate->object_store()->out_of_memory());
	Exceptions::Throw(isolate, exception);
	}
	const Smi& smi_shift_count = Smi::Cast(shift_count);
	const Integer& shift_result = Integer::Handle(
	ShiftOperationHelper(Token::kSHL, value, smi_shift_count, true));
	const Integer& result =
	Integer::Handle(shift_result.BitOp(Token::kBIT_AND, mask));
	return result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Smi_shrFromInt, 2) {
	const Smi& amount = Smi::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, value, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(amount));
	ASSERT(CheckInteger(value));
	const Integer& result = Integer::Handle(
	ShiftOperationHelper(Token::kSHR, value, amount));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}



	DEFINE_NATIVE_ENTRY(Smi_shlFromInt, 2) {
	const Smi& amount = Smi::CheckedHandle(arguments->NativeArgAt(0));
	GET_NON_NULL_NATIVE_ARGUMENT(Integer, value, arguments->NativeArgAt(1));
	ASSERT(CheckInteger(amount));
	ASSERT(CheckInteger(value));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Smi_shlFromInt: %s << %s\n",
	value.ToCString(), amount.ToCString());
	}
	const Integer& result = Integer::Handle(
	ShiftOperationHelper(Token::kSHL, value, amount));
	// A null result indicates that a bigint operation is required.
	return result.IsNull() ? result.raw() : result.AsValidInteger();
	}


	DEFINE_NATIVE_ENTRY(Smi_bitNegate, 1) {
	const Smi& operand = Smi::CheckedHandle(arguments->NativeArgAt(0));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Smi_bitNegate: %s\n", operand.ToCString());
	}
	intptr_t result = ~operand.Value();
	ASSERT(Smi::IsValid(result));
	return Smi::New(result);
	}


	DEFINE_NATIVE_ENTRY(Smi_bitLength, 1) {
	const Smi& operand = Smi::CheckedHandle(arguments->NativeArgAt(0));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Smi_bitLength: %s\n", operand.ToCString());
	}
	int64_t value = operand.AsInt64Value();
	intptr_t result = Utils::BitLength(value);
	ASSERT(Smi::IsValid(result));
	return Smi::New(result);
	}


	// Mint natives.

	DEFINE_NATIVE_ENTRY(Mint_bitNegate, 1) {
	const Mint& operand = Mint::CheckedHandle(arguments->NativeArgAt(0));
	ASSERT(CheckInteger(operand));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Mint_bitNegate: %s\n", operand.ToCString());
	}
	int64_t result = ~operand.value();
	return Integer::New(result);
	}


	DEFINE_NATIVE_ENTRY(Mint_bitLength, 1) {
	const Mint& operand = Mint::CheckedHandle(arguments->NativeArgAt(0));
	ASSERT(CheckInteger(operand));
	if (FLAG_trace_intrinsified_natives) {
	OS::Print("Mint_bitLength: %s\n", operand.ToCString());
	}
	int64_t value = operand.AsInt64Value();
	intptr_t result = Utils::BitLength(value);
	ASSERT(Smi::IsValid(result));
	return Smi::New(result);
	}


	DEFINE_NATIVE_ENTRY(Mint_shlFromInt, 2) {
	// Use the preallocated out of memory exception to avoid calling
	// into dart code or allocating any code.
	const Instance& exception =
	Instance::Handle(isolate->object_store()->out_of_memory());
	Exceptions::Throw(isolate, exception);
	UNREACHABLE();
	return 0;
	}


	// Bigint natives.

	DEFINE_NATIVE_ENTRY(Bigint_getNeg, 1) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	return bigint.neg();
	}


	DEFINE_NATIVE_ENTRY(Bigint_setNeg, 2) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	const Bool& neg = Bool::CheckedHandle(arguments->NativeArgAt(1));
	bigint.set_neg(neg);
	return Object::null();
	}


	DEFINE_NATIVE_ENTRY(Bigint_getUsed, 1) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	return bigint.used();
	}


	DEFINE_NATIVE_ENTRY(Bigint_setUsed, 2) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	const Smi& used = Smi::CheckedHandle(arguments->NativeArgAt(1));
	bigint.set_used(used);
	return Object::null();
	}


	DEFINE_NATIVE_ENTRY(Bigint_getDigits, 1) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	return bigint.digits();
	}


	DEFINE_NATIVE_ENTRY(Bigint_setDigits, 2) {
	const Bigint& bigint = Bigint::CheckedHandle(arguments->NativeArgAt(0));
	const TypedData& digits = TypedData::CheckedHandle(arguments->NativeArgAt(1));
	bigint.set_digits(digits);
	return Object::null();
	}


	DEFINE_NATIVE_ENTRY(Bigint_allocate, 1) {
	// Argument is null type arguments, since class Bigint is not parameterized.
	return Bigint::New();
	}

	} // namespace dart