src/s390/code-stubs-s390.h - platform/external/v8 - Git at Google

 // Copyright 2014 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_S390_CODE_STUBS_S390_H_
 #define V8_S390_CODE_STUBS_S390_H_

 #include "src/s390/frames-s390.h"

 namespace v8 {
 namespace internal {

 void ArrayNativeCode(MacroAssembler* masm, Label* call_generic_code);

 class StringHelper : public AllStatic {
  public:
   // Generate code for copying a large number of characters. This function
   // is allowed to spend extra time setting up conditions to make copying
   // faster. Copying of overlapping regions is not supported.
   // Dest register ends at the position after the last character written.
   static void GenerateCopyCharacters(MacroAssembler* masm, Register dest,
                                      Register src, Register count,
                                      Register scratch,
                                      String::Encoding encoding);

   // Compares two flat one-byte strings and returns result in r0.
   static void GenerateCompareFlatOneByteStrings(MacroAssembler* masm,
                                                 Register left, Register right,
                                                 Register scratch1,
                                                 Register scratch2,
                                                 Register scratch3);

   // Compares two flat one-byte strings for equality and returns result in r0.
   static void GenerateFlatOneByteStringEquals(MacroAssembler* masm,
                                               Register left, Register right,
                                               Register scratch1,
                                               Register scratch2);

  private:
   static void GenerateOneByteCharsCompareLoop(MacroAssembler* masm,
                                               Register left, Register right,
                                               Register length,
                                               Register scratch1,
                                               Label* chars_not_equal);

   DISALLOW_IMPLICIT_CONSTRUCTORS(StringHelper);
 };

 class StoreRegistersStateStub : public PlatformCodeStub {
  public:
   explicit StoreRegistersStateStub(Isolate* isolate)
       : PlatformCodeStub(isolate) {}

   static void GenerateAheadOfTime(Isolate* isolate);

  private:
   DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
   DEFINE_PLATFORM_CODE_STUB(StoreRegistersState, PlatformCodeStub);
 };

 class RestoreRegistersStateStub : public PlatformCodeStub {
  public:
   explicit RestoreRegistersStateStub(Isolate* isolate)
       : PlatformCodeStub(isolate) {}

   static void GenerateAheadOfTime(Isolate* isolate);

  private:
   DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
   DEFINE_PLATFORM_CODE_STUB(RestoreRegistersState, PlatformCodeStub);
 };

 class RecordWriteStub : public PlatformCodeStub {
  public:
   RecordWriteStub(Isolate* isolate, Register object, Register value,
                   Register address, RememberedSetAction remembered_set_action,
                   SaveFPRegsMode fp_mode)
       : PlatformCodeStub(isolate),
         regs_(object,   // An input reg.
               address,  // An input reg.
               value) {  // One scratch reg.
     minor_key_ = ObjectBits::encode(object.code()) |
                  ValueBits::encode(value.code()) |
                  AddressBits::encode(address.code()) |
                  RememberedSetActionBits::encode(remembered_set_action) |
                  SaveFPRegsModeBits::encode(fp_mode);
   }

   RecordWriteStub(uint32_t key, Isolate* isolate)
       : PlatformCodeStub(key, isolate), regs_(object(), address(), value()) {}

   enum Mode { STORE_BUFFER_ONLY, INCREMENTAL, INCREMENTAL_COMPACTION };

   bool SometimesSetsUpAFrame() override { return false; }

   // Patch an always taken branch into a NOP branch
   static void PatchBranchCondMask(MacroAssembler* masm, int pos, Condition c) {
     int32_t instrLen = masm->instr_length_at(pos);
     DCHECK(instrLen == 4 || instrLen == 6);

     if (instrLen == 4) {
       // BRC - Branch Mask @ Bits 23-20
       FourByteInstr updatedMask = static_cast<FourByteInstr>(c) << 20;
       masm->instr_at_put<FourByteInstr>(
           pos, (masm->instr_at(pos) & ~kFourByteBrCondMask) | updatedMask);
     } else {
       // BRCL - Branch Mask @ Bits 39-36
       SixByteInstr updatedMask = static_cast<SixByteInstr>(c) << 36;
       masm->instr_at_put<SixByteInstr>(
           pos, (masm->instr_at(pos) & ~kSixByteBrCondMask) | updatedMask);
     }
   }

   static bool isBranchNop(SixByteInstr instr, int instrLength) {
     if ((4 == instrLength && 0 == (instr & kFourByteBrCondMask)) ||
         // BRC - Check for 0x0 mask condition.
         (6 == instrLength && 0 == (instr & kSixByteBrCondMask))) {
       // BRCL - Check for 0x0 mask condition
       return true;
     }
     return false;
   }

   static Mode GetMode(Code* stub) {
     int32_t first_instr_length =
         Instruction::InstructionLength(stub->instruction_start());
     int32_t second_instr_length = Instruction::InstructionLength(
         stub->instruction_start() + first_instr_length);

     uint64_t first_instr = Assembler::instr_at(stub->instruction_start());
     uint64_t second_instr =
         Assembler::instr_at(stub->instruction_start() + first_instr_length);

     DCHECK(first_instr_length == 4 || first_instr_length == 6);
     DCHECK(second_instr_length == 4 || second_instr_length == 6);

     bool isFirstInstrNOP = isBranchNop(first_instr, first_instr_length);
     bool isSecondInstrNOP = isBranchNop(second_instr, second_instr_length);

     // STORE_BUFFER_ONLY has NOP on both branches
     if (isSecondInstrNOP && isFirstInstrNOP) return STORE_BUFFER_ONLY;
     // INCREMENTAL_COMPACTION has NOP on second branch.
     else if (isFirstInstrNOP && !isSecondInstrNOP)
       return INCREMENTAL_COMPACTION;
     // INCREMENTAL has NOP on first branch.
     else if (!isFirstInstrNOP && isSecondInstrNOP)
       return INCREMENTAL;

     DCHECK(false);
     return STORE_BUFFER_ONLY;
   }

   static void Patch(Code* stub, Mode mode) {
     MacroAssembler masm(stub->GetIsolate(), stub->instruction_start(),
                         stub->instruction_size(), CodeObjectRequired::kNo);

     // Get instruction lengths of two branches
     int32_t first_instr_length = masm.instr_length_at(0);
     int32_t second_instr_length = masm.instr_length_at(first_instr_length);

     switch (mode) {
       case STORE_BUFFER_ONLY:
         DCHECK(GetMode(stub) == INCREMENTAL ||
                GetMode(stub) == INCREMENTAL_COMPACTION);

         PatchBranchCondMask(&masm, 0, CC_NOP);
         PatchBranchCondMask(&masm, first_instr_length, CC_NOP);
         break;
       case INCREMENTAL:
         DCHECK(GetMode(stub) == STORE_BUFFER_ONLY);
         PatchBranchCondMask(&masm, 0, CC_ALWAYS);
         break;
       case INCREMENTAL_COMPACTION:
         DCHECK(GetMode(stub) == STORE_BUFFER_ONLY);
         PatchBranchCondMask(&masm, first_instr_length, CC_ALWAYS);
         break;
     }
     DCHECK(GetMode(stub) == mode);
     Assembler::FlushICache(stub->GetIsolate(), stub->instruction_start(),
                            first_instr_length + second_instr_length);
   }

   DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();

  private:
   // This is a helper class for freeing up 3 scratch registers.  The input is
   // two registers that must be preserved and one scratch register provided by
   // the caller.
   class RegisterAllocation {
    public:
     RegisterAllocation(Register object, Register address, Register scratch0)
         : object_(object), address_(address), scratch0_(scratch0) {
       DCHECK(!AreAliased(scratch0, object, address, no_reg));
       scratch1_ = GetRegisterThatIsNotOneOf(object_, address_, scratch0_);
     }

     void Save(MacroAssembler* masm) {
       DCHECK(!AreAliased(object_, address_, scratch1_, scratch0_));
       // We don't have to save scratch0_ because it was given to us as
       // a scratch register.
       masm->push(scratch1_);
     }

     void Restore(MacroAssembler* masm) { masm->pop(scratch1_); }

     // If we have to call into C then we need to save and restore all caller-
     // saved registers that were not already preserved.  The scratch registers
     // will be restored by other means so we don't bother pushing them here.
     void SaveCallerSaveRegisters(MacroAssembler* masm, SaveFPRegsMode mode) {
       masm->push(r14);
       masm->MultiPush(kJSCallerSaved & ~scratch1_.bit());
       if (mode == kSaveFPRegs) {
         // Save all volatile FP registers except d0.
         masm->MultiPushDoubles(kCallerSavedDoubles & ~d0.bit());
       }
     }

     inline void RestoreCallerSaveRegisters(MacroAssembler* masm,
                                            SaveFPRegsMode mode) {
       if (mode == kSaveFPRegs) {
         // Restore all volatile FP registers except d0.
         masm->MultiPopDoubles(kCallerSavedDoubles & ~d0.bit());
       }
       masm->MultiPop(kJSCallerSaved & ~scratch1_.bit());
       masm->pop(r14);
     }

     inline Register object() { return object_; }
     inline Register address() { return address_; }
     inline Register scratch0() { return scratch0_; }
     inline Register scratch1() { return scratch1_; }

    private:
     Register object_;
     Register address_;
     Register scratch0_;
     Register scratch1_;

     friend class RecordWriteStub;
   };

   enum OnNoNeedToInformIncrementalMarker {
     kReturnOnNoNeedToInformIncrementalMarker,
     kUpdateRememberedSetOnNoNeedToInformIncrementalMarker
   };

   inline Major MajorKey() const final { return RecordWrite; }

   void Generate(MacroAssembler* masm) override;
   void GenerateIncremental(MacroAssembler* masm, Mode mode);
   void CheckNeedsToInformIncrementalMarker(
       MacroAssembler* masm, OnNoNeedToInformIncrementalMarker on_no_need,
       Mode mode);
   void InformIncrementalMarker(MacroAssembler* masm);

   void Activate(Code* code) override {
     code->GetHeap()->incremental_marking()->ActivateGeneratedStub(code);
   }

   Register object() const {
     return Register::from_code(ObjectBits::decode(minor_key_));
   }

   Register value() const {
     return Register::from_code(ValueBits::decode(minor_key_));
   }

   Register address() const {
     return Register::from_code(AddressBits::decode(minor_key_));
   }

   RememberedSetAction remembered_set_action() const {
     return RememberedSetActionBits::decode(minor_key_);
   }

   SaveFPRegsMode save_fp_regs_mode() const {
     return SaveFPRegsModeBits::decode(minor_key_);
   }

   class ObjectBits : public BitField<int, 0, 4> {};
   class ValueBits : public BitField<int, 4, 4> {};
   class AddressBits : public BitField<int, 8, 4> {};
   class RememberedSetActionBits : public BitField<RememberedSetAction, 15, 1> {
   };
   class SaveFPRegsModeBits : public BitField<SaveFPRegsMode, 16, 1> {};

   Label slow_;
   RegisterAllocation regs_;

   DISALLOW_COPY_AND_ASSIGN(RecordWriteStub);
 };

 // Trampoline stub to call into native code. To call safely into native code
 // in the presence of compacting GC (which can move code objects) we need to
 // keep the code which called into native pinned in the memory. Currently the
 // simplest approach is to generate such stub early enough so it can never be
 // moved by GC
 class DirectCEntryStub : public PlatformCodeStub {
  public:
   explicit DirectCEntryStub(Isolate* isolate) : PlatformCodeStub(isolate) {}
   void GenerateCall(MacroAssembler* masm, Register target);

  private:
   bool NeedsImmovableCode() override { return true; }

   DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
   DEFINE_PLATFORM_CODE_STUB(DirectCEntry, PlatformCodeStub);
 };

 class NameDictionaryLookupStub : public PlatformCodeStub {
  public:
   enum LookupMode { POSITIVE_LOOKUP, NEGATIVE_LOOKUP };

   NameDictionaryLookupStub(Isolate* isolate, LookupMode mode)
       : PlatformCodeStub(isolate) {
     minor_key_ = LookupModeBits::encode(mode);
   }

   static void GenerateNegativeLookup(MacroAssembler* masm, Label* miss,
                                      Label* done, Register receiver,
                                      Register properties, Handle<Name> name,
                                      Register scratch0);

   static void GeneratePositiveLookup(MacroAssembler* masm, Label* miss,
                                      Label* done, Register elements,
                                      Register name, Register r0, Register r1);

   bool SometimesSetsUpAFrame() override { return false; }

  private:
   static const int kInlinedProbes = 4;
   static const int kTotalProbes = 20;

   static const int kCapacityOffset =
       NameDictionary::kHeaderSize +
       NameDictionary::kCapacityIndex * kPointerSize;

   static const int kElementsStartOffset =
       NameDictionary::kHeaderSize +
       NameDictionary::kElementsStartIndex * kPointerSize;

   LookupMode mode() const { return LookupModeBits::decode(minor_key_); }

   class LookupModeBits : public BitField<LookupMode, 0, 1> {};

   DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
   DEFINE_PLATFORM_CODE_STUB(NameDictionaryLookup, PlatformCodeStub);
 };

 class FloatingPointHelper : public AllStatic {
  public:
   enum Destination { kFPRegisters, kCoreRegisters };

   // Loads smis from r0 and r1 (right and left in binary operations) into
   // floating point registers. Depending on the destination the values ends up
   // either d7 and d6 or in r2/r3 and r0/r1 respectively. If the destination is
   // floating point registers VFP3 must be supported. If core registers are
   // requested when VFP3 is supported d6 and d7 will be scratched.
   static void LoadSmis(MacroAssembler* masm, Register scratch1,
                        Register scratch2);

   // Loads objects from r0 and r1 (right and left in binary operations) into
   // floating point registers. Depending on the destination the values ends up
   // either d7 and d6 or in r2/r3 and r0/r1 respectively. If the destination is
   // floating point registers VFP3 must be supported. If core registers are
   // requested when VFP3 is supported d6 and d7 will still be scratched. If
   // either r0 or r1 is not a number (not smi and not heap number object) the
   // not_number label is jumped to with r0 and r1 intact.
   static void LoadOperands(MacroAssembler* masm, Register heap_number_map,
                            Register scratch1, Register scratch2,
                            Label* not_number);

   // Convert the smi or heap number in object to an int32 using the rules
   // for ToInt32 as described in ECMAScript 9.5.: the value is truncated
   // and brought into the range -2^31 .. +2^31 - 1.
   static void ConvertNumberToInt32(MacroAssembler* masm, Register object,
                                    Register dst, Register heap_number_map,
                                    Register scratch1, Register scratch2,
                                    Register scratch3,
                                    DoubleRegister double_scratch,
                                    Label* not_int32);

   // Converts the integer (untagged smi) in |src| to a double, storing
   // the result to |double_dst|
   static void ConvertIntToDouble(MacroAssembler* masm, Register src,
                                  DoubleRegister double_dst);

   // Converts the unsigned integer (untagged smi) in |src| to
   // a double, storing the result to |double_dst|
   static void ConvertUnsignedIntToDouble(MacroAssembler* masm, Register src,
                                          DoubleRegister double_dst);

   // Converts the integer (untagged smi) in |src| to
   // a float, storing the result in |dst|
   static void ConvertIntToFloat(MacroAssembler* masm, const DoubleRegister dst,
                                 const Register src);

   // Load the number from object into double_dst in the double format.
   // Control will jump to not_int32 if the value cannot be exactly represented
   // by a 32-bit integer.
   // Floating point value in the 32-bit integer range that are not exact integer
   // won't be loaded.
   static void LoadNumberAsInt32Double(MacroAssembler* masm, Register object,
                                       DoubleRegister double_dst,
                                       DoubleRegister double_scratch,
                                       Register heap_number_map,
                                       Register scratch1, Register scratch2,
                                       Label* not_int32);

   // Loads the number from object into dst as a 32-bit integer.
   // Control will jump to not_int32 if the object cannot be exactly represented
   // by a 32-bit integer.
   // Floating point value in the 32-bit integer range that are not exact integer
   // won't be converted.
   // scratch3 is not used when VFP3 is supported.
   static void LoadNumberAsInt32(MacroAssembler* masm, Register object,
                                 Register dst, Register heap_number_map,
                                 Register scratch1, Register scratch2,
                                 Register scratch3,
                                 DoubleRegister double_scratch0,
                                 DoubleRegister double_scratch1,
                                 Label* not_int32);

   // Generate non VFP3 code to check if a double can be exactly represented by a
   // 32-bit integer. This does not check for 0 or -0, which need
   // to be checked for separately.
   // Control jumps to not_int32 if the value is not a 32-bit integer, and falls
   // through otherwise.
   // src1 and src2 will be cloberred.
   //
   // Expected input:
   // - src1: higher (exponent) part of the double value.
   // - src2: lower (mantissa) part of the double value.
   // Output status:
   // - dst: 32 higher bits of the mantissa. (mantissa[51:20])
   // - src2: contains 1.
   // - other registers are clobbered.
   static void DoubleIs32BitInteger(MacroAssembler* masm, Register src1,
                                    Register src2, Register dst,
                                    Register scratch, Label* not_int32);

   // Generates code to call a C function to do a double operation using core
   // registers. (Used when VFP3 is not supported.)
   // This code never falls through, but returns with a heap number containing
   // the result in r0.
   // Register heapnumber_result must be a heap number in which the
   // result of the operation will be stored.
   // Requires the following layout on entry:
   // r0: Left value (least significant part of mantissa).
   // r1: Left value (sign, exponent, top of mantissa).
   // r2: Right value (least significant part of mantissa).
   // r3: Right value (sign, exponent, top of mantissa).
   static void CallCCodeForDoubleOperation(MacroAssembler* masm, Token::Value op,
                                           Register heap_number_result,
                                           Register scratch);

  private:
   static void LoadNumber(MacroAssembler* masm, Register object,
                          DoubleRegister dst, Register heap_number_map,
                          Register scratch1, Register scratch2,
                          Label* not_number);
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_S390_CODE_STUBS_S390_H_
	// Copyright 2014 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_S390_CODE_STUBS_S390_H_
	#define V8_S390_CODE_STUBS_S390_H_

	#include "src/s390/frames-s390.h"

	namespace v8 {
	namespace internal {

	void ArrayNativeCode(MacroAssembler* masm, Label* call_generic_code);

	class StringHelper : public AllStatic {
	public:
	// Generate code for copying a large number of characters. This function
	// is allowed to spend extra time setting up conditions to make copying
	// faster. Copying of overlapping regions is not supported.
	// Dest register ends at the position after the last character written.
	static void GenerateCopyCharacters(MacroAssembler* masm, Register dest,
	Register src, Register count,
	Register scratch,
	String::Encoding encoding);

	// Compares two flat one-byte strings and returns result in r0.
	static void GenerateCompareFlatOneByteStrings(MacroAssembler* masm,
	Register left, Register right,
	Register scratch1,
	Register scratch2,
	Register scratch3);

	// Compares two flat one-byte strings for equality and returns result in r0.
	static void GenerateFlatOneByteStringEquals(MacroAssembler* masm,
	Register left, Register right,
	Register scratch1,
	Register scratch2);

	private:
	static void GenerateOneByteCharsCompareLoop(MacroAssembler* masm,
	Register left, Register right,
	Register length,
	Register scratch1,
	Label* chars_not_equal);

	DISALLOW_IMPLICIT_CONSTRUCTORS(StringHelper);
	};

	class StoreRegistersStateStub : public PlatformCodeStub {
	public:
	explicit StoreRegistersStateStub(Isolate* isolate)
	: PlatformCodeStub(isolate) {}

	static void GenerateAheadOfTime(Isolate* isolate);

	private:
	DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
	DEFINE_PLATFORM_CODE_STUB(StoreRegistersState, PlatformCodeStub);
	};

	class RestoreRegistersStateStub : public PlatformCodeStub {
	public:
	explicit RestoreRegistersStateStub(Isolate* isolate)
	: PlatformCodeStub(isolate) {}

	static void GenerateAheadOfTime(Isolate* isolate);

	private:
	DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
	DEFINE_PLATFORM_CODE_STUB(RestoreRegistersState, PlatformCodeStub);
	};

	class RecordWriteStub : public PlatformCodeStub {
	public:
	RecordWriteStub(Isolate* isolate, Register object, Register value,
	Register address, RememberedSetAction remembered_set_action,
	SaveFPRegsMode fp_mode)
	: PlatformCodeStub(isolate),
	regs_(object, // An input reg.
	address, // An input reg.
	value) { // One scratch reg.
	minor_key_ = ObjectBits::encode(object.code()) \|
	ValueBits::encode(value.code()) \|
	AddressBits::encode(address.code()) \|
	RememberedSetActionBits::encode(remembered_set_action) \|
	SaveFPRegsModeBits::encode(fp_mode);
	}

	RecordWriteStub(uint32_t key, Isolate* isolate)
	: PlatformCodeStub(key, isolate), regs_(object(), address(), value()) {}

	enum Mode { STORE_BUFFER_ONLY, INCREMENTAL, INCREMENTAL_COMPACTION };

	bool SometimesSetsUpAFrame() override { return false; }

	// Patch an always taken branch into a NOP branch
	static void PatchBranchCondMask(MacroAssembler* masm, int pos, Condition c) {
	int32_t instrLen = masm->instr_length_at(pos);
	DCHECK(instrLen == 4 \|\| instrLen == 6);

	if (instrLen == 4) {
	// BRC - Branch Mask @ Bits 23-20
	FourByteInstr updatedMask = static_cast<FourByteInstr>(c) << 20;
	masm->instr_at_put<FourByteInstr>(
	pos, (masm->instr_at(pos) & ~kFourByteBrCondMask) \| updatedMask);
	} else {
	// BRCL - Branch Mask @ Bits 39-36
	SixByteInstr updatedMask = static_cast<SixByteInstr>(c) << 36;
	masm->instr_at_put<SixByteInstr>(
	pos, (masm->instr_at(pos) & ~kSixByteBrCondMask) \| updatedMask);
	}
	}

	static bool isBranchNop(SixByteInstr instr, int instrLength) {
	if ((4 == instrLength && 0 == (instr & kFourByteBrCondMask)) \|\|
	// BRC - Check for 0x0 mask condition.
	(6 == instrLength && 0 == (instr & kSixByteBrCondMask))) {
	// BRCL - Check for 0x0 mask condition
	return true;
	}
	return false;
	}

	static Mode GetMode(Code* stub) {
	int32_t first_instr_length =
	Instruction::InstructionLength(stub->instruction_start());
	int32_t second_instr_length = Instruction::InstructionLength(
	stub->instruction_start() + first_instr_length);

	uint64_t first_instr = Assembler::instr_at(stub->instruction_start());
	uint64_t second_instr =
	Assembler::instr_at(stub->instruction_start() + first_instr_length);

	DCHECK(first_instr_length == 4 \|\| first_instr_length == 6);
	DCHECK(second_instr_length == 4 \|\| second_instr_length == 6);

	bool isFirstInstrNOP = isBranchNop(first_instr, first_instr_length);
	bool isSecondInstrNOP = isBranchNop(second_instr, second_instr_length);

	// STORE_BUFFER_ONLY has NOP on both branches
	if (isSecondInstrNOP && isFirstInstrNOP) return STORE_BUFFER_ONLY;
	// INCREMENTAL_COMPACTION has NOP on second branch.
	else if (isFirstInstrNOP && !isSecondInstrNOP)
	return INCREMENTAL_COMPACTION;
	// INCREMENTAL has NOP on first branch.
	else if (!isFirstInstrNOP && isSecondInstrNOP)
	return INCREMENTAL;

	DCHECK(false);
	return STORE_BUFFER_ONLY;
	}

	static void Patch(Code* stub, Mode mode) {
	MacroAssembler masm(stub->GetIsolate(), stub->instruction_start(),
	stub->instruction_size(), CodeObjectRequired::kNo);

	// Get instruction lengths of two branches
	int32_t first_instr_length = masm.instr_length_at(0);
	int32_t second_instr_length = masm.instr_length_at(first_instr_length);

	switch (mode) {
	case STORE_BUFFER_ONLY:
	DCHECK(GetMode(stub) == INCREMENTAL \|\|
	GetMode(stub) == INCREMENTAL_COMPACTION);

	PatchBranchCondMask(&masm, 0, CC_NOP);
	PatchBranchCondMask(&masm, first_instr_length, CC_NOP);
	break;
	case INCREMENTAL:
	DCHECK(GetMode(stub) == STORE_BUFFER_ONLY);
	PatchBranchCondMask(&masm, 0, CC_ALWAYS);
	break;
	case INCREMENTAL_COMPACTION:
	DCHECK(GetMode(stub) == STORE_BUFFER_ONLY);
	PatchBranchCondMask(&masm, first_instr_length, CC_ALWAYS);
	break;
	}
	DCHECK(GetMode(stub) == mode);
	Assembler::FlushICache(stub->GetIsolate(), stub->instruction_start(),
	first_instr_length + second_instr_length);
	}

	DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();

	private:
	// This is a helper class for freeing up 3 scratch registers. The input is
	// two registers that must be preserved and one scratch register provided by
	// the caller.
	class RegisterAllocation {
	public:
	RegisterAllocation(Register object, Register address, Register scratch0)
	: object_(object), address_(address), scratch0_(scratch0) {
	DCHECK(!AreAliased(scratch0, object, address, no_reg));
	scratch1_ = GetRegisterThatIsNotOneOf(object_, address_, scratch0_);
	}

	void Save(MacroAssembler* masm) {
	DCHECK(!AreAliased(object_, address_, scratch1_, scratch0_));
	// We don't have to save scratch0_ because it was given to us as
	// a scratch register.
	masm->push(scratch1_);
	}

	void Restore(MacroAssembler* masm) { masm->pop(scratch1_); }

	// If we have to call into C then we need to save and restore all caller-
	// saved registers that were not already preserved. The scratch registers
	// will be restored by other means so we don't bother pushing them here.
	void SaveCallerSaveRegisters(MacroAssembler* masm, SaveFPRegsMode mode) {
	masm->push(r14);
	masm->MultiPush(kJSCallerSaved & ~scratch1_.bit());
	if (mode == kSaveFPRegs) {
	// Save all volatile FP registers except d0.
	masm->MultiPushDoubles(kCallerSavedDoubles & ~d0.bit());
	}
	}

	inline void RestoreCallerSaveRegisters(MacroAssembler* masm,
	SaveFPRegsMode mode) {
	if (mode == kSaveFPRegs) {
	// Restore all volatile FP registers except d0.
	masm->MultiPopDoubles(kCallerSavedDoubles & ~d0.bit());
	}
	masm->MultiPop(kJSCallerSaved & ~scratch1_.bit());
	masm->pop(r14);
	}

	inline Register object() { return object_; }
	inline Register address() { return address_; }
	inline Register scratch0() { return scratch0_; }
	inline Register scratch1() { return scratch1_; }

	private:
	Register object_;
	Register address_;
	Register scratch0_;
	Register scratch1_;

	friend class RecordWriteStub;
	};

	enum OnNoNeedToInformIncrementalMarker {
	kReturnOnNoNeedToInformIncrementalMarker,
	kUpdateRememberedSetOnNoNeedToInformIncrementalMarker
	};

	inline Major MajorKey() const final { return RecordWrite; }

	void Generate(MacroAssembler* masm) override;
	void GenerateIncremental(MacroAssembler* masm, Mode mode);
	void CheckNeedsToInformIncrementalMarker(
	MacroAssembler* masm, OnNoNeedToInformIncrementalMarker on_no_need,
	Mode mode);
	void InformIncrementalMarker(MacroAssembler* masm);

	void Activate(Code* code) override {
	code->GetHeap()->incremental_marking()->ActivateGeneratedStub(code);
	}

	Register object() const {
	return Register::from_code(ObjectBits::decode(minor_key_));
	}

	Register value() const {
	return Register::from_code(ValueBits::decode(minor_key_));
	}

	Register address() const {
	return Register::from_code(AddressBits::decode(minor_key_));
	}

	RememberedSetAction remembered_set_action() const {
	return RememberedSetActionBits::decode(minor_key_);
	}

	SaveFPRegsMode save_fp_regs_mode() const {
	return SaveFPRegsModeBits::decode(minor_key_);
	}

	class ObjectBits : public BitField<int, 0, 4> {};
	class ValueBits : public BitField<int, 4, 4> {};
	class AddressBits : public BitField<int, 8, 4> {};
	class RememberedSetActionBits : public BitField<RememberedSetAction, 15, 1> {
	};
	class SaveFPRegsModeBits : public BitField<SaveFPRegsMode, 16, 1> {};

	Label slow_;
	RegisterAllocation regs_;

	DISALLOW_COPY_AND_ASSIGN(RecordWriteStub);
	};

	// Trampoline stub to call into native code. To call safely into native code
	// in the presence of compacting GC (which can move code objects) we need to
	// keep the code which called into native pinned in the memory. Currently the
	// simplest approach is to generate such stub early enough so it can never be
	// moved by GC
	class DirectCEntryStub : public PlatformCodeStub {
	public:
	explicit DirectCEntryStub(Isolate* isolate) : PlatformCodeStub(isolate) {}
	void GenerateCall(MacroAssembler* masm, Register target);

	private:
	bool NeedsImmovableCode() override { return true; }

	DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
	DEFINE_PLATFORM_CODE_STUB(DirectCEntry, PlatformCodeStub);
	};

	class NameDictionaryLookupStub : public PlatformCodeStub {
	public:
	enum LookupMode { POSITIVE_LOOKUP, NEGATIVE_LOOKUP };

	NameDictionaryLookupStub(Isolate* isolate, LookupMode mode)
	: PlatformCodeStub(isolate) {
	minor_key_ = LookupModeBits::encode(mode);
	}

	static void GenerateNegativeLookup(MacroAssembler* masm, Label* miss,
	Label* done, Register receiver,
	Register properties, Handle<Name> name,
	Register scratch0);

	static void GeneratePositiveLookup(MacroAssembler* masm, Label* miss,
	Label* done, Register elements,
	Register name, Register r0, Register r1);

	bool SometimesSetsUpAFrame() override { return false; }

	private:
	static const int kInlinedProbes = 4;
	static const int kTotalProbes = 20;

	static const int kCapacityOffset =
	NameDictionary::kHeaderSize +
	NameDictionary::kCapacityIndex * kPointerSize;

	static const int kElementsStartOffset =
	NameDictionary::kHeaderSize +
	NameDictionary::kElementsStartIndex * kPointerSize;

	LookupMode mode() const { return LookupModeBits::decode(minor_key_); }

	class LookupModeBits : public BitField<LookupMode, 0, 1> {};

	DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
	DEFINE_PLATFORM_CODE_STUB(NameDictionaryLookup, PlatformCodeStub);
	};

	class FloatingPointHelper : public AllStatic {
	public:
	enum Destination { kFPRegisters, kCoreRegisters };

	// Loads smis from r0 and r1 (right and left in binary operations) into
	// floating point registers. Depending on the destination the values ends up
	// either d7 and d6 or in r2/r3 and r0/r1 respectively. If the destination is
	// floating point registers VFP3 must be supported. If core registers are
	// requested when VFP3 is supported d6 and d7 will be scratched.
	static void LoadSmis(MacroAssembler* masm, Register scratch1,
	Register scratch2);

	// Loads objects from r0 and r1 (right and left in binary operations) into
	// floating point registers. Depending on the destination the values ends up
	// either d7 and d6 or in r2/r3 and r0/r1 respectively. If the destination is
	// floating point registers VFP3 must be supported. If core registers are
	// requested when VFP3 is supported d6 and d7 will still be scratched. If
	// either r0 or r1 is not a number (not smi and not heap number object) the
	// not_number label is jumped to with r0 and r1 intact.
	static void LoadOperands(MacroAssembler* masm, Register heap_number_map,
	Register scratch1, Register scratch2,
	Label* not_number);

	// Convert the smi or heap number in object to an int32 using the rules
	// for ToInt32 as described in ECMAScript 9.5.: the value is truncated
	// and brought into the range -2^31 .. +2^31 - 1.
	static void ConvertNumberToInt32(MacroAssembler* masm, Register object,
	Register dst, Register heap_number_map,
	Register scratch1, Register scratch2,
	Register scratch3,
	DoubleRegister double_scratch,
	Label* not_int32);

	// Converts the integer (untagged smi) in \|src\| to a double, storing
	// the result to \|double_dst\|
	static void ConvertIntToDouble(MacroAssembler* masm, Register src,
	DoubleRegister double_dst);

	// Converts the unsigned integer (untagged smi) in \|src\| to
	// a double, storing the result to \|double_dst\|
	static void ConvertUnsignedIntToDouble(MacroAssembler* masm, Register src,
	DoubleRegister double_dst);

	// Converts the integer (untagged smi) in \|src\| to
	// a float, storing the result in \|dst\|
	static void ConvertIntToFloat(MacroAssembler* masm, const DoubleRegister dst,
	const Register src);

	// Load the number from object into double_dst in the double format.
	// Control will jump to not_int32 if the value cannot be exactly represented
	// by a 32-bit integer.
	// Floating point value in the 32-bit integer range that are not exact integer
	// won't be loaded.
	static void LoadNumberAsInt32Double(MacroAssembler* masm, Register object,
	DoubleRegister double_dst,
	DoubleRegister double_scratch,
	Register heap_number_map,
	Register scratch1, Register scratch2,
	Label* not_int32);

	// Loads the number from object into dst as a 32-bit integer.
	// Control will jump to not_int32 if the object cannot be exactly represented
	// by a 32-bit integer.
	// Floating point value in the 32-bit integer range that are not exact integer
	// won't be converted.
	// scratch3 is not used when VFP3 is supported.
	static void LoadNumberAsInt32(MacroAssembler* masm, Register object,
	Register dst, Register heap_number_map,
	Register scratch1, Register scratch2,
	Register scratch3,
	DoubleRegister double_scratch0,
	DoubleRegister double_scratch1,
	Label* not_int32);

	// Generate non VFP3 code to check if a double can be exactly represented by a
	// 32-bit integer. This does not check for 0 or -0, which need
	// to be checked for separately.
	// Control jumps to not_int32 if the value is not a 32-bit integer, and falls
	// through otherwise.
	// src1 and src2 will be cloberred.
	//
	// Expected input:
	// - src1: higher (exponent) part of the double value.
	// - src2: lower (mantissa) part of the double value.
	// Output status:
	// - dst: 32 higher bits of the mantissa. (mantissa[51:20])
	// - src2: contains 1.
	// - other registers are clobbered.
	static void DoubleIs32BitInteger(MacroAssembler* masm, Register src1,
	Register src2, Register dst,
	Register scratch, Label* not_int32);

	// Generates code to call a C function to do a double operation using core
	// registers. (Used when VFP3 is not supported.)
	// This code never falls through, but returns with a heap number containing
	// the result in r0.
	// Register heapnumber_result must be a heap number in which the
	// result of the operation will be stored.
	// Requires the following layout on entry:
	// r0: Left value (least significant part of mantissa).
	// r1: Left value (sign, exponent, top of mantissa).
	// r2: Right value (least significant part of mantissa).
	// r3: Right value (sign, exponent, top of mantissa).
	static void CallCCodeForDoubleOperation(MacroAssembler* masm, Token::Value op,
	Register heap_number_result,
	Register scratch);

	private:
	static void LoadNumber(MacroAssembler* masm, Register object,
	DoubleRegister dst, Register heap_number_map,
	Register scratch1, Register scratch2,
	Label* not_number);
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_S390_CODE_STUBS_S390_H_