runtime/vm/instructions_arm.cc - sdk - Git at Google

 // Copyright (c) 2013, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/globals.h"  // Needed here to get TARGET_ARCH_ARM.
 #if defined(TARGET_ARCH_ARM)

 #include "vm/instructions.h"
 #include "vm/instructions_arm.h"

 #include "vm/compiler/assembler/assembler.h"
 #include "vm/constants_arm.h"
 #include "vm/cpu.h"
 #include "vm/object.h"
 #include "vm/reverse_pc_lookup_cache.h"

 namespace dart {

 CallPattern::CallPattern(uword pc, const Code& code)
     : object_pool_(ObjectPool::Handle(code.GetObjectPool())),
       end_(pc),
       ic_data_load_end_(0),
       target_code_pool_index_(-1),
       ic_data_(ICData::Handle()) {
   ASSERT(code.ContainsInstructionAt(pc));
   // Last instruction: blx lr.
   ASSERT(*(reinterpret_cast<uword*>(end_) - 1) == 0xe12fff3e);

   Register reg;
   ic_data_load_end_ = InstructionPattern::DecodeLoadWordFromPool(
       end_ - 2 * Instr::kInstrSize, &reg, &target_code_pool_index_);
   ASSERT(reg == CODE_REG);
 }

 NativeCallPattern::NativeCallPattern(uword pc, const Code& code)
     : object_pool_(ObjectPool::Handle(code.GetObjectPool())),
       end_(pc),
       native_function_pool_index_(-1),
       target_code_pool_index_(-1) {
   ASSERT(code.ContainsInstructionAt(pc));
   // Last instruction: blx lr.
   ASSERT(*(reinterpret_cast<uword*>(end_) - 1) == 0xe12fff3e);

   Register reg;
   uword native_function_load_end = InstructionPattern::DecodeLoadWordFromPool(
       end_ - 2 * Instr::kInstrSize, &reg, &target_code_pool_index_);
   ASSERT(reg == CODE_REG);
   InstructionPattern::DecodeLoadWordFromPool(native_function_load_end, &reg,
                                              &native_function_pool_index_);
   ASSERT(reg == R9);
 }

 RawCode* NativeCallPattern::target() const {
   return reinterpret_cast<RawCode*>(
       object_pool_.ObjectAt(target_code_pool_index_));
 }

 void NativeCallPattern::set_target(const Code& new_target) const {
   object_pool_.SetObjectAt(target_code_pool_index_, new_target);
   // No need to flush the instruction cache, since the code is not modified.
 }

 NativeFunction NativeCallPattern::native_function() const {
   return reinterpret_cast<NativeFunction>(
       object_pool_.RawValueAt(native_function_pool_index_));
 }

 void NativeCallPattern::set_native_function(NativeFunction func) const {
   object_pool_.SetRawValueAt(native_function_pool_index_,
                              reinterpret_cast<uword>(func));
 }

 // Decodes a load sequence ending at 'end' (the last instruction of the load
 // sequence is the instruction before the one at end).  Returns a pointer to
 // the first instruction in the sequence.  Returns the register being loaded
 // and the loaded object in the output parameters 'reg' and 'obj'
 // respectively.
 uword InstructionPattern::DecodeLoadObject(uword end,
                                            const ObjectPool& object_pool,
                                            Register* reg,
                                            Object* obj) {
   uword start = 0;
   Instr* instr = Instr::At(end - Instr::kInstrSize);
   if ((instr->InstructionBits() & 0xfff00000) == 0xe5900000) {
     // ldr reg, [reg, #+offset]
     intptr_t index = 0;
     start = DecodeLoadWordFromPool(end, reg, &index);
     *obj = object_pool.ObjectAt(index);
   } else {
     intptr_t value = 0;
     start = DecodeLoadWordImmediate(end, reg, &value);
     *obj = reinterpret_cast<RawObject*>(value);
   }
   return start;
 }

 // Decodes a load sequence ending at 'end' (the last instruction of the load
 // sequence is the instruction before the one at end).  Returns a pointer to
 // the first instruction in the sequence.  Returns the register being loaded
 // and the loaded immediate value in the output parameters 'reg' and 'value'
 // respectively.
 uword InstructionPattern::DecodeLoadWordImmediate(uword end,
                                                   Register* reg,
                                                   intptr_t* value) {
   uword start = end - Instr::kInstrSize;
   int32_t instr = Instr::At(start)->InstructionBits();
   intptr_t imm = 0;
   const ARMVersion version = TargetCPUFeatures::arm_version();
   if ((version == ARMv5TE) || (version == ARMv6)) {
     ASSERT((instr & 0xfff00000) == 0xe3800000);  // orr rd, rd, byte0
     imm |= (instr & 0x000000ff);

     start -= Instr::kInstrSize;
     instr = Instr::At(start)->InstructionBits();
     ASSERT((instr & 0xfff00000) == 0xe3800c00);  // orr rd, rd, (byte1 rot 12)
     imm |= (instr & 0x000000ff);

     start -= Instr::kInstrSize;
     instr = Instr::At(start)->InstructionBits();
     ASSERT((instr & 0xfff00f00) == 0xe3800800);  // orr rd, rd, (byte2 rot 8)
     imm |= (instr & 0x000000ff);

     start -= Instr::kInstrSize;
     instr = Instr::At(start)->InstructionBits();
     ASSERT((instr & 0xffff0f00) == 0xe3a00400);  // mov rd, (byte3 rot 4)
     imm |= (instr & 0x000000ff);

     *reg = static_cast<Register>((instr & 0x0000f000) >> 12);
     *value = imm;
   } else {
     ASSERT(version == ARMv7);
     if ((instr & 0xfff00000) == 0xe3400000) {  // movt reg, #imm_hi
       imm |= (instr & 0xf0000) << 12;
       imm |= (instr & 0xfff) << 16;
       start -= Instr::kInstrSize;
       instr = Instr::At(start)->InstructionBits();
     }
     ASSERT((instr & 0xfff00000) == 0xe3000000);  // movw reg, #imm_lo
     imm |= (instr & 0xf0000) >> 4;
     imm |= instr & 0xfff;
     *reg = static_cast<Register>((instr & 0xf000) >> 12);
     *value = imm;
   }
   return start;
 }

 static bool IsLoadWithOffset(int32_t instr,
                              Register base,
                              intptr_t* offset,
                              Register* dst) {
   if ((instr & 0xffff0000) == (0xe5900000 | (base << 16))) {
     // ldr reg, [base, #+offset]
     *offset = instr & 0xfff;
     *dst = static_cast<Register>((instr & 0xf000) >> 12);
     return true;
   }
   return false;
 }

 // Decodes a load sequence ending at 'end' (the last instruction of the load
 // sequence is the instruction before the one at end).  Returns a pointer to
 // the first instruction in the sequence.  Returns the register being loaded
 // and the index in the pool being read from in the output parameters 'reg'
 // and 'index' respectively.
 uword InstructionPattern::DecodeLoadWordFromPool(uword end,
                                                  Register* reg,
                                                  intptr_t* index) {
   uword start = end - Instr::kInstrSize;
   int32_t instr = Instr::At(start)->InstructionBits();
   intptr_t offset = 0;
   if (IsLoadWithOffset(instr, PP, &offset, reg)) {
     // ldr reg, [PP, #+offset]
   } else {
     ASSERT((instr & 0xfff00000) == 0xe5900000);  // ldr reg, [reg, #+offset]
     offset = instr & 0xfff;
     start -= Instr::kInstrSize;
     instr = Instr::At(start)->InstructionBits();
     if ((instr & 0xffff0000) == (0xe2850000 | (PP << 16))) {
       // add reg, pp, operand
       const intptr_t rot = (instr & 0xf00) >> 7;
       const intptr_t imm8 = instr & 0xff;
       offset += (imm8 >> rot) | (imm8 << (32 - rot));
       *reg = static_cast<Register>((instr & 0xf000) >> 12);
     } else {
       ASSERT((instr & 0xffff0000) == (0xe0800000 | (PP << 16)));
       // add reg, pp, reg
       end = DecodeLoadWordImmediate(end, reg, &offset);
     }
   }
   *index = ObjectPool::IndexFromOffset(offset);
   return start;
 }

 bool DecodeLoadObjectFromPoolOrThread(uword pc, const Code& code, Object* obj) {
   ASSERT(code.ContainsInstructionAt(pc));

   int32_t instr = Instr::At(pc)->InstructionBits();
   intptr_t offset;
   Register dst;
   if (IsLoadWithOffset(instr, PP, &offset, &dst)) {
     intptr_t index = ObjectPool::IndexFromOffset(offset);
     const ObjectPool& pool = ObjectPool::Handle(code.object_pool());
     if (!pool.IsNull()) {
       if (pool.TypeAt(index) == ObjectPool::kTaggedObject) {
         *obj = pool.ObjectAt(index);
         return true;
       }
     }
   } else if (IsLoadWithOffset(instr, THR, &offset, &dst)) {
     return Thread::ObjectAtOffset(offset, obj);
   }
   // TODO(rmacnak): Sequence for loads beyond 12 bits.

   return false;
 }

 RawICData* CallPattern::IcData() {
   if (ic_data_.IsNull()) {
     Register reg;
     InstructionPattern::DecodeLoadObject(ic_data_load_end_, object_pool_, &reg,
                                          &ic_data_);
     ASSERT(reg == R9);
   }
   return ic_data_.raw();
 }

 RawCode* CallPattern::TargetCode() const {
   return reinterpret_cast<RawCode*>(
       object_pool_.ObjectAt(target_code_pool_index_));
 }

 void CallPattern::SetTargetCode(const Code& target_code) const {
   object_pool_.SetObjectAt(target_code_pool_index_, target_code);
 }

 SwitchableCallPatternBase::SwitchableCallPatternBase(const Code& code)
     : object_pool_(ObjectPool::Handle(code.GetObjectPool())),
       data_pool_index_(-1),
       target_pool_index_(-1) {}

 RawObject* SwitchableCallPatternBase::data() const {
   return object_pool_.ObjectAt(data_pool_index_);
 }

 void SwitchableCallPatternBase::SetData(const Object& data) const {
   ASSERT(!Object::Handle(object_pool_.ObjectAt(data_pool_index_)).IsCode());
   object_pool_.SetObjectAt(data_pool_index_, data);
 }

 SwitchableCallPattern::SwitchableCallPattern(uword pc, const Code& code)
     : SwitchableCallPatternBase(code) {
   ASSERT(code.ContainsInstructionAt(pc));
   // Last instruction: blx lr.
   ASSERT(*(reinterpret_cast<uword*>(pc) - 1) == 0xe12fff3e);

   Register reg;
   uword data_load_end = InstructionPattern::DecodeLoadWordFromPool(
       pc - Instr::kInstrSize, &reg, &data_pool_index_);
   ASSERT(reg == R9);
   InstructionPattern::DecodeLoadWordFromPool(data_load_end - Instr::kInstrSize,
                                              &reg, &target_pool_index_);
   ASSERT(reg == CODE_REG);
 }

 RawCode* SwitchableCallPattern::target() const {
   return reinterpret_cast<RawCode*>(object_pool_.ObjectAt(target_pool_index_));
 }
 void SwitchableCallPattern::SetTarget(const Code& target) const {
   ASSERT(Object::Handle(object_pool_.ObjectAt(target_pool_index_)).IsCode());
   object_pool_.SetObjectAt(target_pool_index_, target);
 }

 BareSwitchableCallPattern::BareSwitchableCallPattern(uword pc, const Code& code)
     : SwitchableCallPatternBase(code) {
   ASSERT(code.ContainsInstructionAt(pc));
   // Last instruction: blx lr.
   ASSERT(*(reinterpret_cast<uword*>(pc) - 1) == 0xe12fff3e);

   Register reg;
   uword data_load_end = InstructionPattern::DecodeLoadWordFromPool(
       pc - Instr::kInstrSize, &reg, &data_pool_index_);
   ASSERT(reg == R9);

   InstructionPattern::DecodeLoadWordFromPool(data_load_end, &reg,
                                              &target_pool_index_);
   ASSERT(reg == LR);
 }

 RawCode* BareSwitchableCallPattern::target() const {
   const uword pc = object_pool_.RawValueAt(target_pool_index_);
   auto rct = Isolate::Current()->reverse_pc_lookup_cache();
   if (rct->Contains(pc)) {
     return rct->Lookup(pc);
   }
   rct = Dart::vm_isolate()->reverse_pc_lookup_cache();
   if (rct->Contains(pc)) {
     return rct->Lookup(pc);
   }
   UNREACHABLE();
 }

 void BareSwitchableCallPattern::SetTarget(const Code& target) const {
   ASSERT(object_pool_.TypeAt(target_pool_index_) == ObjectPool::kImmediate);
   object_pool_.SetRawValueAt(target_pool_index_,
                              target.MonomorphicEntryPoint());
 }

 ReturnPattern::ReturnPattern(uword pc) : pc_(pc) {}

 bool ReturnPattern::IsValid() const {
   Instr* bx_lr = Instr::At(pc_);
   const int32_t B4 = 1 << 4;
   const int32_t B21 = 1 << 21;
   const int32_t B24 = 1 << 24;
   int32_t instruction = (static_cast<int32_t>(AL) << kConditionShift) | B24 |
                         B21 | (0xfff << 8) | B4 |
                         (static_cast<int32_t>(LR) << kRmShift);
   const ARMVersion version = TargetCPUFeatures::arm_version();
   if ((version == ARMv5TE) || (version == ARMv6)) {
     return bx_lr->InstructionBits() == instruction;
   } else {
     ASSERT(version == ARMv7);
     return bx_lr->InstructionBits() == instruction;
   }
   return false;
 }

 bool PcRelativeCallPattern::IsValid() const {
   // bl <offset>
   const uint32_t word = *reinterpret_cast<uint32_t*>(pc_);
   const uint32_t cond_all = 0xe0;
   const uint32_t branch_link = 0x0b;
   return (word >> 24) == (cond_all | branch_link);
 }

 bool PcRelativeJumpPattern::IsValid() const {
   // b <offset>
   const uint32_t word = *reinterpret_cast<uint32_t*>(pc_);
   const uint32_t cond_all = 0xe0;
   const uint32_t branch_nolink = 0x0a;
   return (word >> 24) == (cond_all | branch_nolink);
 }

 intptr_t TypeTestingStubCallPattern::GetSubtypeTestCachePoolIndex() {
   // Calls to the type testing stubs look like:
   //   ldr R3, [PP+idx]
   //   blx R9

   // Ensure the caller of the type testing stub (whose return address is [pc_])
   // branched via the `blx R9` instruction.
   ASSERT(*reinterpret_cast<uint32_t*>(pc_ - Instr::kInstrSize) == 0xe12fff39);
   const uword load_instr_end = pc_ - Instr::kInstrSize;

   Register reg;
   intptr_t pool_index = -1;
   InstructionPattern::DecodeLoadWordFromPool(load_instr_end, &reg, &pool_index);
   ASSERT(reg == R3);
   return pool_index;
 }

 }  // namespace dart

 #endif  // defined TARGET_ARCH_ARM
	// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/globals.h" // Needed here to get TARGET_ARCH_ARM.
	#if defined(TARGET_ARCH_ARM)

	#include "vm/instructions.h"
	#include "vm/instructions_arm.h"

	#include "vm/compiler/assembler/assembler.h"
	#include "vm/constants_arm.h"
	#include "vm/cpu.h"
	#include "vm/object.h"
	#include "vm/reverse_pc_lookup_cache.h"

	namespace dart {

	CallPattern::CallPattern(uword pc, const Code& code)
	: object_pool_(ObjectPool::Handle(code.GetObjectPool())),
	end_(pc),
	ic_data_load_end_(0),
	target_code_pool_index_(-1),
	ic_data_(ICData::Handle()) {
	ASSERT(code.ContainsInstructionAt(pc));
	// Last instruction: blx lr.
	ASSERT((reinterpret_cast<uword>(end_) - 1) == 0xe12fff3e);

	Register reg;
	ic_data_load_end_ = InstructionPattern::DecodeLoadWordFromPool(
	end_ - 2 * Instr::kInstrSize, &reg, &target_code_pool_index_);
	ASSERT(reg == CODE_REG);
	}

	NativeCallPattern::NativeCallPattern(uword pc, const Code& code)
	: object_pool_(ObjectPool::Handle(code.GetObjectPool())),
	end_(pc),
	native_function_pool_index_(-1),
	target_code_pool_index_(-1) {
	ASSERT(code.ContainsInstructionAt(pc));
	// Last instruction: blx lr.
	ASSERT((reinterpret_cast<uword>(end_) - 1) == 0xe12fff3e);

	Register reg;
	uword native_function_load_end = InstructionPattern::DecodeLoadWordFromPool(
	end_ - 2 * Instr::kInstrSize, &reg, &target_code_pool_index_);
	ASSERT(reg == CODE_REG);
	InstructionPattern::DecodeLoadWordFromPool(native_function_load_end, &reg,
	&native_function_pool_index_);
	ASSERT(reg == R9);
	}

	RawCode* NativeCallPattern::target() const {
	return reinterpret_cast<RawCode*>(
	object_pool_.ObjectAt(target_code_pool_index_));
	}

	void NativeCallPattern::set_target(const Code& new_target) const {
	object_pool_.SetObjectAt(target_code_pool_index_, new_target);
	// No need to flush the instruction cache, since the code is not modified.
	}

	NativeFunction NativeCallPattern::native_function() const {
	return reinterpret_cast<NativeFunction>(
	object_pool_.RawValueAt(native_function_pool_index_));
	}

	void NativeCallPattern::set_native_function(NativeFunction func) const {
	object_pool_.SetRawValueAt(native_function_pool_index_,
	reinterpret_cast<uword>(func));
	}

	// Decodes a load sequence ending at 'end' (the last instruction of the load
	// sequence is the instruction before the one at end). Returns a pointer to
	// the first instruction in the sequence. Returns the register being loaded
	// and the loaded object in the output parameters 'reg' and 'obj'
	// respectively.
	uword InstructionPattern::DecodeLoadObject(uword end,
	const ObjectPool& object_pool,
	Register* reg,
	Object* obj) {
	uword start = 0;
	Instr* instr = Instr::At(end - Instr::kInstrSize);
	if ((instr->InstructionBits() & 0xfff00000) == 0xe5900000) {
	// ldr reg, [reg, #+offset]
	intptr_t index = 0;
	start = DecodeLoadWordFromPool(end, reg, &index);
	*obj = object_pool.ObjectAt(index);
	} else {
	intptr_t value = 0;
	start = DecodeLoadWordImmediate(end, reg, &value);
	obj = reinterpret_cast<RawObject>(value);
	}
	return start;
	}

	// Decodes a load sequence ending at 'end' (the last instruction of the load
	// sequence is the instruction before the one at end). Returns a pointer to
	// the first instruction in the sequence. Returns the register being loaded
	// and the loaded immediate value in the output parameters 'reg' and 'value'
	// respectively.
	uword InstructionPattern::DecodeLoadWordImmediate(uword end,
	Register* reg,
	intptr_t* value) {
	uword start = end - Instr::kInstrSize;
	int32_t instr = Instr::At(start)->InstructionBits();
	intptr_t imm = 0;
	const ARMVersion version = TargetCPUFeatures::arm_version();
	if ((version == ARMv5TE) \|\| (version == ARMv6)) {
	ASSERT((instr & 0xfff00000) == 0xe3800000); // orr rd, rd, byte0
	imm \|= (instr & 0x000000ff);

	start -= Instr::kInstrSize;
	instr = Instr::At(start)->InstructionBits();
	ASSERT((instr & 0xfff00000) == 0xe3800c00); // orr rd, rd, (byte1 rot 12)
	imm \|= (instr & 0x000000ff);

	start -= Instr::kInstrSize;
	instr = Instr::At(start)->InstructionBits();
	ASSERT((instr & 0xfff00f00) == 0xe3800800); // orr rd, rd, (byte2 rot 8)
	imm \|= (instr & 0x000000ff);

	start -= Instr::kInstrSize;
	instr = Instr::At(start)->InstructionBits();
	ASSERT((instr & 0xffff0f00) == 0xe3a00400); // mov rd, (byte3 rot 4)
	imm \|= (instr & 0x000000ff);

	*reg = static_cast<Register>((instr & 0x0000f000) >> 12);
	*value = imm;
	} else {
	ASSERT(version == ARMv7);
	if ((instr & 0xfff00000) == 0xe3400000) { // movt reg, #imm_hi
	imm \|= (instr & 0xf0000) << 12;
	imm \|= (instr & 0xfff) << 16;
	start -= Instr::kInstrSize;
	instr = Instr::At(start)->InstructionBits();
	}
	ASSERT((instr & 0xfff00000) == 0xe3000000); // movw reg, #imm_lo
	imm \|= (instr & 0xf0000) >> 4;
	imm \|= instr & 0xfff;
	*reg = static_cast<Register>((instr & 0xf000) >> 12);
	*value = imm;
	}
	return start;
	}

	static bool IsLoadWithOffset(int32_t instr,
	Register base,
	intptr_t* offset,
	Register* dst) {
	if ((instr & 0xffff0000) == (0xe5900000 \| (base << 16))) {
	// ldr reg, [base, #+offset]
	*offset = instr & 0xfff;
	*dst = static_cast<Register>((instr & 0xf000) >> 12);
	return true;
	}
	return false;
	}

	// Decodes a load sequence ending at 'end' (the last instruction of the load
	// sequence is the instruction before the one at end). Returns a pointer to
	// the first instruction in the sequence. Returns the register being loaded
	// and the index in the pool being read from in the output parameters 'reg'
	// and 'index' respectively.
	uword InstructionPattern::DecodeLoadWordFromPool(uword end,
	Register* reg,
	intptr_t* index) {
	uword start = end - Instr::kInstrSize;
	int32_t instr = Instr::At(start)->InstructionBits();
	intptr_t offset = 0;
	if (IsLoadWithOffset(instr, PP, &offset, reg)) {
	// ldr reg, [PP, #+offset]
	} else {
	ASSERT((instr & 0xfff00000) == 0xe5900000); // ldr reg, [reg, #+offset]
	offset = instr & 0xfff;
	start -= Instr::kInstrSize;
	instr = Instr::At(start)->InstructionBits();
	if ((instr & 0xffff0000) == (0xe2850000 \| (PP << 16))) {
	// add reg, pp, operand
	const intptr_t rot = (instr & 0xf00) >> 7;
	const intptr_t imm8 = instr & 0xff;
	offset += (imm8 >> rot) \| (imm8 << (32 - rot));
	*reg = static_cast<Register>((instr & 0xf000) >> 12);
	} else {
	ASSERT((instr & 0xffff0000) == (0xe0800000 \| (PP << 16)));
	// add reg, pp, reg
	end = DecodeLoadWordImmediate(end, reg, &offset);
	}
	}
	*index = ObjectPool::IndexFromOffset(offset);
	return start;
	}

	bool DecodeLoadObjectFromPoolOrThread(uword pc, const Code& code, Object* obj) {
	ASSERT(code.ContainsInstructionAt(pc));

	int32_t instr = Instr::At(pc)->InstructionBits();
	intptr_t offset;
	Register dst;
	if (IsLoadWithOffset(instr, PP, &offset, &dst)) {
	intptr_t index = ObjectPool::IndexFromOffset(offset);
	const ObjectPool& pool = ObjectPool::Handle(code.object_pool());
	if (!pool.IsNull()) {
	if (pool.TypeAt(index) == ObjectPool::kTaggedObject) {
	*obj = pool.ObjectAt(index);
	return true;
	}
	}
	} else if (IsLoadWithOffset(instr, THR, &offset, &dst)) {
	return Thread::ObjectAtOffset(offset, obj);
	}
	// TODO(rmacnak): Sequence for loads beyond 12 bits.

	return false;
	}

	RawICData* CallPattern::IcData() {
	if (ic_data_.IsNull()) {
	Register reg;
	InstructionPattern::DecodeLoadObject(ic_data_load_end_, object_pool_, &reg,
	&ic_data_);
	ASSERT(reg == R9);
	}
	return ic_data_.raw();
	}

	RawCode* CallPattern::TargetCode() const {
	return reinterpret_cast<RawCode*>(
	object_pool_.ObjectAt(target_code_pool_index_));
	}

	void CallPattern::SetTargetCode(const Code& target_code) const {
	object_pool_.SetObjectAt(target_code_pool_index_, target_code);
	}

	SwitchableCallPatternBase::SwitchableCallPatternBase(const Code& code)
	: object_pool_(ObjectPool::Handle(code.GetObjectPool())),
	data_pool_index_(-1),
	target_pool_index_(-1) {}

	RawObject* SwitchableCallPatternBase::data() const {
	return object_pool_.ObjectAt(data_pool_index_);
	}

	void SwitchableCallPatternBase::SetData(const Object& data) const {
	ASSERT(!Object::Handle(object_pool_.ObjectAt(data_pool_index_)).IsCode());
	object_pool_.SetObjectAt(data_pool_index_, data);
	}

	SwitchableCallPattern::SwitchableCallPattern(uword pc, const Code& code)
	: SwitchableCallPatternBase(code) {
	ASSERT(code.ContainsInstructionAt(pc));
	// Last instruction: blx lr.
	ASSERT((reinterpret_cast<uword>(pc) - 1) == 0xe12fff3e);

	Register reg;
	uword data_load_end = InstructionPattern::DecodeLoadWordFromPool(
	pc - Instr::kInstrSize, &reg, &data_pool_index_);
	ASSERT(reg == R9);
	InstructionPattern::DecodeLoadWordFromPool(data_load_end - Instr::kInstrSize,
	&reg, &target_pool_index_);
	ASSERT(reg == CODE_REG);
	}

	RawCode* SwitchableCallPattern::target() const {
	return reinterpret_cast<RawCode*>(object_pool_.ObjectAt(target_pool_index_));
	}
	void SwitchableCallPattern::SetTarget(const Code& target) const {
	ASSERT(Object::Handle(object_pool_.ObjectAt(target_pool_index_)).IsCode());
	object_pool_.SetObjectAt(target_pool_index_, target);
	}

	BareSwitchableCallPattern::BareSwitchableCallPattern(uword pc, const Code& code)
	: SwitchableCallPatternBase(code) {
	ASSERT(code.ContainsInstructionAt(pc));
	// Last instruction: blx lr.
	ASSERT((reinterpret_cast<uword>(pc) - 1) == 0xe12fff3e);

	Register reg;
	uword data_load_end = InstructionPattern::DecodeLoadWordFromPool(
	pc - Instr::kInstrSize, &reg, &data_pool_index_);
	ASSERT(reg == R9);

	InstructionPattern::DecodeLoadWordFromPool(data_load_end, &reg,
	&target_pool_index_);
	ASSERT(reg == LR);
	}

	RawCode* BareSwitchableCallPattern::target() const {
	const uword pc = object_pool_.RawValueAt(target_pool_index_);
	auto rct = Isolate::Current()->reverse_pc_lookup_cache();
	if (rct->Contains(pc)) {
	return rct->Lookup(pc);
	}
	rct = Dart::vm_isolate()->reverse_pc_lookup_cache();
	if (rct->Contains(pc)) {
	return rct->Lookup(pc);
	}
	UNREACHABLE();
	}

	void BareSwitchableCallPattern::SetTarget(const Code& target) const {
	ASSERT(object_pool_.TypeAt(target_pool_index_) == ObjectPool::kImmediate);
	object_pool_.SetRawValueAt(target_pool_index_,
	target.MonomorphicEntryPoint());
	}

	ReturnPattern::ReturnPattern(uword pc) : pc_(pc) {}

	bool ReturnPattern::IsValid() const {
	Instr* bx_lr = Instr::At(pc_);
	const int32_t B4 = 1 << 4;
	const int32_t B21 = 1 << 21;
	const int32_t B24 = 1 << 24;
	int32_t instruction = (static_cast<int32_t>(AL) << kConditionShift) \| B24 \|
	B21 \| (0xfff << 8) \| B4 \|
	(static_cast<int32_t>(LR) << kRmShift);
	const ARMVersion version = TargetCPUFeatures::arm_version();
	if ((version == ARMv5TE) \|\| (version == ARMv6)) {
	return bx_lr->InstructionBits() == instruction;
	} else {
	ASSERT(version == ARMv7);
	return bx_lr->InstructionBits() == instruction;
	}
	return false;
	}

	bool PcRelativeCallPattern::IsValid() const {
	// bl <offset>
	const uint32_t word = reinterpret_cast<uint32_t>(pc_);
	const uint32_t cond_all = 0xe0;
	const uint32_t branch_link = 0x0b;
	return (word >> 24) == (cond_all \| branch_link);
	}

	bool PcRelativeJumpPattern::IsValid() const {
	// b <offset>
	const uint32_t word = reinterpret_cast<uint32_t>(pc_);
	const uint32_t cond_all = 0xe0;
	const uint32_t branch_nolink = 0x0a;
	return (word >> 24) == (cond_all \| branch_nolink);
	}

	intptr_t TypeTestingStubCallPattern::GetSubtypeTestCachePoolIndex() {
	// Calls to the type testing stubs look like:
	// ldr R3, [PP+idx]
	// blx R9

	// Ensure the caller of the type testing stub (whose return address is [pc_])
	// branched via the `blx R9` instruction.
	ASSERT(reinterpret_cast<uint32_t>(pc_ - Instr::kInstrSize) == 0xe12fff39);
	const uword load_instr_end = pc_ - Instr::kInstrSize;

	Register reg;
	intptr_t pool_index = -1;
	InstructionPattern::DecodeLoadWordFromPool(load_instr_end, &reg, &pool_index);
	ASSERT(reg == R3);
	return pool_index;
	}

	} // namespace dart

	#endif // defined TARGET_ARCH_ARM