blob: b06d91c82361a998802faf4504334543fd034c36 [file] [log] [blame]
/*
* Copyright (C) 2016 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "instruction_builder.h"
#include "art_method-inl.h"
#include "bytecode_utils.h"
#include "class_linker.h"
#include "data_type-inl.h"
#include "dex_instruction-inl.h"
#include "driver/compiler_options.h"
#include "imtable-inl.h"
#include "quicken_info.h"
#include "scoped_thread_state_change-inl.h"
#include "sharpening.h"
#include "well_known_classes.h"
namespace art {
HBasicBlock* HInstructionBuilder::FindBlockStartingAt(uint32_t dex_pc) const {
return block_builder_->GetBlockAt(dex_pc);
}
inline ArenaVector<HInstruction*>* HInstructionBuilder::GetLocalsFor(HBasicBlock* block) {
ArenaVector<HInstruction*>* locals = &locals_for_[block->GetBlockId()];
const size_t vregs = graph_->GetNumberOfVRegs();
if (locals->size() == vregs) {
return locals;
}
return GetLocalsForWithAllocation(block, locals, vregs);
}
ArenaVector<HInstruction*>* HInstructionBuilder::GetLocalsForWithAllocation(
HBasicBlock* block,
ArenaVector<HInstruction*>* locals,
const size_t vregs) {
DCHECK_NE(locals->size(), vregs);
locals->resize(vregs, nullptr);
if (block->IsCatchBlock()) {
// We record incoming inputs of catch phis at throwing instructions and
// must therefore eagerly create the phis. Phis for undefined vregs will
// be deleted when the first throwing instruction with the vreg undefined
// is encountered. Unused phis will be removed by dead phi analysis.
for (size_t i = 0; i < vregs; ++i) {
// No point in creating the catch phi if it is already undefined at
// the first throwing instruction.
HInstruction* current_local_value = (*current_locals_)[i];
if (current_local_value != nullptr) {
HPhi* phi = new (allocator_) HPhi(
allocator_,
i,
0,
current_local_value->GetType());
block->AddPhi(phi);
(*locals)[i] = phi;
}
}
}
return locals;
}
inline HInstruction* HInstructionBuilder::ValueOfLocalAt(HBasicBlock* block, size_t local) {
ArenaVector<HInstruction*>* locals = GetLocalsFor(block);
return (*locals)[local];
}
void HInstructionBuilder::InitializeBlockLocals() {
current_locals_ = GetLocalsFor(current_block_);
if (current_block_->IsCatchBlock()) {
// Catch phis were already created and inputs collected from throwing sites.
if (kIsDebugBuild) {
// Make sure there was at least one throwing instruction which initialized
// locals (guaranteed by HGraphBuilder) and that all try blocks have been
// visited already (from HTryBoundary scoping and reverse post order).
bool catch_block_visited = false;
for (HBasicBlock* current : graph_->GetReversePostOrder()) {
if (current == current_block_) {
catch_block_visited = true;
} else if (current->IsTryBlock()) {
const HTryBoundary& try_entry = current->GetTryCatchInformation()->GetTryEntry();
if (try_entry.HasExceptionHandler(*current_block_)) {
DCHECK(!catch_block_visited) << "Catch block visited before its try block.";
}
}
}
DCHECK_EQ(current_locals_->size(), graph_->GetNumberOfVRegs())
<< "No instructions throwing into a live catch block.";
}
} else if (current_block_->IsLoopHeader()) {
// If the block is a loop header, we know we only have visited the pre header
// because we are visiting in reverse post order. We create phis for all initialized
// locals from the pre header. Their inputs will be populated at the end of
// the analysis.
for (size_t local = 0; local < current_locals_->size(); ++local) {
HInstruction* incoming =
ValueOfLocalAt(current_block_->GetLoopInformation()->GetPreHeader(), local);
if (incoming != nullptr) {
HPhi* phi = new (allocator_) HPhi(
allocator_,
local,
0,
incoming->GetType());
current_block_->AddPhi(phi);
(*current_locals_)[local] = phi;
}
}
// Save the loop header so that the last phase of the analysis knows which
// blocks need to be updated.
loop_headers_.push_back(current_block_);
} else if (current_block_->GetPredecessors().size() > 0) {
// All predecessors have already been visited because we are visiting in reverse post order.
// We merge the values of all locals, creating phis if those values differ.
for (size_t local = 0; local < current_locals_->size(); ++local) {
bool one_predecessor_has_no_value = false;
bool is_different = false;
HInstruction* value = ValueOfLocalAt(current_block_->GetPredecessors()[0], local);
for (HBasicBlock* predecessor : current_block_->GetPredecessors()) {
HInstruction* current = ValueOfLocalAt(predecessor, local);
if (current == nullptr) {
one_predecessor_has_no_value = true;
break;
} else if (current != value) {
is_different = true;
}
}
if (one_predecessor_has_no_value) {
// If one predecessor has no value for this local, we trust the verifier has
// successfully checked that there is a store dominating any read after this block.
continue;
}
if (is_different) {
HInstruction* first_input = ValueOfLocalAt(current_block_->GetPredecessors()[0], local);
HPhi* phi = new (allocator_) HPhi(
allocator_,
local,
current_block_->GetPredecessors().size(),
first_input->GetType());
for (size_t i = 0; i < current_block_->GetPredecessors().size(); i++) {
HInstruction* pred_value = ValueOfLocalAt(current_block_->GetPredecessors()[i], local);
phi->SetRawInputAt(i, pred_value);
}
current_block_->AddPhi(phi);
value = phi;
}
(*current_locals_)[local] = value;
}
}
}
void HInstructionBuilder::PropagateLocalsToCatchBlocks() {
const HTryBoundary& try_entry = current_block_->GetTryCatchInformation()->GetTryEntry();
for (HBasicBlock* catch_block : try_entry.GetExceptionHandlers()) {
ArenaVector<HInstruction*>* handler_locals = GetLocalsFor(catch_block);
DCHECK_EQ(handler_locals->size(), current_locals_->size());
for (size_t vreg = 0, e = current_locals_->size(); vreg < e; ++vreg) {
HInstruction* handler_value = (*handler_locals)[vreg];
if (handler_value == nullptr) {
// Vreg was undefined at a previously encountered throwing instruction
// and the catch phi was deleted. Do not record the local value.
continue;
}
DCHECK(handler_value->IsPhi());
HInstruction* local_value = (*current_locals_)[vreg];
if (local_value == nullptr) {
// This is the first instruction throwing into `catch_block` where
// `vreg` is undefined. Delete the catch phi.
catch_block->RemovePhi(handler_value->AsPhi());
(*handler_locals)[vreg] = nullptr;
} else {
// Vreg has been defined at all instructions throwing into `catch_block`
// encountered so far. Record the local value in the catch phi.
handler_value->AsPhi()->AddInput(local_value);
}
}
}
}
void HInstructionBuilder::AppendInstruction(HInstruction* instruction) {
current_block_->AddInstruction(instruction);
InitializeInstruction(instruction);
}
void HInstructionBuilder::InsertInstructionAtTop(HInstruction* instruction) {
if (current_block_->GetInstructions().IsEmpty()) {
current_block_->AddInstruction(instruction);
} else {
current_block_->InsertInstructionBefore(instruction, current_block_->GetFirstInstruction());
}
InitializeInstruction(instruction);
}
void HInstructionBuilder::InitializeInstruction(HInstruction* instruction) {
if (instruction->NeedsEnvironment()) {
HEnvironment* environment = new (allocator_) HEnvironment(
allocator_,
current_locals_->size(),
graph_->GetArtMethod(),
instruction->GetDexPc(),
instruction);
environment->CopyFrom(*current_locals_);
instruction->SetRawEnvironment(environment);
}
}
HInstruction* HInstructionBuilder::LoadNullCheckedLocal(uint32_t register_index, uint32_t dex_pc) {
HInstruction* ref = LoadLocal(register_index, DataType::Type::kReference);
if (!ref->CanBeNull()) {
return ref;
}
HNullCheck* null_check = new (allocator_) HNullCheck(ref, dex_pc);
AppendInstruction(null_check);
return null_check;
}
void HInstructionBuilder::SetLoopHeaderPhiInputs() {
for (size_t i = loop_headers_.size(); i > 0; --i) {
HBasicBlock* block = loop_headers_[i - 1];
for (HInstructionIterator it(block->GetPhis()); !it.Done(); it.Advance()) {
HPhi* phi = it.Current()->AsPhi();
size_t vreg = phi->GetRegNumber();
for (HBasicBlock* predecessor : block->GetPredecessors()) {
HInstruction* value = ValueOfLocalAt(predecessor, vreg);
if (value == nullptr) {
// Vreg is undefined at this predecessor. Mark it dead and leave with
// fewer inputs than predecessors. SsaChecker will fail if not removed.
phi->SetDead();
break;
} else {
phi->AddInput(value);
}
}
}
}
}
static bool IsBlockPopulated(HBasicBlock* block) {
if (block->IsLoopHeader()) {
// Suspend checks were inserted into loop headers during building of dominator tree.
DCHECK(block->GetFirstInstruction()->IsSuspendCheck());
return block->GetFirstInstruction() != block->GetLastInstruction();
} else {
return !block->GetInstructions().IsEmpty();
}
}
bool HInstructionBuilder::Build() {
locals_for_.resize(graph_->GetBlocks().size(),
ArenaVector<HInstruction*>(allocator_->Adapter(kArenaAllocGraphBuilder)));
// Find locations where we want to generate extra stackmaps for native debugging.
// This allows us to generate the info only at interesting points (for example,
// at start of java statement) rather than before every dex instruction.
const bool native_debuggable = compiler_driver_ != nullptr &&
compiler_driver_->GetCompilerOptions().GetNativeDebuggable();
ArenaBitVector* native_debug_info_locations = nullptr;
if (native_debuggable) {
const uint32_t num_instructions = code_item_.insns_size_in_code_units_;
native_debug_info_locations =
new (allocator_) ArenaBitVector (allocator_, num_instructions, false);
FindNativeDebugInfoLocations(native_debug_info_locations);
}
for (HBasicBlock* block : graph_->GetReversePostOrder()) {
current_block_ = block;
uint32_t block_dex_pc = current_block_->GetDexPc();
InitializeBlockLocals();
if (current_block_->IsEntryBlock()) {
InitializeParameters();
AppendInstruction(new (allocator_) HSuspendCheck(0u));
AppendInstruction(new (allocator_) HGoto(0u));
continue;
} else if (current_block_->IsExitBlock()) {
AppendInstruction(new (allocator_) HExit());
continue;
} else if (current_block_->IsLoopHeader()) {
HSuspendCheck* suspend_check = new (allocator_) HSuspendCheck(current_block_->GetDexPc());
current_block_->GetLoopInformation()->SetSuspendCheck(suspend_check);
// This is slightly odd because the loop header might not be empty (TryBoundary).
// But we're still creating the environment with locals from the top of the block.
InsertInstructionAtTop(suspend_check);
}
if (block_dex_pc == kNoDexPc || current_block_ != block_builder_->GetBlockAt(block_dex_pc)) {
// Synthetic block that does not need to be populated.
DCHECK(IsBlockPopulated(current_block_));
continue;
}
DCHECK(!IsBlockPopulated(current_block_));
uint32_t quicken_index = 0;
if (CanDecodeQuickenedInfo()) {
quicken_index = block_builder_->GetQuickenIndex(block_dex_pc);
}
for (CodeItemIterator it(code_item_, block_dex_pc); !it.Done(); it.Advance()) {
if (current_block_ == nullptr) {
// The previous instruction ended this block.
break;
}
uint32_t dex_pc = it.CurrentDexPc();
if (dex_pc != block_dex_pc && FindBlockStartingAt(dex_pc) != nullptr) {
// This dex_pc starts a new basic block.
break;
}
if (current_block_->IsTryBlock() && IsThrowingDexInstruction(it.CurrentInstruction())) {
PropagateLocalsToCatchBlocks();
}
if (native_debuggable && native_debug_info_locations->IsBitSet(dex_pc)) {
AppendInstruction(new (allocator_) HNativeDebugInfo(dex_pc));
}
if (!ProcessDexInstruction(it.CurrentInstruction(), dex_pc, quicken_index)) {
return false;
}
if (QuickenInfoTable::NeedsIndexForInstruction(&it.CurrentInstruction())) {
++quicken_index;
}
}
if (current_block_ != nullptr) {
// Branching instructions clear current_block, so we know the last
// instruction of the current block is not a branching instruction.
// We add an unconditional Goto to the next block.
DCHECK_EQ(current_block_->GetSuccessors().size(), 1u);
AppendInstruction(new (allocator_) HGoto());
}
}
SetLoopHeaderPhiInputs();
return true;
}
void HInstructionBuilder::FindNativeDebugInfoLocations(ArenaBitVector* locations) {
// The callback gets called when the line number changes.
// In other words, it marks the start of new java statement.
struct Callback {
static bool Position(void* ctx, const DexFile::PositionInfo& entry) {
static_cast<ArenaBitVector*>(ctx)->SetBit(entry.address_);
return false;
}
};
dex_file_->DecodeDebugPositionInfo(&code_item_, Callback::Position, locations);
// Instruction-specific tweaks.
IterationRange<DexInstructionIterator> instructions = code_item_.Instructions();
for (const Instruction& inst : instructions) {
switch (inst.Opcode()) {
case Instruction::MOVE_EXCEPTION: {
// Stop in native debugger after the exception has been moved.
// The compiler also expects the move at the start of basic block so
// we do not want to interfere by inserting native-debug-info before it.
locations->ClearBit(inst.GetDexPc(code_item_.insns_));
const Instruction* next = inst.Next();
if (DexInstructionIterator(next) != instructions.end()) {
locations->SetBit(next->GetDexPc(code_item_.insns_));
}
break;
}
default:
break;
}
}
}
HInstruction* HInstructionBuilder::LoadLocal(uint32_t reg_number, DataType::Type type) const {
HInstruction* value = (*current_locals_)[reg_number];
DCHECK(value != nullptr);
// If the operation requests a specific type, we make sure its input is of that type.
if (type != value->GetType()) {
if (DataType::IsFloatingPointType(type)) {
value = ssa_builder_->GetFloatOrDoubleEquivalent(value, type);
} else if (type == DataType::Type::kReference) {
value = ssa_builder_->GetReferenceTypeEquivalent(value);
}
DCHECK(value != nullptr);
}
return value;
}
void HInstructionBuilder::UpdateLocal(uint32_t reg_number, HInstruction* stored_value) {
DataType::Type stored_type = stored_value->GetType();
DCHECK_NE(stored_type, DataType::Type::kVoid);
// Storing into vreg `reg_number` may implicitly invalidate the surrounding
// registers. Consider the following cases:
// (1) Storing a wide value must overwrite previous values in both `reg_number`
// and `reg_number+1`. We store `nullptr` in `reg_number+1`.
// (2) If vreg `reg_number-1` holds a wide value, writing into `reg_number`
// must invalidate it. We store `nullptr` in `reg_number-1`.
// Consequently, storing a wide value into the high vreg of another wide value
// will invalidate both `reg_number-1` and `reg_number+1`.
if (reg_number != 0) {
HInstruction* local_low = (*current_locals_)[reg_number - 1];
if (local_low != nullptr && DataType::Is64BitType(local_low->GetType())) {
// The vreg we are storing into was previously the high vreg of a pair.
// We need to invalidate its low vreg.
DCHECK((*current_locals_)[reg_number] == nullptr);
(*current_locals_)[reg_number - 1] = nullptr;
}
}
(*current_locals_)[reg_number] = stored_value;
if (DataType::Is64BitType(stored_type)) {
// We are storing a pair. Invalidate the instruction in the high vreg.
(*current_locals_)[reg_number + 1] = nullptr;
}
}
void HInstructionBuilder::InitializeParameters() {
DCHECK(current_block_->IsEntryBlock());
// dex_compilation_unit_ is null only when unit testing.
if (dex_compilation_unit_ == nullptr) {
return;
}
const char* shorty = dex_compilation_unit_->GetShorty();
uint16_t number_of_parameters = graph_->GetNumberOfInVRegs();
uint16_t locals_index = graph_->GetNumberOfLocalVRegs();
uint16_t parameter_index = 0;
const DexFile::MethodId& referrer_method_id =
dex_file_->GetMethodId(dex_compilation_unit_->GetDexMethodIndex());
if (!dex_compilation_unit_->IsStatic()) {
// Add the implicit 'this' argument, not expressed in the signature.
HParameterValue* parameter = new (allocator_) HParameterValue(*dex_file_,
referrer_method_id.class_idx_,
parameter_index++,
DataType::Type::kReference,
/* is_this */ true);
AppendInstruction(parameter);
UpdateLocal(locals_index++, parameter);
number_of_parameters--;
current_this_parameter_ = parameter;
} else {
DCHECK(current_this_parameter_ == nullptr);
}
const DexFile::ProtoId& proto = dex_file_->GetMethodPrototype(referrer_method_id);
const DexFile::TypeList* arg_types = dex_file_->GetProtoParameters(proto);
for (int i = 0, shorty_pos = 1; i < number_of_parameters; i++) {
HParameterValue* parameter = new (allocator_) HParameterValue(
*dex_file_,
arg_types->GetTypeItem(shorty_pos - 1).type_idx_,
parameter_index++,
DataType::FromShorty(shorty[shorty_pos]),
/* is_this */ false);
++shorty_pos;
AppendInstruction(parameter);
// Store the parameter value in the local that the dex code will use
// to reference that parameter.
UpdateLocal(locals_index++, parameter);
if (DataType::Is64BitType(parameter->GetType())) {
i++;
locals_index++;
parameter_index++;
}
}
}
template<typename T>
void HInstructionBuilder::If_22t(const Instruction& instruction, uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegA(), DataType::Type::kInt32);
HInstruction* second = LoadLocal(instruction.VRegB(), DataType::Type::kInt32);
T* comparison = new (allocator_) T(first, second, dex_pc);
AppendInstruction(comparison);
AppendInstruction(new (allocator_) HIf(comparison, dex_pc));
current_block_ = nullptr;
}
template<typename T>
void HInstructionBuilder::If_21t(const Instruction& instruction, uint32_t dex_pc) {
HInstruction* value = LoadLocal(instruction.VRegA(), DataType::Type::kInt32);
T* comparison = new (allocator_) T(value, graph_->GetIntConstant(0, dex_pc), dex_pc);
AppendInstruction(comparison);
AppendInstruction(new (allocator_) HIf(comparison, dex_pc));
current_block_ = nullptr;
}
template<typename T>
void HInstructionBuilder::Unop_12x(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), type);
AppendInstruction(new (allocator_) T(type, first, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
void HInstructionBuilder::Conversion_12x(const Instruction& instruction,
DataType::Type input_type,
DataType::Type result_type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), input_type);
AppendInstruction(new (allocator_) HTypeConversion(result_type, first, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_23x(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), type);
HInstruction* second = LoadLocal(instruction.VRegC(), type);
AppendInstruction(new (allocator_) T(type, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_23x_shift(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), type);
HInstruction* second = LoadLocal(instruction.VRegC(), DataType::Type::kInt32);
AppendInstruction(new (allocator_) T(type, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
void HInstructionBuilder::Binop_23x_cmp(const Instruction& instruction,
DataType::Type type,
ComparisonBias bias,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), type);
HInstruction* second = LoadLocal(instruction.VRegC(), type);
AppendInstruction(new (allocator_) HCompare(type, first, second, bias, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_12x_shift(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegA(), type);
HInstruction* second = LoadLocal(instruction.VRegB(), DataType::Type::kInt32);
AppendInstruction(new (allocator_) T(type, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_12x(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegA(), type);
HInstruction* second = LoadLocal(instruction.VRegB(), type);
AppendInstruction(new (allocator_) T(type, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_22s(const Instruction& instruction, bool reverse, uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), DataType::Type::kInt32);
HInstruction* second = graph_->GetIntConstant(instruction.VRegC_22s(), dex_pc);
if (reverse) {
std::swap(first, second);
}
AppendInstruction(new (allocator_) T(DataType::Type::kInt32, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
template<typename T>
void HInstructionBuilder::Binop_22b(const Instruction& instruction, bool reverse, uint32_t dex_pc) {
HInstruction* first = LoadLocal(instruction.VRegB(), DataType::Type::kInt32);
HInstruction* second = graph_->GetIntConstant(instruction.VRegC_22b(), dex_pc);
if (reverse) {
std::swap(first, second);
}
AppendInstruction(new (allocator_) T(DataType::Type::kInt32, first, second, dex_pc));
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
}
// Does the method being compiled need any constructor barriers being inserted?
// (Always 'false' for methods that aren't <init>.)
static bool RequiresConstructorBarrier(const DexCompilationUnit* cu, CompilerDriver* driver) {
// Can be null in unit tests only.
if (UNLIKELY(cu == nullptr)) {
return false;
}
Thread* self = Thread::Current();
return cu->IsConstructor()
&& !cu->IsStatic()
// RequiresConstructorBarrier must only be queried for <init> methods;
// it's effectively "false" for every other method.
//
// See CompilerDriver::RequiresConstructBarrier for more explanation.
&& driver->RequiresConstructorBarrier(self, cu->GetDexFile(), cu->GetClassDefIndex());
}
// Returns true if `block` has only one successor which starts at the next
// dex_pc after `instruction` at `dex_pc`.
static bool IsFallthroughInstruction(const Instruction& instruction,
uint32_t dex_pc,
HBasicBlock* block) {
uint32_t next_dex_pc = dex_pc + instruction.SizeInCodeUnits();
return block->GetSingleSuccessor()->GetDexPc() == next_dex_pc;
}
void HInstructionBuilder::BuildSwitch(const Instruction& instruction, uint32_t dex_pc) {
HInstruction* value = LoadLocal(instruction.VRegA(), DataType::Type::kInt32);
DexSwitchTable table(instruction, dex_pc);
if (table.GetNumEntries() == 0) {
// Empty Switch. Code falls through to the next block.
DCHECK(IsFallthroughInstruction(instruction, dex_pc, current_block_));
AppendInstruction(new (allocator_) HGoto(dex_pc));
} else if (table.ShouldBuildDecisionTree()) {
for (DexSwitchTableIterator it(table); !it.Done(); it.Advance()) {
HInstruction* case_value = graph_->GetIntConstant(it.CurrentKey(), dex_pc);
HEqual* comparison = new (allocator_) HEqual(value, case_value, dex_pc);
AppendInstruction(comparison);
AppendInstruction(new (allocator_) HIf(comparison, dex_pc));
if (!it.IsLast()) {
current_block_ = FindBlockStartingAt(it.GetDexPcForCurrentIndex());
}
}
} else {
AppendInstruction(
new (allocator_) HPackedSwitch(table.GetEntryAt(0), table.GetNumEntries(), value, dex_pc));
}
current_block_ = nullptr;
}
void HInstructionBuilder::BuildReturn(const Instruction& instruction,
DataType::Type type,
uint32_t dex_pc) {
if (type == DataType::Type::kVoid) {
// Only <init> (which is a return-void) could possibly have a constructor fence.
// This may insert additional redundant constructor fences from the super constructors.
// TODO: remove redundant constructor fences (b/36656456).
if (RequiresConstructorBarrier(dex_compilation_unit_, compiler_driver_)) {
// Compiling instance constructor.
DCHECK_STREQ("<init>", graph_->GetMethodName());
HInstruction* fence_target = current_this_parameter_;
DCHECK(fence_target != nullptr);
AppendInstruction(new (allocator_) HConstructorFence(fence_target, dex_pc, allocator_));
MaybeRecordStat(
compilation_stats_,
MethodCompilationStat::kConstructorFenceGeneratedFinal);
}
AppendInstruction(new (allocator_) HReturnVoid(dex_pc));
} else {
DCHECK(!RequiresConstructorBarrier(dex_compilation_unit_, compiler_driver_));
HInstruction* value = LoadLocal(instruction.VRegA(), type);
AppendInstruction(new (allocator_) HReturn(value, dex_pc));
}
current_block_ = nullptr;
}
static InvokeType GetInvokeTypeFromOpCode(Instruction::Code opcode) {
switch (opcode) {
case Instruction::INVOKE_STATIC:
case Instruction::INVOKE_STATIC_RANGE:
return kStatic;
case Instruction::INVOKE_DIRECT:
case Instruction::INVOKE_DIRECT_RANGE:
return kDirect;
case Instruction::INVOKE_VIRTUAL:
case Instruction::INVOKE_VIRTUAL_QUICK:
case Instruction::INVOKE_VIRTUAL_RANGE:
case Instruction::INVOKE_VIRTUAL_RANGE_QUICK:
return kVirtual;
case Instruction::INVOKE_INTERFACE:
case Instruction::INVOKE_INTERFACE_RANGE:
return kInterface;
case Instruction::INVOKE_SUPER_RANGE:
case Instruction::INVOKE_SUPER:
return kSuper;
default:
LOG(FATAL) << "Unexpected invoke opcode: " << opcode;
UNREACHABLE();
}
}
ArtMethod* HInstructionBuilder::ResolveMethod(uint16_t method_idx, InvokeType invoke_type) {
ScopedObjectAccess soa(Thread::Current());
ClassLinker* class_linker = dex_compilation_unit_->GetClassLinker();
Handle<mirror::ClassLoader> class_loader = dex_compilation_unit_->GetClassLoader();
ArtMethod* resolved_method =
class_linker->ResolveMethod<ClassLinker::ResolveMode::kCheckICCEAndIAE>(
*dex_compilation_unit_->GetDexFile(),
method_idx,
dex_compilation_unit_->GetDexCache(),
class_loader,
graph_->GetArtMethod(),
invoke_type);
if (UNLIKELY(resolved_method == nullptr)) {
// Clean up any exception left by type resolution.
soa.Self()->ClearException();
return nullptr;
}
// The referrer may be unresolved for AOT if we're compiling a class that cannot be
// resolved because, for example, we don't find a superclass in the classpath.
if (graph_->GetArtMethod() == nullptr) {
// The class linker cannot check access without a referrer, so we have to do it.
// Fall back to HInvokeUnresolved if the method isn't public.
if (!resolved_method->IsPublic()) {
return nullptr;
}
}
// We have to special case the invoke-super case, as ClassLinker::ResolveMethod does not.
// We need to look at the referrer's super class vtable. We need to do this to know if we need to
// make this an invoke-unresolved to handle cross-dex invokes or abstract super methods, both of
// which require runtime handling.
if (invoke_type == kSuper) {
ObjPtr<mirror::Class> compiling_class = GetCompilingClass();
if (compiling_class == nullptr) {
// We could not determine the method's class we need to wait until runtime.
DCHECK(Runtime::Current()->IsAotCompiler());
return nullptr;
}
ObjPtr<mirror::Class> referenced_class = class_linker->LookupResolvedType(
*dex_compilation_unit_->GetDexFile(),
dex_compilation_unit_->GetDexFile()->GetMethodId(method_idx).class_idx_,
dex_compilation_unit_->GetDexCache().Get(),
class_loader.Get());
DCHECK(referenced_class != nullptr); // We have already resolved a method from this class.
if (!referenced_class->IsAssignableFrom(compiling_class)) {
// We cannot statically determine the target method. The runtime will throw a
// NoSuchMethodError on this one.
return nullptr;
}
ArtMethod* actual_method;
if (referenced_class->IsInterface()) {
actual_method = referenced_class->FindVirtualMethodForInterfaceSuper(
resolved_method, class_linker->GetImagePointerSize());
} else {
uint16_t vtable_index = resolved_method->GetMethodIndex();
actual_method = compiling_class->GetSuperClass()->GetVTableEntry(
vtable_index, class_linker->GetImagePointerSize());
}
if (actual_method != resolved_method &&
!IsSameDexFile(*actual_method->GetDexFile(), *dex_compilation_unit_->GetDexFile())) {
// The back-end code generator relies on this check in order to ensure that it will not
// attempt to read the dex_cache with a dex_method_index that is not from the correct
// dex_file. If we didn't do this check then the dex_method_index will not be updated in the
// builder, which means that the code-generator (and compiler driver during sharpening and
// inliner, maybe) might invoke an incorrect method.
// TODO: The actual method could still be referenced in the current dex file, so we
// could try locating it.
// TODO: Remove the dex_file restriction.
return nullptr;
}
if (!actual_method->IsInvokable()) {
// Fail if the actual method cannot be invoked. Otherwise, the runtime resolution stub
// could resolve the callee to the wrong method.
return nullptr;
}
resolved_method = actual_method;
}
return resolved_method;
}
static bool IsStringConstructor(ArtMethod* method) {
ScopedObjectAccess soa(Thread::Current());
return method->GetDeclaringClass()->IsStringClass() && method->IsConstructor();
}
bool HInstructionBuilder::BuildInvoke(const Instruction& instruction,
uint32_t dex_pc,
uint32_t method_idx,
uint32_t number_of_vreg_arguments,
bool is_range,
uint32_t* args,
uint32_t register_index) {
InvokeType invoke_type = GetInvokeTypeFromOpCode(instruction.Opcode());
const char* descriptor = dex_file_->GetMethodShorty(method_idx);
DataType::Type return_type = DataType::FromShorty(descriptor[0]);
// Remove the return type from the 'proto'.
size_t number_of_arguments = strlen(descriptor) - 1;
if (invoke_type != kStatic) { // instance call
// One extra argument for 'this'.
number_of_arguments++;
}
ArtMethod* resolved_method = ResolveMethod(method_idx, invoke_type);
if (UNLIKELY(resolved_method == nullptr)) {
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kUnresolvedMethod);
HInvoke* invoke = new (allocator_) HInvokeUnresolved(allocator_,
number_of_arguments,
return_type,
dex_pc,
method_idx,
invoke_type);
return HandleInvoke(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor,
nullptr, /* clinit_check */
true /* is_unresolved */);
}
// Replace calls to String.<init> with StringFactory.
if (IsStringConstructor(resolved_method)) {
uint32_t string_init_entry_point = WellKnownClasses::StringInitToEntryPoint(resolved_method);
HInvokeStaticOrDirect::DispatchInfo dispatch_info = {
HInvokeStaticOrDirect::MethodLoadKind::kStringInit,
HInvokeStaticOrDirect::CodePtrLocation::kCallArtMethod,
dchecked_integral_cast<uint64_t>(string_init_entry_point)
};
MethodReference target_method(dex_file_, method_idx);
HInvoke* invoke = new (allocator_) HInvokeStaticOrDirect(
allocator_,
number_of_arguments - 1,
DataType::Type::kReference /*return_type */,
dex_pc,
method_idx,
nullptr,
dispatch_info,
invoke_type,
target_method,
HInvokeStaticOrDirect::ClinitCheckRequirement::kImplicit);
return HandleStringInit(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor);
}
// Potential class initialization check, in the case of a static method call.
HClinitCheck* clinit_check = nullptr;
HInvoke* invoke = nullptr;
if (invoke_type == kDirect || invoke_type == kStatic || invoke_type == kSuper) {
// By default, consider that the called method implicitly requires
// an initialization check of its declaring method.
HInvokeStaticOrDirect::ClinitCheckRequirement clinit_check_requirement
= HInvokeStaticOrDirect::ClinitCheckRequirement::kImplicit;
ScopedObjectAccess soa(Thread::Current());
if (invoke_type == kStatic) {
clinit_check = ProcessClinitCheckForInvoke(
dex_pc, resolved_method, &clinit_check_requirement);
} else if (invoke_type == kSuper) {
if (IsSameDexFile(*resolved_method->GetDexFile(), *dex_compilation_unit_->GetDexFile())) {
// Update the method index to the one resolved. Note that this may be a no-op if
// we resolved to the method referenced by the instruction.
method_idx = resolved_method->GetDexMethodIndex();
}
}
HInvokeStaticOrDirect::DispatchInfo dispatch_info = {
HInvokeStaticOrDirect::MethodLoadKind::kRuntimeCall,
HInvokeStaticOrDirect::CodePtrLocation::kCallArtMethod,
0u
};
MethodReference target_method(resolved_method->GetDexFile(),
resolved_method->GetDexMethodIndex());
invoke = new (allocator_) HInvokeStaticOrDirect(allocator_,
number_of_arguments,
return_type,
dex_pc,
method_idx,
resolved_method,
dispatch_info,
invoke_type,
target_method,
clinit_check_requirement);
} else if (invoke_type == kVirtual) {
ScopedObjectAccess soa(Thread::Current()); // Needed for the method index
invoke = new (allocator_) HInvokeVirtual(allocator_,
number_of_arguments,
return_type,
dex_pc,
method_idx,
resolved_method,
resolved_method->GetMethodIndex());
} else {
DCHECK_EQ(invoke_type, kInterface);
ScopedObjectAccess soa(Thread::Current()); // Needed for the IMT index.
invoke = new (allocator_) HInvokeInterface(allocator_,
number_of_arguments,
return_type,
dex_pc,
method_idx,
resolved_method,
ImTable::GetImtIndex(resolved_method));
}
return HandleInvoke(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor,
clinit_check,
false /* is_unresolved */);
}
bool HInstructionBuilder::BuildInvokePolymorphic(const Instruction& instruction ATTRIBUTE_UNUSED,
uint32_t dex_pc,
uint32_t method_idx,
uint32_t proto_idx,
uint32_t number_of_vreg_arguments,
bool is_range,
uint32_t* args,
uint32_t register_index) {
const char* descriptor = dex_file_->GetShorty(proto_idx);
DCHECK_EQ(1 + ArtMethod::NumArgRegisters(descriptor), number_of_vreg_arguments);
DataType::Type return_type = DataType::FromShorty(descriptor[0]);
size_t number_of_arguments = strlen(descriptor);
HInvoke* invoke = new (allocator_) HInvokePolymorphic(allocator_,
number_of_arguments,
return_type,
dex_pc,
method_idx);
return HandleInvoke(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor,
nullptr /* clinit_check */,
false /* is_unresolved */);
}
HNewInstance* HInstructionBuilder::BuildNewInstance(dex::TypeIndex type_index, uint32_t dex_pc) {
ScopedObjectAccess soa(Thread::Current());
HLoadClass* load_class = BuildLoadClass(type_index, dex_pc);
HInstruction* cls = load_class;
Handle<mirror::Class> klass = load_class->GetClass();
if (!IsInitialized(klass)) {
cls = new (allocator_) HClinitCheck(load_class, dex_pc);
AppendInstruction(cls);
}
// Only the access check entrypoint handles the finalizable class case. If we
// need access checks, then we haven't resolved the method and the class may
// again be finalizable.
QuickEntrypointEnum entrypoint = kQuickAllocObjectInitialized;
if (load_class->NeedsAccessCheck() || klass->IsFinalizable() || !klass->IsInstantiable()) {
entrypoint = kQuickAllocObjectWithChecks;
}
// Consider classes we haven't resolved as potentially finalizable.
bool finalizable = (klass == nullptr) || klass->IsFinalizable();
HNewInstance* new_instance = new (allocator_) HNewInstance(
cls,
dex_pc,
type_index,
*dex_compilation_unit_->GetDexFile(),
finalizable,
entrypoint);
AppendInstruction(new_instance);
return new_instance;
}
void HInstructionBuilder::BuildConstructorFenceForAllocation(HInstruction* allocation) {
DCHECK(allocation != nullptr &&
(allocation->IsNewInstance() ||
allocation->IsNewArray())); // corresponding to "new" keyword in JLS.
if (allocation->IsNewInstance()) {
// STRING SPECIAL HANDLING:
// -------------------------------
// Strings have a real HNewInstance node but they end up always having 0 uses.
// All uses of a String HNewInstance are always transformed to replace their input
// of the HNewInstance with an input of the invoke to StringFactory.
//
// Do not emit an HConstructorFence here since it can inhibit some String new-instance
// optimizations (to pass checker tests that rely on those optimizations).
HNewInstance* new_inst = allocation->AsNewInstance();
HLoadClass* load_class = new_inst->GetLoadClass();
Thread* self = Thread::Current();
ScopedObjectAccess soa(self);
StackHandleScope<1> hs(self);
Handle<mirror::Class> klass = load_class->GetClass();
if (klass != nullptr && klass->IsStringClass()) {
return;
// Note: Do not use allocation->IsStringAlloc which requires
// a valid ReferenceTypeInfo, but that doesn't get made until after reference type
// propagation (and instruction builder is too early).
}
// (In terms of correctness, the StringFactory needs to provide its own
// default initialization barrier, see below.)
}
// JLS 17.4.5 "Happens-before Order" describes:
//
// The default initialization of any object happens-before any other actions (other than
// default-writes) of a program.
//
// In our implementation the default initialization of an object to type T means
// setting all of its initial data (object[0..size)) to 0, and setting the
// object's class header (i.e. object.getClass() == T.class).
//
// In practice this fence ensures that the writes to the object header
// are visible to other threads if this object escapes the current thread.
// (and in theory the 0-initializing, but that happens automatically
// when new memory pages are mapped in by the OS).
HConstructorFence* ctor_fence =
new (allocator_) HConstructorFence(allocation, allocation->GetDexPc(), allocator_);
AppendInstruction(ctor_fence);
MaybeRecordStat(
compilation_stats_,
MethodCompilationStat::kConstructorFenceGeneratedNew);
}
static bool IsSubClass(mirror::Class* to_test, mirror::Class* super_class)
REQUIRES_SHARED(Locks::mutator_lock_) {
return to_test != nullptr && !to_test->IsInterface() && to_test->IsSubClass(super_class);
}
bool HInstructionBuilder::IsInitialized(Handle<mirror::Class> cls) const {
if (cls == nullptr) {
return false;
}
// `CanAssumeClassIsLoaded` will return true if we're JITting, or will
// check whether the class is in an image for the AOT compilation.
if (cls->IsInitialized() &&
compiler_driver_->CanAssumeClassIsLoaded(cls.Get())) {
return true;
}
if (IsSubClass(GetOutermostCompilingClass(), cls.Get())) {
return true;
}
// TODO: We should walk over the inlined methods, but we don't pass
// that information to the builder.
if (IsSubClass(GetCompilingClass(), cls.Get())) {
return true;
}
return false;
}
HClinitCheck* HInstructionBuilder::ProcessClinitCheckForInvoke(
uint32_t dex_pc,
ArtMethod* resolved_method,
HInvokeStaticOrDirect::ClinitCheckRequirement* clinit_check_requirement) {
Handle<mirror::Class> klass = handles_->NewHandle(resolved_method->GetDeclaringClass());
HClinitCheck* clinit_check = nullptr;
if (IsInitialized(klass)) {
*clinit_check_requirement = HInvokeStaticOrDirect::ClinitCheckRequirement::kNone;
} else {
HLoadClass* cls = BuildLoadClass(klass->GetDexTypeIndex(),
klass->GetDexFile(),
klass,
dex_pc,
/* needs_access_check */ false);
if (cls != nullptr) {
*clinit_check_requirement = HInvokeStaticOrDirect::ClinitCheckRequirement::kExplicit;
clinit_check = new (allocator_) HClinitCheck(cls, dex_pc);
AppendInstruction(clinit_check);
}
}
return clinit_check;
}
bool HInstructionBuilder::SetupInvokeArguments(HInvoke* invoke,
uint32_t number_of_vreg_arguments,
uint32_t* args,
uint32_t register_index,
bool is_range,
const char* descriptor,
size_t start_index,
size_t* argument_index) {
uint32_t descriptor_index = 1; // Skip the return type.
for (size_t i = start_index;
// Make sure we don't go over the expected arguments or over the number of
// dex registers given. If the instruction was seen as dead by the verifier,
// it hasn't been properly checked.
(i < number_of_vreg_arguments) && (*argument_index < invoke->GetNumberOfArguments());
i++, (*argument_index)++) {
DataType::Type type = DataType::FromShorty(descriptor[descriptor_index++]);
bool is_wide = (type == DataType::Type::kInt64) || (type == DataType::Type::kFloat64);
if (!is_range
&& is_wide
&& ((i + 1 == number_of_vreg_arguments) || (args[i] + 1 != args[i + 1]))) {
// Longs and doubles should be in pairs, that is, sequential registers. The verifier should
// reject any class where this is violated. However, the verifier only does these checks
// on non trivially dead instructions, so we just bailout the compilation.
VLOG(compiler) << "Did not compile "
<< dex_file_->PrettyMethod(dex_compilation_unit_->GetDexMethodIndex())
<< " because of non-sequential dex register pair in wide argument";
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kNotCompiledMalformedOpcode);
return false;
}
HInstruction* arg = LoadLocal(is_range ? register_index + i : args[i], type);
invoke->SetArgumentAt(*argument_index, arg);
if (is_wide) {
i++;
}
}
if (*argument_index != invoke->GetNumberOfArguments()) {
VLOG(compiler) << "Did not compile "
<< dex_file_->PrettyMethod(dex_compilation_unit_->GetDexMethodIndex())
<< " because of wrong number of arguments in invoke instruction";
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kNotCompiledMalformedOpcode);
return false;
}
if (invoke->IsInvokeStaticOrDirect() &&
HInvokeStaticOrDirect::NeedsCurrentMethodInput(
invoke->AsInvokeStaticOrDirect()->GetMethodLoadKind())) {
invoke->SetArgumentAt(*argument_index, graph_->GetCurrentMethod());
(*argument_index)++;
}
return true;
}
bool HInstructionBuilder::HandleInvoke(HInvoke* invoke,
uint32_t number_of_vreg_arguments,
uint32_t* args,
uint32_t register_index,
bool is_range,
const char* descriptor,
HClinitCheck* clinit_check,
bool is_unresolved) {
DCHECK(!invoke->IsInvokeStaticOrDirect() || !invoke->AsInvokeStaticOrDirect()->IsStringInit());
size_t start_index = 0;
size_t argument_index = 0;
if (invoke->GetInvokeType() != InvokeType::kStatic) { // Instance call.
uint32_t obj_reg = is_range ? register_index : args[0];
HInstruction* arg = is_unresolved
? LoadLocal(obj_reg, DataType::Type::kReference)
: LoadNullCheckedLocal(obj_reg, invoke->GetDexPc());
invoke->SetArgumentAt(0, arg);
start_index = 1;
argument_index = 1;
}
if (!SetupInvokeArguments(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor,
start_index,
&argument_index)) {
return false;
}
if (clinit_check != nullptr) {
// Add the class initialization check as last input of `invoke`.
DCHECK(invoke->IsInvokeStaticOrDirect());
DCHECK(invoke->AsInvokeStaticOrDirect()->GetClinitCheckRequirement()
== HInvokeStaticOrDirect::ClinitCheckRequirement::kExplicit);
invoke->SetArgumentAt(argument_index, clinit_check);
argument_index++;
}
AppendInstruction(invoke);
latest_result_ = invoke;
return true;
}
bool HInstructionBuilder::HandleStringInit(HInvoke* invoke,
uint32_t number_of_vreg_arguments,
uint32_t* args,
uint32_t register_index,
bool is_range,
const char* descriptor) {
DCHECK(invoke->IsInvokeStaticOrDirect());
DCHECK(invoke->AsInvokeStaticOrDirect()->IsStringInit());
size_t start_index = 1;
size_t argument_index = 0;
if (!SetupInvokeArguments(invoke,
number_of_vreg_arguments,
args,
register_index,
is_range,
descriptor,
start_index,
&argument_index)) {
return false;
}
AppendInstruction(invoke);
// This is a StringFactory call, not an actual String constructor. Its result
// replaces the empty String pre-allocated by NewInstance.
uint32_t orig_this_reg = is_range ? register_index : args[0];
HInstruction* arg_this = LoadLocal(orig_this_reg, DataType::Type::kReference);
// Replacing the NewInstance might render it redundant. Keep a list of these
// to be visited once it is clear whether it is has remaining uses.
if (arg_this->IsNewInstance()) {
ssa_builder_->AddUninitializedString(arg_this->AsNewInstance());
} else {
DCHECK(arg_this->IsPhi());
// NewInstance is not the direct input of the StringFactory call. It might
// be redundant but optimizing this case is not worth the effort.
}
// Walk over all vregs and replace any occurrence of `arg_this` with `invoke`.
for (size_t vreg = 0, e = current_locals_->size(); vreg < e; ++vreg) {
if ((*current_locals_)[vreg] == arg_this) {
(*current_locals_)[vreg] = invoke;
}
}
return true;
}
static DataType::Type GetFieldAccessType(const DexFile& dex_file, uint16_t field_index) {
const DexFile::FieldId& field_id = dex_file.GetFieldId(field_index);
const char* type = dex_file.GetFieldTypeDescriptor(field_id);
return DataType::FromShorty(type[0]);
}
bool HInstructionBuilder::BuildInstanceFieldAccess(const Instruction& instruction,
uint32_t dex_pc,
bool is_put,
size_t quicken_index) {
uint32_t source_or_dest_reg = instruction.VRegA_22c();
uint32_t obj_reg = instruction.VRegB_22c();
uint16_t field_index;
if (instruction.IsQuickened()) {
if (!CanDecodeQuickenedInfo()) {
return false;
}
field_index = LookupQuickenedInfo(quicken_index);
} else {
field_index = instruction.VRegC_22c();
}
ScopedObjectAccess soa(Thread::Current());
ArtField* resolved_field = ResolveField(field_index, /* is_static */ false, is_put);
// Generate an explicit null check on the reference, unless the field access
// is unresolved. In that case, we rely on the runtime to perform various
// checks first, followed by a null check.
HInstruction* object = (resolved_field == nullptr)
? LoadLocal(obj_reg, DataType::Type::kReference)
: LoadNullCheckedLocal(obj_reg, dex_pc);
DataType::Type field_type = GetFieldAccessType(*dex_file_, field_index);
if (is_put) {
HInstruction* value = LoadLocal(source_or_dest_reg, field_type);
HInstruction* field_set = nullptr;
if (resolved_field == nullptr) {
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kUnresolvedField);
field_set = new (allocator_) HUnresolvedInstanceFieldSet(object,
value,
field_type,
field_index,
dex_pc);
} else {
uint16_t class_def_index = resolved_field->GetDeclaringClass()->GetDexClassDefIndex();
field_set = new (allocator_) HInstanceFieldSet(object,
value,
resolved_field,
field_type,
resolved_field->GetOffset(),
resolved_field->IsVolatile(),
field_index,
class_def_index,
*dex_file_,
dex_pc);
}
AppendInstruction(field_set);
} else {
HInstruction* field_get = nullptr;
if (resolved_field == nullptr) {
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kUnresolvedField);
field_get = new (allocator_) HUnresolvedInstanceFieldGet(object,
field_type,
field_index,
dex_pc);
} else {
uint16_t class_def_index = resolved_field->GetDeclaringClass()->GetDexClassDefIndex();
field_get = new (allocator_) HInstanceFieldGet(object,
resolved_field,
field_type,
resolved_field->GetOffset(),
resolved_field->IsVolatile(),
field_index,
class_def_index,
*dex_file_,
dex_pc);
}
AppendInstruction(field_get);
UpdateLocal(source_or_dest_reg, field_get);
}
return true;
}
static mirror::Class* GetClassFrom(CompilerDriver* driver,
const DexCompilationUnit& compilation_unit) {
ScopedObjectAccess soa(Thread::Current());
Handle<mirror::ClassLoader> class_loader = compilation_unit.GetClassLoader();
Handle<mirror::DexCache> dex_cache = compilation_unit.GetDexCache();
return driver->ResolveCompilingMethodsClass(soa, dex_cache, class_loader, &compilation_unit);
}
mirror::Class* HInstructionBuilder::GetOutermostCompilingClass() const {
return GetClassFrom(compiler_driver_, *outer_compilation_unit_);
}
mirror::Class* HInstructionBuilder::GetCompilingClass() const {
return GetClassFrom(compiler_driver_, *dex_compilation_unit_);
}
bool HInstructionBuilder::IsOutermostCompilingClass(dex::TypeIndex type_index) const {
ScopedObjectAccess soa(Thread::Current());
StackHandleScope<2> hs(soa.Self());
Handle<mirror::DexCache> dex_cache = dex_compilation_unit_->GetDexCache();
Handle<mirror::ClassLoader> class_loader = dex_compilation_unit_->GetClassLoader();
Handle<mirror::Class> cls(hs.NewHandle(compiler_driver_->ResolveClass(
soa, dex_cache, class_loader, type_index, dex_compilation_unit_)));
Handle<mirror::Class> outer_class(hs.NewHandle(GetOutermostCompilingClass()));
// GetOutermostCompilingClass returns null when the class is unresolved
// (e.g. if it derives from an unresolved class). This is bogus knowing that
// we are compiling it.
// When this happens we cannot establish a direct relation between the current
// class and the outer class, so we return false.
// (Note that this is only used for optimizing invokes and field accesses)
return (cls != nullptr) && (outer_class.Get() == cls.Get());
}
void HInstructionBuilder::BuildUnresolvedStaticFieldAccess(const Instruction& instruction,
uint32_t dex_pc,
bool is_put,
DataType::Type field_type) {
uint32_t source_or_dest_reg = instruction.VRegA_21c();
uint16_t field_index = instruction.VRegB_21c();
if (is_put) {
HInstruction* value = LoadLocal(source_or_dest_reg, field_type);
AppendInstruction(
new (allocator_) HUnresolvedStaticFieldSet(value, field_type, field_index, dex_pc));
} else {
AppendInstruction(new (allocator_) HUnresolvedStaticFieldGet(field_type, field_index, dex_pc));
UpdateLocal(source_or_dest_reg, current_block_->GetLastInstruction());
}
}
ArtField* HInstructionBuilder::ResolveField(uint16_t field_idx, bool is_static, bool is_put) {
ScopedObjectAccess soa(Thread::Current());
StackHandleScope<2> hs(soa.Self());
ClassLinker* class_linker = dex_compilation_unit_->GetClassLinker();
Handle<mirror::ClassLoader> class_loader = dex_compilation_unit_->GetClassLoader();
Handle<mirror::Class> compiling_class(hs.NewHandle(GetCompilingClass()));
ArtField* resolved_field = class_linker->ResolveField(*dex_compilation_unit_->GetDexFile(),
field_idx,
dex_compilation_unit_->GetDexCache(),
class_loader,
is_static);
if (UNLIKELY(resolved_field == nullptr)) {
// Clean up any exception left by type resolution.
soa.Self()->ClearException();
return nullptr;
}
// Check static/instance. The class linker has a fast path for looking into the dex cache
// and does not check static/instance if it hits it.
if (UNLIKELY(resolved_field->IsStatic() != is_static)) {
return nullptr;
}
// Check access.
if (compiling_class == nullptr) {
if (!resolved_field->IsPublic()) {
return nullptr;
}
} else if (!compiling_class->CanAccessResolvedField(resolved_field->GetDeclaringClass(),
resolved_field,
dex_compilation_unit_->GetDexCache().Get(),
field_idx)) {
return nullptr;
}
if (is_put &&
resolved_field->IsFinal() &&
(compiling_class.Get() != resolved_field->GetDeclaringClass())) {
// Final fields can only be updated within their own class.
// TODO: Only allow it in constructors. b/34966607.
return nullptr;
}
return resolved_field;
}
bool HInstructionBuilder::BuildStaticFieldAccess(const Instruction& instruction,
uint32_t dex_pc,
bool is_put) {
uint32_t source_or_dest_reg = instruction.VRegA_21c();
uint16_t field_index = instruction.VRegB_21c();
ScopedObjectAccess soa(Thread::Current());
ArtField* resolved_field = ResolveField(field_index, /* is_static */ true, is_put);
if (resolved_field == nullptr) {
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kUnresolvedField);
DataType::Type field_type = GetFieldAccessType(*dex_file_, field_index);
BuildUnresolvedStaticFieldAccess(instruction, dex_pc, is_put, field_type);
return true;
}
DataType::Type field_type = GetFieldAccessType(*dex_file_, field_index);
Handle<mirror::Class> klass = handles_->NewHandle(resolved_field->GetDeclaringClass());
HLoadClass* constant = BuildLoadClass(klass->GetDexTypeIndex(),
klass->GetDexFile(),
klass,
dex_pc,
/* needs_access_check */ false);
if (constant == nullptr) {
// The class cannot be referenced from this compiled code. Generate
// an unresolved access.
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kUnresolvedFieldNotAFastAccess);
BuildUnresolvedStaticFieldAccess(instruction, dex_pc, is_put, field_type);
return true;
}
HInstruction* cls = constant;
if (!IsInitialized(klass)) {
cls = new (allocator_) HClinitCheck(constant, dex_pc);
AppendInstruction(cls);
}
uint16_t class_def_index = klass->GetDexClassDefIndex();
if (is_put) {
// We need to keep the class alive before loading the value.
HInstruction* value = LoadLocal(source_or_dest_reg, field_type);
DCHECK_EQ(HPhi::ToPhiType(value->GetType()), HPhi::ToPhiType(field_type));
AppendInstruction(new (allocator_) HStaticFieldSet(cls,
value,
resolved_field,
field_type,
resolved_field->GetOffset(),
resolved_field->IsVolatile(),
field_index,
class_def_index,
*dex_file_,
dex_pc));
} else {
AppendInstruction(new (allocator_) HStaticFieldGet(cls,
resolved_field,
field_type,
resolved_field->GetOffset(),
resolved_field->IsVolatile(),
field_index,
class_def_index,
*dex_file_,
dex_pc));
UpdateLocal(source_or_dest_reg, current_block_->GetLastInstruction());
}
return true;
}
void HInstructionBuilder::BuildCheckedDivRem(uint16_t out_vreg,
uint16_t first_vreg,
int64_t second_vreg_or_constant,
uint32_t dex_pc,
DataType::Type type,
bool second_is_constant,
bool isDiv) {
DCHECK(type == DataType::Type::kInt32 || type == DataType::Type::kInt64);
HInstruction* first = LoadLocal(first_vreg, type);
HInstruction* second = nullptr;
if (second_is_constant) {
if (type == DataType::Type::kInt32) {
second = graph_->GetIntConstant(second_vreg_or_constant, dex_pc);
} else {
second = graph_->GetLongConstant(second_vreg_or_constant, dex_pc);
}
} else {
second = LoadLocal(second_vreg_or_constant, type);
}
if (!second_is_constant
|| (type == DataType::Type::kInt32 && second->AsIntConstant()->GetValue() == 0)
|| (type == DataType::Type::kInt64 && second->AsLongConstant()->GetValue() == 0)) {
second = new (allocator_) HDivZeroCheck(second, dex_pc);
AppendInstruction(second);
}
if (isDiv) {
AppendInstruction(new (allocator_) HDiv(type, first, second, dex_pc));
} else {
AppendInstruction(new (allocator_) HRem(type, first, second, dex_pc));
}
UpdateLocal(out_vreg, current_block_->GetLastInstruction());
}
void HInstructionBuilder::BuildArrayAccess(const Instruction& instruction,
uint32_t dex_pc,
bool is_put,
DataType::Type anticipated_type) {
uint8_t source_or_dest_reg = instruction.VRegA_23x();
uint8_t array_reg = instruction.VRegB_23x();
uint8_t index_reg = instruction.VRegC_23x();
HInstruction* object = LoadNullCheckedLocal(array_reg, dex_pc);
HInstruction* length = new (allocator_) HArrayLength(object, dex_pc);
AppendInstruction(length);
HInstruction* index = LoadLocal(index_reg, DataType::Type::kInt32);
index = new (allocator_) HBoundsCheck(index, length, dex_pc);
AppendInstruction(index);
if (is_put) {
HInstruction* value = LoadLocal(source_or_dest_reg, anticipated_type);
// TODO: Insert a type check node if the type is Object.
HArraySet* aset = new (allocator_) HArraySet(object, index, value, anticipated_type, dex_pc);
ssa_builder_->MaybeAddAmbiguousArraySet(aset);
AppendInstruction(aset);
} else {
HArrayGet* aget = new (allocator_) HArrayGet(object, index, anticipated_type, dex_pc);
ssa_builder_->MaybeAddAmbiguousArrayGet(aget);
AppendInstruction(aget);
UpdateLocal(source_or_dest_reg, current_block_->GetLastInstruction());
}
graph_->SetHasBoundsChecks(true);
}
HNewArray* HInstructionBuilder::BuildFilledNewArray(uint32_t dex_pc,
dex::TypeIndex type_index,
uint32_t number_of_vreg_arguments,
bool is_range,
uint32_t* args,
uint32_t register_index) {
HInstruction* length = graph_->GetIntConstant(number_of_vreg_arguments, dex_pc);
HLoadClass* cls = BuildLoadClass(type_index, dex_pc);
HNewArray* const object = new (allocator_) HNewArray(cls, length, dex_pc);
AppendInstruction(object);
const char* descriptor = dex_file_->StringByTypeIdx(type_index);
DCHECK_EQ(descriptor[0], '[') << descriptor;
char primitive = descriptor[1];
DCHECK(primitive == 'I'
|| primitive == 'L'
|| primitive == '[') << descriptor;
bool is_reference_array = (primitive == 'L') || (primitive == '[');
DataType::Type type = is_reference_array ? DataType::Type::kReference : DataType::Type::kInt32;
for (size_t i = 0; i < number_of_vreg_arguments; ++i) {
HInstruction* value = LoadLocal(is_range ? register_index + i : args[i], type);
HInstruction* index = graph_->GetIntConstant(i, dex_pc);
HArraySet* aset = new (allocator_) HArraySet(object, index, value, type, dex_pc);
ssa_builder_->MaybeAddAmbiguousArraySet(aset);
AppendInstruction(aset);
}
latest_result_ = object;
return object;
}
template <typename T>
void HInstructionBuilder::BuildFillArrayData(HInstruction* object,
const T* data,
uint32_t element_count,
DataType::Type anticipated_type,
uint32_t dex_pc) {
for (uint32_t i = 0; i < element_count; ++i) {
HInstruction* index = graph_->GetIntConstant(i, dex_pc);
HInstruction* value = graph_->GetIntConstant(data[i], dex_pc);
HArraySet* aset = new (allocator_) HArraySet(object, index, value, anticipated_type, dex_pc);
ssa_builder_->MaybeAddAmbiguousArraySet(aset);
AppendInstruction(aset);
}
}
void HInstructionBuilder::BuildFillArrayData(const Instruction& instruction, uint32_t dex_pc) {
HInstruction* array = LoadNullCheckedLocal(instruction.VRegA_31t(), dex_pc);
int32_t payload_offset = instruction.VRegB_31t() + dex_pc;
const Instruction::ArrayDataPayload* payload =
reinterpret_cast<const Instruction::ArrayDataPayload*>(code_item_.insns_ + payload_offset);
const uint8_t* data = payload->data;
uint32_t element_count = payload->element_count;
if (element_count == 0u) {
// For empty payload we emit only the null check above.
return;
}
HInstruction* length = new (allocator_) HArrayLength(array, dex_pc);
AppendInstruction(length);
// Implementation of this DEX instruction seems to be that the bounds check is
// done before doing any stores.
HInstruction* last_index = graph_->GetIntConstant(payload->element_count - 1, dex_pc);
AppendInstruction(new (allocator_) HBoundsCheck(last_index, length, dex_pc));
switch (payload->element_width) {
case 1:
BuildFillArrayData(array,
reinterpret_cast<const int8_t*>(data),
element_count,
DataType::Type::kInt8,
dex_pc);
break;
case 2:
BuildFillArrayData(array,
reinterpret_cast<const int16_t*>(data),
element_count,
DataType::Type::kInt16,
dex_pc);
break;
case 4:
BuildFillArrayData(array,
reinterpret_cast<const int32_t*>(data),
element_count,
DataType::Type::kInt32,
dex_pc);
break;
case 8:
BuildFillWideArrayData(array,
reinterpret_cast<const int64_t*>(data),
element_count,
dex_pc);
break;
default:
LOG(FATAL) << "Unknown element width for " << payload->element_width;
}
graph_->SetHasBoundsChecks(true);
}
void HInstructionBuilder::BuildFillWideArrayData(HInstruction* object,
const int64_t* data,
uint32_t element_count,
uint32_t dex_pc) {
for (uint32_t i = 0; i < element_count; ++i) {
HInstruction* index = graph_->GetIntConstant(i, dex_pc);
HInstruction* value = graph_->GetLongConstant(data[i], dex_pc);
HArraySet* aset =
new (allocator_) HArraySet(object, index, value, DataType::Type::kInt64, dex_pc);
ssa_builder_->MaybeAddAmbiguousArraySet(aset);
AppendInstruction(aset);
}
}
static TypeCheckKind ComputeTypeCheckKind(Handle<mirror::Class> cls)
REQUIRES_SHARED(Locks::mutator_lock_) {
if (cls == nullptr) {
return TypeCheckKind::kUnresolvedCheck;
} else if (cls->IsInterface()) {
return TypeCheckKind::kInterfaceCheck;
} else if (cls->IsArrayClass()) {
if (cls->GetComponentType()->IsObjectClass()) {
return TypeCheckKind::kArrayObjectCheck;
} else if (cls->CannotBeAssignedFromOtherTypes()) {
return TypeCheckKind::kExactCheck;
} else {
return TypeCheckKind::kArrayCheck;
}
} else if (cls->IsFinal()) {
return TypeCheckKind::kExactCheck;
} else if (cls->IsAbstract()) {
return TypeCheckKind::kAbstractClassCheck;
} else {
return TypeCheckKind::kClassHierarchyCheck;
}
}
HLoadClass* HInstructionBuilder::BuildLoadClass(dex::TypeIndex type_index, uint32_t dex_pc) {
ScopedObjectAccess soa(Thread::Current());
const DexFile& dex_file = *dex_compilation_unit_->GetDexFile();
Handle<mirror::ClassLoader> class_loader = dex_compilation_unit_->GetClassLoader();
Handle<mirror::Class> klass = handles_->NewHandle(compiler_driver_->ResolveClass(
soa, dex_compilation_unit_->GetDexCache(), class_loader, type_index, dex_compilation_unit_));
bool needs_access_check = true;
if (klass != nullptr) {
if (klass->IsPublic()) {
needs_access_check = false;
} else {
mirror::Class* compiling_class = GetCompilingClass();
if (compiling_class != nullptr && compiling_class->CanAccess(klass.Get())) {
needs_access_check = false;
}
}
}
return BuildLoadClass(type_index, dex_file, klass, dex_pc, needs_access_check);
}
HLoadClass* HInstructionBuilder::BuildLoadClass(dex::TypeIndex type_index,
const DexFile& dex_file,
Handle<mirror::Class> klass,
uint32_t dex_pc,
bool needs_access_check) {
// Try to find a reference in the compiling dex file.
const DexFile* actual_dex_file = &dex_file;
if (!IsSameDexFile(dex_file, *dex_compilation_unit_->GetDexFile())) {
dex::TypeIndex local_type_index =
klass->FindTypeIndexInOtherDexFile(*dex_compilation_unit_->GetDexFile());
if (local_type_index.IsValid()) {
type_index = local_type_index;
actual_dex_file = dex_compilation_unit_->GetDexFile();
}
}
// Note: `klass` must be from `handles_`.
HLoadClass* load_class = new (allocator_) HLoadClass(
graph_->GetCurrentMethod(),
type_index,
*actual_dex_file,
klass,
klass != nullptr && (klass.Get() == GetOutermostCompilingClass()),
dex_pc,
needs_access_check);
HLoadClass::LoadKind load_kind = HSharpening::ComputeLoadClassKind(load_class,
code_generator_,
compiler_driver_,
*dex_compilation_unit_);
if (load_kind == HLoadClass::LoadKind::kInvalid) {
// We actually cannot reference this class, we're forced to bail.
return nullptr;
}
// Append the instruction first, as setting the load kind affects the inputs.
AppendInstruction(load_class);
load_class->SetLoadKind(load_kind);
return load_class;
}
void HInstructionBuilder::BuildTypeCheck(const Instruction& instruction,
uint8_t destination,
uint8_t reference,
dex::TypeIndex type_index,
uint32_t dex_pc) {
HInstruction* object = LoadLocal(reference, DataType::Type::kReference);
HLoadClass* cls = BuildLoadClass(type_index, dex_pc);
ScopedObjectAccess soa(Thread::Current());
TypeCheckKind check_kind = ComputeTypeCheckKind(cls->GetClass());
if (instruction.Opcode() == Instruction::INSTANCE_OF) {
AppendInstruction(new (allocator_) HInstanceOf(object, cls, check_kind, dex_pc));
UpdateLocal(destination, current_block_->GetLastInstruction());
} else {
DCHECK_EQ(instruction.Opcode(), Instruction::CHECK_CAST);
// We emit a CheckCast followed by a BoundType. CheckCast is a statement
// which may throw. If it succeeds BoundType sets the new type of `object`
// for all subsequent uses.
AppendInstruction(new (allocator_) HCheckCast(object, cls, check_kind, dex_pc));
AppendInstruction(new (allocator_) HBoundType(object, dex_pc));
UpdateLocal(reference, current_block_->GetLastInstruction());
}
}
bool HInstructionBuilder::NeedsAccessCheck(dex::TypeIndex type_index, bool* finalizable) const {
return !compiler_driver_->CanAccessInstantiableTypeWithoutChecks(
LookupReferrerClass(), LookupResolvedType(type_index, *dex_compilation_unit_), finalizable);
}
bool HInstructionBuilder::CanDecodeQuickenedInfo() const {
return !quicken_info_.IsNull();
}
uint16_t HInstructionBuilder::LookupQuickenedInfo(uint32_t quicken_index) {
DCHECK(CanDecodeQuickenedInfo());
return quicken_info_.GetData(quicken_index);
}
bool HInstructionBuilder::ProcessDexInstruction(const Instruction& instruction,
uint32_t dex_pc,
size_t quicken_index) {
switch (instruction.Opcode()) {
case Instruction::CONST_4: {
int32_t register_index = instruction.VRegA();
HIntConstant* constant = graph_->GetIntConstant(instruction.VRegB_11n(), dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_16: {
int32_t register_index = instruction.VRegA();
HIntConstant* constant = graph_->GetIntConstant(instruction.VRegB_21s(), dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST: {
int32_t register_index = instruction.VRegA();
HIntConstant* constant = graph_->GetIntConstant(instruction.VRegB_31i(), dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_HIGH16: {
int32_t register_index = instruction.VRegA();
HIntConstant* constant = graph_->GetIntConstant(instruction.VRegB_21h() << 16, dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_WIDE_16: {
int32_t register_index = instruction.VRegA();
// Get 16 bits of constant value, sign extended to 64 bits.
int64_t value = instruction.VRegB_21s();
value <<= 48;
value >>= 48;
HLongConstant* constant = graph_->GetLongConstant(value, dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_WIDE_32: {
int32_t register_index = instruction.VRegA();
// Get 32 bits of constant value, sign extended to 64 bits.
int64_t value = instruction.VRegB_31i();
value <<= 32;
value >>= 32;
HLongConstant* constant = graph_->GetLongConstant(value, dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_WIDE: {
int32_t register_index = instruction.VRegA();
HLongConstant* constant = graph_->GetLongConstant(instruction.VRegB_51l(), dex_pc);
UpdateLocal(register_index, constant);
break;
}
case Instruction::CONST_WIDE_HIGH16: {
int32_t register_index = instruction.VRegA();
int64_t value = static_cast<int64_t>(instruction.VRegB_21h()) << 48;
HLongConstant* constant = graph_->GetLongConstant(value, dex_pc);
UpdateLocal(register_index, constant);
break;
}
// Note that the SSA building will refine the types.
case Instruction::MOVE:
case Instruction::MOVE_FROM16:
case Instruction::MOVE_16: {
HInstruction* value = LoadLocal(instruction.VRegB(), DataType::Type::kInt32);
UpdateLocal(instruction.VRegA(), value);
break;
}
// Note that the SSA building will refine the types.
case Instruction::MOVE_WIDE:
case Instruction::MOVE_WIDE_FROM16:
case Instruction::MOVE_WIDE_16: {
HInstruction* value = LoadLocal(instruction.VRegB(), DataType::Type::kInt64);
UpdateLocal(instruction.VRegA(), value);
break;
}
case Instruction::MOVE_OBJECT:
case Instruction::MOVE_OBJECT_16:
case Instruction::MOVE_OBJECT_FROM16: {
// The verifier has no notion of a null type, so a move-object of constant 0
// will lead to the same constant 0 in the destination register. To mimic
// this behavior, we just pretend we haven't seen a type change (int to reference)
// for the 0 constant and phis. We rely on our type propagation to eventually get the
// types correct.
uint32_t reg_number = instruction.VRegB();
HInstruction* value = (*current_locals_)[reg_number];
if (value->IsIntConstant()) {
DCHECK_EQ(value->AsIntConstant()->GetValue(), 0);
} else if (value->IsPhi()) {
DCHECK(value->GetType() == DataType::Type::kInt32 ||
value->GetType() == DataType::Type::kReference);
} else {
value = LoadLocal(reg_number, DataType::Type::kReference);
}
UpdateLocal(instruction.VRegA(), value);
break;
}
case Instruction::RETURN_VOID_NO_BARRIER:
case Instruction::RETURN_VOID: {
BuildReturn(instruction, DataType::Type::kVoid, dex_pc);
break;
}
#define IF_XX(comparison, cond) \
case Instruction::IF_##cond: If_22t<comparison>(instruction, dex_pc); break; \
case Instruction::IF_##cond##Z: If_21t<comparison>(instruction, dex_pc); break
IF_XX(HEqual, EQ);
IF_XX(HNotEqual, NE);
IF_XX(HLessThan, LT);
IF_XX(HLessThanOrEqual, LE);
IF_XX(HGreaterThan, GT);
IF_XX(HGreaterThanOrEqual, GE);
case Instruction::GOTO:
case Instruction::GOTO_16:
case Instruction::GOTO_32: {
AppendInstruction(new (allocator_) HGoto(dex_pc));
current_block_ = nullptr;
break;
}
case Instruction::RETURN: {
BuildReturn(instruction, return_type_, dex_pc);
break;
}
case Instruction::RETURN_OBJECT: {
BuildReturn(instruction, return_type_, dex_pc);
break;
}
case Instruction::RETURN_WIDE: {
BuildReturn(instruction, return_type_, dex_pc);
break;
}
case Instruction::INVOKE_DIRECT:
case Instruction::INVOKE_INTERFACE:
case Instruction::INVOKE_STATIC:
case Instruction::INVOKE_SUPER:
case Instruction::INVOKE_VIRTUAL:
case Instruction::INVOKE_VIRTUAL_QUICK: {
uint16_t method_idx;
if (instruction.Opcode() == Instruction::INVOKE_VIRTUAL_QUICK) {
if (!CanDecodeQuickenedInfo()) {
return false;
}
method_idx = LookupQuickenedInfo(quicken_index);
} else {
method_idx = instruction.VRegB_35c();
}
uint32_t number_of_vreg_arguments = instruction.VRegA_35c();
uint32_t args[5];
instruction.GetVarArgs(args);
if (!BuildInvoke(instruction, dex_pc, method_idx,
number_of_vreg_arguments, false, args, -1)) {
return false;
}
break;
}
case Instruction::INVOKE_DIRECT_RANGE:
case Instruction::INVOKE_INTERFACE_RANGE:
case Instruction::INVOKE_STATIC_RANGE:
case Instruction::INVOKE_SUPER_RANGE:
case Instruction::INVOKE_VIRTUAL_RANGE:
case Instruction::INVOKE_VIRTUAL_RANGE_QUICK: {
uint16_t method_idx;
if (instruction.Opcode() == Instruction::INVOKE_VIRTUAL_RANGE_QUICK) {
if (!CanDecodeQuickenedInfo()) {
return false;
}
method_idx = LookupQuickenedInfo(quicken_index);
} else {
method_idx = instruction.VRegB_3rc();
}
uint32_t number_of_vreg_arguments = instruction.VRegA_3rc();
uint32_t register_index = instruction.VRegC();
if (!BuildInvoke(instruction, dex_pc, method_idx,
number_of_vreg_arguments, true, nullptr, register_index)) {
return false;
}
break;
}
case Instruction::INVOKE_POLYMORPHIC: {
uint16_t method_idx = instruction.VRegB_45cc();
uint16_t proto_idx = instruction.VRegH_45cc();
uint32_t number_of_vreg_arguments = instruction.VRegA_45cc();
uint32_t args[5];
instruction.GetVarArgs(args);
return BuildInvokePolymorphic(instruction,
dex_pc,
method_idx,
proto_idx,
number_of_vreg_arguments,
false,
args,
-1);
}
case Instruction::INVOKE_POLYMORPHIC_RANGE: {
uint16_t method_idx = instruction.VRegB_4rcc();
uint16_t proto_idx = instruction.VRegH_4rcc();
uint32_t number_of_vreg_arguments = instruction.VRegA_4rcc();
uint32_t register_index = instruction.VRegC_4rcc();
return BuildInvokePolymorphic(instruction,
dex_pc,
method_idx,
proto_idx,
number_of_vreg_arguments,
true,
nullptr,
register_index);
}
case Instruction::NEG_INT: {
Unop_12x<HNeg>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::NEG_LONG: {
Unop_12x<HNeg>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::NEG_FLOAT: {
Unop_12x<HNeg>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::NEG_DOUBLE: {
Unop_12x<HNeg>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::NOT_INT: {
Unop_12x<HNot>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::NOT_LONG: {
Unop_12x<HNot>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::INT_TO_LONG: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::INT_TO_FLOAT: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::INT_TO_DOUBLE: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::LONG_TO_INT: {
Conversion_12x(instruction, DataType::Type::kInt64, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::LONG_TO_FLOAT: {
Conversion_12x(instruction, DataType::Type::kInt64, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::LONG_TO_DOUBLE: {
Conversion_12x(instruction, DataType::Type::kInt64, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::FLOAT_TO_INT: {
Conversion_12x(instruction, DataType::Type::kFloat32, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::FLOAT_TO_LONG: {
Conversion_12x(instruction, DataType::Type::kFloat32, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::FLOAT_TO_DOUBLE: {
Conversion_12x(instruction, DataType::Type::kFloat32, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::DOUBLE_TO_INT: {
Conversion_12x(instruction, DataType::Type::kFloat64, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::DOUBLE_TO_LONG: {
Conversion_12x(instruction, DataType::Type::kFloat64, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::DOUBLE_TO_FLOAT: {
Conversion_12x(instruction, DataType::Type::kFloat64, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::INT_TO_BYTE: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kInt8, dex_pc);
break;
}
case Instruction::INT_TO_SHORT: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kInt16, dex_pc);
break;
}
case Instruction::INT_TO_CHAR: {
Conversion_12x(instruction, DataType::Type::kInt32, DataType::Type::kUint16, dex_pc);
break;
}
case Instruction::ADD_INT: {
Binop_23x<HAdd>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::ADD_LONG: {
Binop_23x<HAdd>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::ADD_DOUBLE: {
Binop_23x<HAdd>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::ADD_FLOAT: {
Binop_23x<HAdd>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::SUB_INT: {
Binop_23x<HSub>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SUB_LONG: {
Binop_23x<HSub>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::SUB_FLOAT: {
Binop_23x<HSub>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::SUB_DOUBLE: {
Binop_23x<HSub>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::ADD_INT_2ADDR: {
Binop_12x<HAdd>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::MUL_INT: {
Binop_23x<HMul>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::MUL_LONG: {
Binop_23x<HMul>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::MUL_FLOAT: {
Binop_23x<HMul>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::MUL_DOUBLE: {
Binop_23x<HMul>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::DIV_INT: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt32, false, true);
break;
}
case Instruction::DIV_LONG: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt64, false, true);
break;
}
case Instruction::DIV_FLOAT: {
Binop_23x<HDiv>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::DIV_DOUBLE: {
Binop_23x<HDiv>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::REM_INT: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt32, false, false);
break;
}
case Instruction::REM_LONG: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt64, false, false);
break;
}
case Instruction::REM_FLOAT: {
Binop_23x<HRem>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::REM_DOUBLE: {
Binop_23x<HRem>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::AND_INT: {
Binop_23x<HAnd>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::AND_LONG: {
Binop_23x<HAnd>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::SHL_INT: {
Binop_23x_shift<HShl>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SHL_LONG: {
Binop_23x_shift<HShl>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::SHR_INT: {
Binop_23x_shift<HShr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SHR_LONG: {
Binop_23x_shift<HShr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::USHR_INT: {
Binop_23x_shift<HUShr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::USHR_LONG: {
Binop_23x_shift<HUShr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::OR_INT: {
Binop_23x<HOr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::OR_LONG: {
Binop_23x<HOr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::XOR_INT: {
Binop_23x<HXor>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::XOR_LONG: {
Binop_23x<HXor>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::ADD_LONG_2ADDR: {
Binop_12x<HAdd>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::ADD_DOUBLE_2ADDR: {
Binop_12x<HAdd>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::ADD_FLOAT_2ADDR: {
Binop_12x<HAdd>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::SUB_INT_2ADDR: {
Binop_12x<HSub>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SUB_LONG_2ADDR: {
Binop_12x<HSub>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::SUB_FLOAT_2ADDR: {
Binop_12x<HSub>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::SUB_DOUBLE_2ADDR: {
Binop_12x<HSub>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::MUL_INT_2ADDR: {
Binop_12x<HMul>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::MUL_LONG_2ADDR: {
Binop_12x<HMul>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::MUL_FLOAT_2ADDR: {
Binop_12x<HMul>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::MUL_DOUBLE_2ADDR: {
Binop_12x<HMul>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::DIV_INT_2ADDR: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegA(), instruction.VRegB(),
dex_pc, DataType::Type::kInt32, false, true);
break;
}
case Instruction::DIV_LONG_2ADDR: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegA(), instruction.VRegB(),
dex_pc, DataType::Type::kInt64, false, true);
break;
}
case Instruction::REM_INT_2ADDR: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegA(), instruction.VRegB(),
dex_pc, DataType::Type::kInt32, false, false);
break;
}
case Instruction::REM_LONG_2ADDR: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegA(), instruction.VRegB(),
dex_pc, DataType::Type::kInt64, false, false);
break;
}
case Instruction::REM_FLOAT_2ADDR: {
Binop_12x<HRem>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::REM_DOUBLE_2ADDR: {
Binop_12x<HRem>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::SHL_INT_2ADDR: {
Binop_12x_shift<HShl>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SHL_LONG_2ADDR: {
Binop_12x_shift<HShl>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::SHR_INT_2ADDR: {
Binop_12x_shift<HShr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::SHR_LONG_2ADDR: {
Binop_12x_shift<HShr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::USHR_INT_2ADDR: {
Binop_12x_shift<HUShr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::USHR_LONG_2ADDR: {
Binop_12x_shift<HUShr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::DIV_FLOAT_2ADDR: {
Binop_12x<HDiv>(instruction, DataType::Type::kFloat32, dex_pc);
break;
}
case Instruction::DIV_DOUBLE_2ADDR: {
Binop_12x<HDiv>(instruction, DataType::Type::kFloat64, dex_pc);
break;
}
case Instruction::AND_INT_2ADDR: {
Binop_12x<HAnd>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::AND_LONG_2ADDR: {
Binop_12x<HAnd>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::OR_INT_2ADDR: {
Binop_12x<HOr>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::OR_LONG_2ADDR: {
Binop_12x<HOr>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::XOR_INT_2ADDR: {
Binop_12x<HXor>(instruction, DataType::Type::kInt32, dex_pc);
break;
}
case Instruction::XOR_LONG_2ADDR: {
Binop_12x<HXor>(instruction, DataType::Type::kInt64, dex_pc);
break;
}
case Instruction::ADD_INT_LIT16: {
Binop_22s<HAdd>(instruction, false, dex_pc);
break;
}
case Instruction::AND_INT_LIT16: {
Binop_22s<HAnd>(instruction, false, dex_pc);
break;
}
case Instruction::OR_INT_LIT16: {
Binop_22s<HOr>(instruction, false, dex_pc);
break;
}
case Instruction::XOR_INT_LIT16: {
Binop_22s<HXor>(instruction, false, dex_pc);
break;
}
case Instruction::RSUB_INT: {
Binop_22s<HSub>(instruction, true, dex_pc);
break;
}
case Instruction::MUL_INT_LIT16: {
Binop_22s<HMul>(instruction, false, dex_pc);
break;
}
case Instruction::ADD_INT_LIT8: {
Binop_22b<HAdd>(instruction, false, dex_pc);
break;
}
case Instruction::AND_INT_LIT8: {
Binop_22b<HAnd>(instruction, false, dex_pc);
break;
}
case Instruction::OR_INT_LIT8: {
Binop_22b<HOr>(instruction, false, dex_pc);
break;
}
case Instruction::XOR_INT_LIT8: {
Binop_22b<HXor>(instruction, false, dex_pc);
break;
}
case Instruction::RSUB_INT_LIT8: {
Binop_22b<HSub>(instruction, true, dex_pc);
break;
}
case Instruction::MUL_INT_LIT8: {
Binop_22b<HMul>(instruction, false, dex_pc);
break;
}
case Instruction::DIV_INT_LIT16:
case Instruction::DIV_INT_LIT8: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt32, true, true);
break;
}
case Instruction::REM_INT_LIT16:
case Instruction::REM_INT_LIT8: {
BuildCheckedDivRem(instruction.VRegA(), instruction.VRegB(), instruction.VRegC(),
dex_pc, DataType::Type::kInt32, true, false);
break;
}
case Instruction::SHL_INT_LIT8: {
Binop_22b<HShl>(instruction, false, dex_pc);
break;
}
case Instruction::SHR_INT_LIT8: {
Binop_22b<HShr>(instruction, false, dex_pc);
break;
}
case Instruction::USHR_INT_LIT8: {
Binop_22b<HUShr>(instruction, false, dex_pc);
break;
}
case Instruction::NEW_INSTANCE: {
HNewInstance* new_instance =
BuildNewInstance(dex::TypeIndex(instruction.VRegB_21c()), dex_pc);
DCHECK(new_instance != nullptr);
UpdateLocal(instruction.VRegA(), current_block_->GetLastInstruction());
BuildConstructorFenceForAllocation(new_instance);
break;
}
case Instruction::NEW_ARRAY: {
dex::TypeIndex type_index(instruction.VRegC_22c());
HInstruction* length = LoadLocal(instruction.VRegB_22c(), DataType::Type::kInt32);
HLoadClass* cls = BuildLoadClass(type_index, dex_pc);
HNewArray* new_array = new (allocator_) HNewArray(cls, length, dex_pc);
AppendInstruction(new_array);
UpdateLocal(instruction.VRegA_22c(), current_block_->GetLastInstruction());
BuildConstructorFenceForAllocation(new_array);
break;
}
case Instruction::FILLED_NEW_ARRAY: {
uint32_t number_of_vreg_arguments = instruction.VRegA_35c();
dex::TypeIndex type_index(instruction.VRegB_35c());
uint32_t args[5];
instruction.GetVarArgs(args);
HNewArray* new_array = BuildFilledNewArray(dex_pc,
type_index,
number_of_vreg_arguments,
/* is_range */ false,
args,
/* register_index */ 0);
BuildConstructorFenceForAllocation(new_array);
break;
}
case Instruction::FILLED_NEW_ARRAY_RANGE: {
uint32_t number_of_vreg_arguments = instruction.VRegA_3rc();
dex::TypeIndex type_index(instruction.VRegB_3rc());
uint32_t register_index = instruction.VRegC_3rc();
HNewArray* new_array = BuildFilledNewArray(dex_pc,
type_index,
number_of_vreg_arguments,
/* is_range */ true,
/* args*/ nullptr,
register_index);
BuildConstructorFenceForAllocation(new_array);
break;
}
case Instruction::FILL_ARRAY_DATA: {
BuildFillArrayData(instruction, dex_pc);
break;
}
case Instruction::MOVE_RESULT:
case Instruction::MOVE_RESULT_WIDE:
case Instruction::MOVE_RESULT_OBJECT: {
DCHECK(latest_result_ != nullptr);
UpdateLocal(instruction.VRegA(), latest_result_);
latest_result_ = nullptr;
break;
}
case Instruction::CMP_LONG: {
Binop_23x_cmp(instruction, DataType::Type::kInt64, ComparisonBias::kNoBias, dex_pc);
break;
}
case Instruction::CMPG_FLOAT: {
Binop_23x_cmp(instruction, DataType::Type::kFloat32, ComparisonBias::kGtBias, dex_pc);
break;
}
case Instruction::CMPG_DOUBLE: {
Binop_23x_cmp(instruction, DataType::Type::kFloat64, ComparisonBias::kGtBias, dex_pc);
break;
}
case Instruction::CMPL_FLOAT: {
Binop_23x_cmp(instruction, DataType::Type::kFloat32, ComparisonBias::kLtBias, dex_pc);
break;
}
case Instruction::CMPL_DOUBLE: {
Binop_23x_cmp(instruction, DataType::Type::kFloat64, ComparisonBias::kLtBias, dex_pc);
break;
}
case Instruction::NOP:
break;
case Instruction::IGET:
case Instruction::IGET_QUICK:
case Instruction::IGET_WIDE:
case Instruction::IGET_WIDE_QUICK:
case Instruction::IGET_OBJECT:
case Instruction::IGET_OBJECT_QUICK:
case Instruction::IGET_BOOLEAN:
case Instruction::IGET_BOOLEAN_QUICK:
case Instruction::IGET_BYTE:
case Instruction::IGET_BYTE_QUICK:
case Instruction::IGET_CHAR:
case Instruction::IGET_CHAR_QUICK:
case Instruction::IGET_SHORT:
case Instruction::IGET_SHORT_QUICK: {
if (!BuildInstanceFieldAccess(instruction, dex_pc, false, quicken_index)) {
return false;
}
break;
}
case Instruction::IPUT:
case Instruction::IPUT_QUICK:
case Instruction::IPUT_WIDE:
case Instruction::IPUT_WIDE_QUICK:
case Instruction::IPUT_OBJECT:
case Instruction::IPUT_OBJECT_QUICK:
case Instruction::IPUT_BOOLEAN:
case Instruction::IPUT_BOOLEAN_QUICK:
case Instruction::IPUT_BYTE:
case Instruction::IPUT_BYTE_QUICK:
case Instruction::IPUT_CHAR:
case Instruction::IPUT_CHAR_QUICK:
case Instruction::IPUT_SHORT:
case Instruction::IPUT_SHORT_QUICK: {
if (!BuildInstanceFieldAccess(instruction, dex_pc, true, quicken_index)) {
return false;
}
break;
}
case Instruction::SGET:
case Instruction::SGET_WIDE:
case Instruction::SGET_OBJECT:
case Instruction::SGET_BOOLEAN:
case Instruction::SGET_BYTE:
case Instruction::SGET_CHAR:
case Instruction::SGET_SHORT: {
if (!BuildStaticFieldAccess(instruction, dex_pc, false)) {
return false;
}
break;
}
case Instruction::SPUT:
case Instruction::SPUT_WIDE:
case Instruction::SPUT_OBJECT:
case Instruction::SPUT_BOOLEAN:
case Instruction::SPUT_BYTE:
case Instruction::SPUT_CHAR:
case Instruction::SPUT_SHORT: {
if (!BuildStaticFieldAccess(instruction, dex_pc, true)) {
return false;
}
break;
}
#define ARRAY_XX(kind, anticipated_type) \
case Instruction::AGET##kind: { \
BuildArrayAccess(instruction, dex_pc, false, anticipated_type); \
break; \
} \
case Instruction::APUT##kind: { \
BuildArrayAccess(instruction, dex_pc, true, anticipated_type); \
break; \
}
ARRAY_XX(, DataType::Type::kInt32);
ARRAY_XX(_WIDE, DataType::Type::kInt64);
ARRAY_XX(_OBJECT, DataType::Type::kReference);
ARRAY_XX(_BOOLEAN, DataType::Type::kBool);
ARRAY_XX(_BYTE, DataType::Type::kInt8);
ARRAY_XX(_CHAR, DataType::Type::kUint16);
ARRAY_XX(_SHORT, DataType::Type::kInt16);
case Instruction::ARRAY_LENGTH: {
HInstruction* object = LoadNullCheckedLocal(instruction.VRegB_12x(), dex_pc);
AppendInstruction(new (allocator_) HArrayLength(object, dex_pc));
UpdateLocal(instruction.VRegA_12x(), current_block_->GetLastInstruction());
break;
}
case Instruction::CONST_STRING: {
dex::StringIndex string_index(instruction.VRegB_21c());
AppendInstruction(new (allocator_) HLoadString(graph_->GetCurrentMethod(),
string_index,
*dex_file_,
dex_pc));
UpdateLocal(instruction.VRegA_21c(), current_block_->GetLastInstruction());
break;
}
case Instruction::CONST_STRING_JUMBO: {
dex::StringIndex string_index(instruction.VRegB_31c());
AppendInstruction(new (allocator_) HLoadString(graph_->GetCurrentMethod(),
string_index,
*dex_file_,
dex_pc));
UpdateLocal(instruction.VRegA_31c(), current_block_->GetLastInstruction());
break;
}
case Instruction::CONST_CLASS: {
dex::TypeIndex type_index(instruction.VRegB_21c());
BuildLoadClass(type_index, dex_pc);
UpdateLocal(instruction.VRegA_21c(), current_block_->GetLastInstruction());
break;
}
case Instruction::MOVE_EXCEPTION: {
AppendInstruction(new (allocator_) HLoadException(dex_pc));
UpdateLocal(instruction.VRegA_11x(), current_block_->GetLastInstruction());
AppendInstruction(new (allocator_) HClearException(dex_pc));
break;
}
case Instruction::THROW: {
HInstruction* exception = LoadLocal(instruction.VRegA_11x(), DataType::Type::kReference);
AppendInstruction(new (allocator_) HThrow(exception, dex_pc));
// We finished building this block. Set the current block to null to avoid
// adding dead instructions to it.
current_block_ = nullptr;
break;
}
case Instruction::INSTANCE_OF: {
uint8_t destination = instruction.VRegA_22c();
uint8_t reference = instruction.VRegB_22c();
dex::TypeIndex type_index(instruction.VRegC_22c());
BuildTypeCheck(instruction, destination, reference, type_index, dex_pc);
break;
}
case Instruction::CHECK_CAST: {
uint8_t reference = instruction.VRegA_21c();
dex::TypeIndex type_index(instruction.VRegB_21c());
BuildTypeCheck(instruction, -1, reference, type_index, dex_pc);
break;
}
case Instruction::MONITOR_ENTER: {
AppendInstruction(new (allocator_) HMonitorOperation(
LoadLocal(instruction.VRegA_11x(), DataType::Type::kReference),
HMonitorOperation::OperationKind::kEnter,
dex_pc));
break;
}
case Instruction::MONITOR_EXIT: {
AppendInstruction(new (allocator_) HMonitorOperation(
LoadLocal(instruction.VRegA_11x(), DataType::Type::kReference),
HMonitorOperation::OperationKind::kExit,
dex_pc));
break;
}
case Instruction::SPARSE_SWITCH:
case Instruction::PACKED_SWITCH: {
BuildSwitch(instruction, dex_pc);
break;
}
default:
VLOG(compiler) << "Did not compile "
<< dex_file_->PrettyMethod(dex_compilation_unit_->GetDexMethodIndex())
<< " because of unhandled instruction "
<< instruction.Name();
MaybeRecordStat(compilation_stats_,
MethodCompilationStat::kNotCompiledUnhandledInstruction);
return false;
}
return true;
} // NOLINT(readability/fn_size)
ObjPtr<mirror::Class> HInstructionBuilder::LookupResolvedType(
dex::TypeIndex type_index,
const DexCompilationUnit& compilation_unit) const {
return ClassLinker::LookupResolvedType(
type_index, compilation_unit.GetDexCache().Get(), compilation_unit.GetClassLoader().Get());
}
ObjPtr<mirror::Class> HInstructionBuilder::LookupReferrerClass() const {
// TODO: Cache the result in a Handle<mirror::Class>.
const DexFile::MethodId& method_id =
dex_compilation_unit_->GetDexFile()->GetMethodId(dex_compilation_unit_->GetDexMethodIndex());
return LookupResolvedType(method_id.class_idx_, *dex_compilation_unit_);
}
} // namespace art