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/*
* Copyright (C) 2014 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.
*/
#ifndef ART_COMPILER_OPTIMIZING_NODES_H_
#define ART_COMPILER_OPTIMIZING_NODES_H_
#include <algorithm>
#include <array>
#include <type_traits>
#include "base/arena_bit_vector.h"
#include "base/arena_containers.h"
#include "base/arena_object.h"
#include "base/stl_util.h"
#include "dex/compiler_enums.h"
#include "entrypoints/quick/quick_entrypoints_enum.h"
#include "handle.h"
#include "handle_scope.h"
#include "invoke_type.h"
#include "locations.h"
#include "method_reference.h"
#include "mirror/class.h"
#include "offsets.h"
#include "primitive.h"
#include "utils/array_ref.h"
#include "utils/intrusive_forward_list.h"
namespace art {
class GraphChecker;
class HBasicBlock;
class HCurrentMethod;
class HDoubleConstant;
class HEnvironment;
class HFloatConstant;
class HGraphBuilder;
class HGraphVisitor;
class HInstruction;
class HIntConstant;
class HInvoke;
class HLongConstant;
class HNullConstant;
class HPhi;
class HSuspendCheck;
class HTryBoundary;
class LiveInterval;
class LocationSummary;
class SlowPathCode;
class SsaBuilder;
namespace mirror {
class DexCache;
} // namespace mirror
static const int kDefaultNumberOfBlocks = 8;
static const int kDefaultNumberOfSuccessors = 2;
static const int kDefaultNumberOfPredecessors = 2;
static const int kDefaultNumberOfExceptionalPredecessors = 0;
static const int kDefaultNumberOfDominatedBlocks = 1;
static const int kDefaultNumberOfBackEdges = 1;
// The maximum (meaningful) distance (31) that can be used in an integer shift/rotate operation.
static constexpr int32_t kMaxIntShiftDistance = 0x1f;
// The maximum (meaningful) distance (63) that can be used in a long shift/rotate operation.
static constexpr int32_t kMaxLongShiftDistance = 0x3f;
static constexpr uint32_t kUnknownFieldIndex = static_cast<uint32_t>(-1);
static constexpr uint16_t kUnknownClassDefIndex = static_cast<uint16_t>(-1);
static constexpr InvokeType kInvalidInvokeType = static_cast<InvokeType>(-1);
static constexpr uint32_t kNoDexPc = -1;
enum IfCondition {
// All types.
kCondEQ, // ==
kCondNE, // !=
// Signed integers and floating-point numbers.
kCondLT, // <
kCondLE, // <=
kCondGT, // >
kCondGE, // >=
// Unsigned integers.
kCondB, // <
kCondBE, // <=
kCondA, // >
kCondAE, // >=
};
enum GraphAnalysisResult {
kAnalysisSkipped,
kAnalysisInvalidBytecode,
kAnalysisFailThrowCatchLoop,
kAnalysisFailAmbiguousArrayOp,
kAnalysisSuccess,
};
class HInstructionList : public ValueObject {
public:
HInstructionList() : first_instruction_(nullptr), last_instruction_(nullptr) {}
void AddInstruction(HInstruction* instruction);
void RemoveInstruction(HInstruction* instruction);
// Insert `instruction` before/after an existing instruction `cursor`.
void InsertInstructionBefore(HInstruction* instruction, HInstruction* cursor);
void InsertInstructionAfter(HInstruction* instruction, HInstruction* cursor);
// Return true if this list contains `instruction`.
bool Contains(HInstruction* instruction) const;
// Return true if `instruction1` is found before `instruction2` in
// this instruction list and false otherwise. Abort if none
// of these instructions is found.
bool FoundBefore(const HInstruction* instruction1,
const HInstruction* instruction2) const;
bool IsEmpty() const { return first_instruction_ == nullptr; }
void Clear() { first_instruction_ = last_instruction_ = nullptr; }
// Update the block of all instructions to be `block`.
void SetBlockOfInstructions(HBasicBlock* block) const;
void AddAfter(HInstruction* cursor, const HInstructionList& instruction_list);
void AddBefore(HInstruction* cursor, const HInstructionList& instruction_list);
void Add(const HInstructionList& instruction_list);
// Return the number of instructions in the list. This is an expensive operation.
size_t CountSize() const;
private:
HInstruction* first_instruction_;
HInstruction* last_instruction_;
friend class HBasicBlock;
friend class HGraph;
friend class HInstruction;
friend class HInstructionIterator;
friend class HBackwardInstructionIterator;
DISALLOW_COPY_AND_ASSIGN(HInstructionList);
};
class ReferenceTypeInfo : ValueObject {
public:
typedef Handle<mirror::Class> TypeHandle;
static ReferenceTypeInfo Create(TypeHandle type_handle, bool is_exact);
static ReferenceTypeInfo CreateUnchecked(TypeHandle type_handle, bool is_exact) {
return ReferenceTypeInfo(type_handle, is_exact);
}
static ReferenceTypeInfo CreateInvalid() { return ReferenceTypeInfo(); }
static bool IsValidHandle(TypeHandle handle) {
return handle.GetReference() != nullptr;
}
bool IsValid() const {
return IsValidHandle(type_handle_);
}
bool IsExact() const { return is_exact_; }
bool IsObjectClass() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsObjectClass();
}
bool IsStringClass() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsStringClass();
}
bool IsObjectArray() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return IsArrayClass() && GetTypeHandle()->GetComponentType()->IsObjectClass();
}
bool IsInterface() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsInterface();
}
bool IsArrayClass() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsArrayClass();
}
bool IsPrimitiveArrayClass() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsPrimitiveArray();
}
bool IsNonPrimitiveArrayClass() const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
return GetTypeHandle()->IsArrayClass() && !GetTypeHandle()->IsPrimitiveArray();
}
bool CanArrayHold(ReferenceTypeInfo rti) const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
if (!IsExact()) return false;
if (!IsArrayClass()) return false;
return GetTypeHandle()->GetComponentType()->IsAssignableFrom(rti.GetTypeHandle().Get());
}
bool CanArrayHoldValuesOf(ReferenceTypeInfo rti) const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
if (!IsExact()) return false;
if (!IsArrayClass()) return false;
if (!rti.IsArrayClass()) return false;
return GetTypeHandle()->GetComponentType()->IsAssignableFrom(
rti.GetTypeHandle()->GetComponentType());
}
Handle<mirror::Class> GetTypeHandle() const { return type_handle_; }
bool IsSupertypeOf(ReferenceTypeInfo rti) const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
DCHECK(rti.IsValid());
return GetTypeHandle()->IsAssignableFrom(rti.GetTypeHandle().Get());
}
bool IsStrictSupertypeOf(ReferenceTypeInfo rti) const SHARED_REQUIRES(Locks::mutator_lock_) {
DCHECK(IsValid());
DCHECK(rti.IsValid());
return GetTypeHandle().Get() != rti.GetTypeHandle().Get() &&
GetTypeHandle()->IsAssignableFrom(rti.GetTypeHandle().Get());
}
// Returns true if the type information provide the same amount of details.
// Note that it does not mean that the instructions have the same actual type
// (because the type can be the result of a merge).
bool IsEqual(ReferenceTypeInfo rti) const SHARED_REQUIRES(Locks::mutator_lock_) {
if (!IsValid() && !rti.IsValid()) {
// Invalid types are equal.
return true;
}
if (!IsValid() || !rti.IsValid()) {
// One is valid, the other not.
return false;
}
return IsExact() == rti.IsExact()
&& GetTypeHandle().Get() == rti.GetTypeHandle().Get();
}
private:
ReferenceTypeInfo() : type_handle_(TypeHandle()), is_exact_(false) {}
ReferenceTypeInfo(TypeHandle type_handle, bool is_exact)
: type_handle_(type_handle), is_exact_(is_exact) { }
// The class of the object.
TypeHandle type_handle_;
// Whether or not the type is exact or a superclass of the actual type.
// Whether or not we have any information about this type.
bool is_exact_;
};
std::ostream& operator<<(std::ostream& os, const ReferenceTypeInfo& rhs);
// Control-flow graph of a method. Contains a list of basic blocks.
class HGraph : public ArenaObject<kArenaAllocGraph> {
public:
HGraph(ArenaAllocator* arena,
const DexFile& dex_file,
uint32_t method_idx,
bool should_generate_constructor_barrier,
InstructionSet instruction_set,
InvokeType invoke_type = kInvalidInvokeType,
bool debuggable = false,
bool osr = false,
int start_instruction_id = 0)
: arena_(arena),
blocks_(arena->Adapter(kArenaAllocBlockList)),
reverse_post_order_(arena->Adapter(kArenaAllocReversePostOrder)),
linear_order_(arena->Adapter(kArenaAllocLinearOrder)),
entry_block_(nullptr),
exit_block_(nullptr),
maximum_number_of_out_vregs_(0),
number_of_vregs_(0),
number_of_in_vregs_(0),
temporaries_vreg_slots_(0),
has_bounds_checks_(false),
has_try_catch_(false),
has_irreducible_loops_(false),
debuggable_(debuggable),
current_instruction_id_(start_instruction_id),
dex_file_(dex_file),
method_idx_(method_idx),
invoke_type_(invoke_type),
in_ssa_form_(false),
should_generate_constructor_barrier_(should_generate_constructor_barrier),
instruction_set_(instruction_set),
cached_null_constant_(nullptr),
cached_int_constants_(std::less<int32_t>(), arena->Adapter(kArenaAllocConstantsMap)),
cached_float_constants_(std::less<int32_t>(), arena->Adapter(kArenaAllocConstantsMap)),
cached_long_constants_(std::less<int64_t>(), arena->Adapter(kArenaAllocConstantsMap)),
cached_double_constants_(std::less<int64_t>(), arena->Adapter(kArenaAllocConstantsMap)),
cached_current_method_(nullptr),
inexact_object_rti_(ReferenceTypeInfo::CreateInvalid()),
osr_(osr) {
blocks_.reserve(kDefaultNumberOfBlocks);
}
// Acquires and stores RTI of inexact Object to be used when creating HNullConstant.
void InitializeInexactObjectRTI(StackHandleScopeCollection* handles);
ArenaAllocator* GetArena() const { return arena_; }
const ArenaVector<HBasicBlock*>& GetBlocks() const { return blocks_; }
bool IsInSsaForm() const { return in_ssa_form_; }
void SetInSsaForm() { in_ssa_form_ = true; }
HBasicBlock* GetEntryBlock() const { return entry_block_; }
HBasicBlock* GetExitBlock() const { return exit_block_; }
bool HasExitBlock() const { return exit_block_ != nullptr; }
void SetEntryBlock(HBasicBlock* block) { entry_block_ = block; }
void SetExitBlock(HBasicBlock* block) { exit_block_ = block; }
void AddBlock(HBasicBlock* block);
void ComputeDominanceInformation();
void ClearDominanceInformation();
void ClearLoopInformation();
void FindBackEdges(ArenaBitVector* visited);
GraphAnalysisResult BuildDominatorTree();
void SimplifyCFG();
void SimplifyCatchBlocks();
// Analyze all natural loops in this graph. Returns a code specifying that it
// was successful or the reason for failure. The method will fail if a loop
// is a throw-catch loop, i.e. the header is a catch block.
GraphAnalysisResult AnalyzeLoops() const;
// Iterate over blocks to compute try block membership. Needs reverse post
// order and loop information.
void ComputeTryBlockInformation();
// Inline this graph in `outer_graph`, replacing the given `invoke` instruction.
// Returns the instruction to replace the invoke expression or null if the
// invoke is for a void method. Note that the caller is responsible for replacing
// and removing the invoke instruction.
HInstruction* InlineInto(HGraph* outer_graph, HInvoke* invoke);
// Update the loop and try membership of `block`, which was spawned from `reference`.
// In case `reference` is a back edge, `replace_if_back_edge` notifies whether `block`
// should be the new back edge.
void UpdateLoopAndTryInformationOfNewBlock(HBasicBlock* block,
HBasicBlock* reference,
bool replace_if_back_edge);
// Need to add a couple of blocks to test if the loop body is entered and
// put deoptimization instructions, etc.
void TransformLoopHeaderForBCE(HBasicBlock* header);
// Removes `block` from the graph. Assumes `block` has been disconnected from
// other blocks and has no instructions or phis.
void DeleteDeadEmptyBlock(HBasicBlock* block);
// Splits the edge between `block` and `successor` while preserving the
// indices in the predecessor/successor lists. If there are multiple edges
// between the blocks, the lowest indices are used.
// Returns the new block which is empty and has the same dex pc as `successor`.
HBasicBlock* SplitEdge(HBasicBlock* block, HBasicBlock* successor);
void SplitCriticalEdge(HBasicBlock* block, HBasicBlock* successor);
void SimplifyLoop(HBasicBlock* header);
int32_t GetNextInstructionId() {
DCHECK_NE(current_instruction_id_, INT32_MAX);
return current_instruction_id_++;
}
int32_t GetCurrentInstructionId() const {
return current_instruction_id_;
}
void SetCurrentInstructionId(int32_t id) {
DCHECK_GE(id, current_instruction_id_);
current_instruction_id_ = id;
}
uint16_t GetMaximumNumberOfOutVRegs() const {
return maximum_number_of_out_vregs_;
}
void SetMaximumNumberOfOutVRegs(uint16_t new_value) {
maximum_number_of_out_vregs_ = new_value;
}
void UpdateMaximumNumberOfOutVRegs(uint16_t other_value) {
maximum_number_of_out_vregs_ = std::max(maximum_number_of_out_vregs_, other_value);
}
void UpdateTemporariesVRegSlots(size_t slots) {
temporaries_vreg_slots_ = std::max(slots, temporaries_vreg_slots_);
}
size_t GetTemporariesVRegSlots() const {
DCHECK(!in_ssa_form_);
return temporaries_vreg_slots_;
}
void SetNumberOfVRegs(uint16_t number_of_vregs) {
number_of_vregs_ = number_of_vregs;
}
uint16_t GetNumberOfVRegs() const {
return number_of_vregs_;
}
void SetNumberOfInVRegs(uint16_t value) {
number_of_in_vregs_ = value;
}
uint16_t GetNumberOfInVRegs() const {
return number_of_in_vregs_;
}
uint16_t GetNumberOfLocalVRegs() const {
DCHECK(!in_ssa_form_);
return number_of_vregs_ - number_of_in_vregs_;
}
const ArenaVector<HBasicBlock*>& GetReversePostOrder() const {
return reverse_post_order_;
}
const ArenaVector<HBasicBlock*>& GetLinearOrder() const {
return linear_order_;
}
bool HasBoundsChecks() const {
return has_bounds_checks_;
}
void SetHasBoundsChecks(bool value) {
has_bounds_checks_ = value;
}
bool ShouldGenerateConstructorBarrier() const {
return should_generate_constructor_barrier_;
}
bool IsDebuggable() const { return debuggable_; }
// Returns a constant of the given type and value. If it does not exist
// already, it is created and inserted into the graph. This method is only for
// integral types.
HConstant* GetConstant(Primitive::Type type, int64_t value, uint32_t dex_pc = kNoDexPc);
// TODO: This is problematic for the consistency of reference type propagation
// because it can be created anytime after the pass and thus it will be left
// with an invalid type.
HNullConstant* GetNullConstant(uint32_t dex_pc = kNoDexPc);
HIntConstant* GetIntConstant(int32_t value, uint32_t dex_pc = kNoDexPc) {
return CreateConstant(value, &cached_int_constants_, dex_pc);
}
HLongConstant* GetLongConstant(int64_t value, uint32_t dex_pc = kNoDexPc) {
return CreateConstant(value, &cached_long_constants_, dex_pc);
}
HFloatConstant* GetFloatConstant(float value, uint32_t dex_pc = kNoDexPc) {
return CreateConstant(bit_cast<int32_t, float>(value), &cached_float_constants_, dex_pc);
}
HDoubleConstant* GetDoubleConstant(double value, uint32_t dex_pc = kNoDexPc) {
return CreateConstant(bit_cast<int64_t, double>(value), &cached_double_constants_, dex_pc);
}
HCurrentMethod* GetCurrentMethod();
const DexFile& GetDexFile() const {
return dex_file_;
}
uint32_t GetMethodIdx() const {
return method_idx_;
}
InvokeType GetInvokeType() const {
return invoke_type_;
}
InstructionSet GetInstructionSet() const {
return instruction_set_;
}
bool IsCompilingOsr() const { return osr_; }
bool HasTryCatch() const { return has_try_catch_; }
void SetHasTryCatch(bool value) { has_try_catch_ = value; }
bool HasIrreducibleLoops() const { return has_irreducible_loops_; }
void SetHasIrreducibleLoops(bool value) { has_irreducible_loops_ = value; }
ArtMethod* GetArtMethod() const { return art_method_; }
void SetArtMethod(ArtMethod* method) { art_method_ = method; }
// Returns an instruction with the opposite boolean value from 'cond'.
// The instruction has been inserted into the graph, either as a constant, or
// before cursor.
HInstruction* InsertOppositeCondition(HInstruction* cond, HInstruction* cursor);
ReferenceTypeInfo GetInexactObjectRti() const { return inexact_object_rti_; }
private:
void RemoveInstructionsAsUsersFromDeadBlocks(const ArenaBitVector& visited) const;
void RemoveDeadBlocks(const ArenaBitVector& visited);
template <class InstructionType, typename ValueType>
InstructionType* CreateConstant(ValueType value,
ArenaSafeMap<ValueType, InstructionType*>* cache,
uint32_t dex_pc = kNoDexPc) {
// Try to find an existing constant of the given value.
InstructionType* constant = nullptr;
auto cached_constant = cache->find(value);
if (cached_constant != cache->end()) {
constant = cached_constant->second;
}
// If not found or previously deleted, create and cache a new instruction.
// Don't bother reviving a previously deleted instruction, for simplicity.
if (constant == nullptr || constant->GetBlock() == nullptr) {
constant = new (arena_) InstructionType(value, dex_pc);
cache->Overwrite(value, constant);
InsertConstant(constant);
}
return constant;
}
void InsertConstant(HConstant* instruction);
// Cache a float constant into the graph. This method should only be
// called by the SsaBuilder when creating "equivalent" instructions.
void CacheFloatConstant(HFloatConstant* constant);
// See CacheFloatConstant comment.
void CacheDoubleConstant(HDoubleConstant* constant);
ArenaAllocator* const arena_;
// List of blocks in insertion order.
ArenaVector<HBasicBlock*> blocks_;
// List of blocks to perform a reverse post order tree traversal.
ArenaVector<HBasicBlock*> reverse_post_order_;
// List of blocks to perform a linear order tree traversal.
ArenaVector<HBasicBlock*> linear_order_;
HBasicBlock* entry_block_;
HBasicBlock* exit_block_;
// The maximum number of virtual registers arguments passed to a HInvoke in this graph.
uint16_t maximum_number_of_out_vregs_;
// The number of virtual registers in this method. Contains the parameters.
uint16_t number_of_vregs_;
// The number of virtual registers used by parameters of this method.
uint16_t number_of_in_vregs_;
// Number of vreg size slots that the temporaries use (used in baseline compiler).
size_t temporaries_vreg_slots_;
// Has bounds checks. We can totally skip BCE if it's false.
bool has_bounds_checks_;
// Flag whether there are any try/catch blocks in the graph. We will skip
// try/catch-related passes if false.
bool has_try_catch_;
// Flag whether there are any irreducible loops in the graph.
bool has_irreducible_loops_;
// Indicates whether the graph should be compiled in a way that
// ensures full debuggability. If false, we can apply more
// aggressive optimizations that may limit the level of debugging.
const bool debuggable_;
// The current id to assign to a newly added instruction. See HInstruction.id_.
int32_t current_instruction_id_;
// The dex file from which the method is from.
const DexFile& dex_file_;
// The method index in the dex file.
const uint32_t method_idx_;
// If inlined, this encodes how the callee is being invoked.
const InvokeType invoke_type_;
// Whether the graph has been transformed to SSA form. Only used
// in debug mode to ensure we are not using properties only valid
// for non-SSA form (like the number of temporaries).
bool in_ssa_form_;
const bool should_generate_constructor_barrier_;
const InstructionSet instruction_set_;
// Cached constants.
HNullConstant* cached_null_constant_;
ArenaSafeMap<int32_t, HIntConstant*> cached_int_constants_;
ArenaSafeMap<int32_t, HFloatConstant*> cached_float_constants_;
ArenaSafeMap<int64_t, HLongConstant*> cached_long_constants_;
ArenaSafeMap<int64_t, HDoubleConstant*> cached_double_constants_;
HCurrentMethod* cached_current_method_;
// The ArtMethod this graph is for. Note that for AOT, it may be null,
// for example for methods whose declaring class could not be resolved
// (such as when the superclass could not be found).
ArtMethod* art_method_;
// Keep the RTI of inexact Object to avoid having to pass stack handle
// collection pointer to passes which may create NullConstant.
ReferenceTypeInfo inexact_object_rti_;
// Whether we are compiling this graph for on stack replacement: this will
// make all loops seen as irreducible and emit special stack maps to mark
// compiled code entries which the interpreter can directly jump to.
const bool osr_;
friend class SsaBuilder; // For caching constants.
friend class SsaLivenessAnalysis; // For the linear order.
friend class HInliner; // For the reverse post order.
ART_FRIEND_TEST(GraphTest, IfSuccessorSimpleJoinBlock1);
DISALLOW_COPY_AND_ASSIGN(HGraph);
};
class HLoopInformation : public ArenaObject<kArenaAllocLoopInfo> {
public:
HLoopInformation(HBasicBlock* header, HGraph* graph)
: header_(header),
suspend_check_(nullptr),
irreducible_(false),
contains_irreducible_loop_(false),
back_edges_(graph->GetArena()->Adapter(kArenaAllocLoopInfoBackEdges)),
// Make bit vector growable, as the number of blocks may change.
blocks_(graph->GetArena(), graph->GetBlocks().size(), true, kArenaAllocLoopInfoBackEdges) {
back_edges_.reserve(kDefaultNumberOfBackEdges);
}
bool IsIrreducible() const { return irreducible_; }
bool ContainsIrreducibleLoop() const { return contains_irreducible_loop_; }
void Dump(std::ostream& os);
HBasicBlock* GetHeader() const {
return header_;
}
void SetHeader(HBasicBlock* block) {
header_ = block;
}
HSuspendCheck* GetSuspendCheck() const { return suspend_check_; }
void SetSuspendCheck(HSuspendCheck* check) { suspend_check_ = check; }
bool HasSuspendCheck() const { return suspend_check_ != nullptr; }
void AddBackEdge(HBasicBlock* back_edge) {
back_edges_.push_back(back_edge);
}
void RemoveBackEdge(HBasicBlock* back_edge) {
RemoveElement(back_edges_, back_edge);
}
bool IsBackEdge(const HBasicBlock& block) const {
return ContainsElement(back_edges_, &block);
}
size_t NumberOfBackEdges() const {
return back_edges_.size();
}
HBasicBlock* GetPreHeader() const;
const ArenaVector<HBasicBlock*>& GetBackEdges() const {
return back_edges_;
}
// Returns the lifetime position of the back edge that has the
// greatest lifetime position.
size_t GetLifetimeEnd() const;
void ReplaceBackEdge(HBasicBlock* existing, HBasicBlock* new_back_edge) {
ReplaceElement(back_edges_, existing, new_back_edge);
}
// Finds blocks that are part of this loop.
void Populate();
// Returns whether this loop information contains `block`.
// Note that this loop information *must* be populated before entering this function.
bool Contains(const HBasicBlock& block) const;
// Returns whether this loop information is an inner loop of `other`.
// Note that `other` *must* be populated before entering this function.
bool IsIn(const HLoopInformation& other) const;
// Returns true if instruction is not defined within this loop.
bool IsDefinedOutOfTheLoop(HInstruction* instruction) const;
const ArenaBitVector& GetBlocks() const { return blocks_; }
void Add(HBasicBlock* block);
void Remove(HBasicBlock* block);
void ClearAllBlocks() {
blocks_.ClearAllBits();
}
bool HasBackEdgeNotDominatedByHeader() const;
bool IsPopulated() const {
return blocks_.GetHighestBitSet() != -1;
}
bool DominatesAllBackEdges(HBasicBlock* block);
private:
// Internal recursive implementation of `Populate`.
void PopulateRecursive(HBasicBlock* block);
void PopulateIrreducibleRecursive(HBasicBlock* block, ArenaBitVector* finalized);
HBasicBlock* header_;
HSuspendCheck* suspend_check_;
bool irreducible_;
bool contains_irreducible_loop_;
ArenaVector<HBasicBlock*> back_edges_;
ArenaBitVector blocks_;
DISALLOW_COPY_AND_ASSIGN(HLoopInformation);
};
// Stores try/catch information for basic blocks.
// Note that HGraph is constructed so that catch blocks cannot simultaneously
// be try blocks.
class TryCatchInformation : public ArenaObject<kArenaAllocTryCatchInfo> {
public:
// Try block information constructor.
explicit TryCatchInformation(const HTryBoundary& try_entry)
: try_entry_(&try_entry),
catch_dex_file_(nullptr),
catch_type_index_(DexFile::kDexNoIndex16) {
DCHECK(try_entry_ != nullptr);
}
// Catch block information constructor.
TryCatchInformation(uint16_t catch_type_index, const DexFile& dex_file)
: try_entry_(nullptr),
catch_dex_file_(&dex_file),
catch_type_index_(catch_type_index) {}
bool IsTryBlock() const { return try_entry_ != nullptr; }
const HTryBoundary& GetTryEntry() const {
DCHECK(IsTryBlock());
return *try_entry_;
}
bool IsCatchBlock() const { return catch_dex_file_ != nullptr; }
bool IsCatchAllTypeIndex() const {
DCHECK(IsCatchBlock());
return catch_type_index_ == DexFile::kDexNoIndex16;
}
uint16_t GetCatchTypeIndex() const {
DCHECK(IsCatchBlock());
return catch_type_index_;
}
const DexFile& GetCatchDexFile() const {
DCHECK(IsCatchBlock());
return *catch_dex_file_;
}
private:
// One of possibly several TryBoundary instructions entering the block's try.
// Only set for try blocks.
const HTryBoundary* try_entry_;
// Exception type information. Only set for catch blocks.
const DexFile* catch_dex_file_;
const uint16_t catch_type_index_;
};
static constexpr size_t kNoLifetime = -1;
static constexpr uint32_t kInvalidBlockId = static_cast<uint32_t>(-1);
// A block in a method. Contains the list of instructions represented
// as a double linked list. Each block knows its predecessors and
// successors.
class HBasicBlock : public ArenaObject<kArenaAllocBasicBlock> {
public:
HBasicBlock(HGraph* graph, uint32_t dex_pc = kNoDexPc)
: graph_(graph),
predecessors_(graph->GetArena()->Adapter(kArenaAllocPredecessors)),
successors_(graph->GetArena()->Adapter(kArenaAllocSuccessors)),
loop_information_(nullptr),
dominator_(nullptr),
dominated_blocks_(graph->GetArena()->Adapter(kArenaAllocDominated)),
block_id_(kInvalidBlockId),
dex_pc_(dex_pc),
lifetime_start_(kNoLifetime),
lifetime_end_(kNoLifetime),
try_catch_information_(nullptr) {
predecessors_.reserve(kDefaultNumberOfPredecessors);
successors_.reserve(kDefaultNumberOfSuccessors);
dominated_blocks_.reserve(kDefaultNumberOfDominatedBlocks);
}
const ArenaVector<HBasicBlock*>& GetPredecessors() const {
return predecessors_;
}
const ArenaVector<HBasicBlock*>& GetSuccessors() const {
return successors_;
}
ArrayRef<HBasicBlock* const> GetNormalSuccessors() const;
ArrayRef<HBasicBlock* const> GetExceptionalSuccessors() const;
bool HasSuccessor(const HBasicBlock* block, size_t start_from = 0u) {
return ContainsElement(successors_, block, start_from);
}
const ArenaVector<HBasicBlock*>& GetDominatedBlocks() const {
return dominated_blocks_;
}
bool IsEntryBlock() const {
return graph_->GetEntryBlock() == this;
}
bool IsExitBlock() const {
return graph_->GetExitBlock() == this;
}
bool IsSingleGoto() const;
bool IsSingleTryBoundary() const;
// Returns true if this block emits nothing but a jump.
bool IsSingleJump() const {
HLoopInformation* loop_info = GetLoopInformation();
return (IsSingleGoto() || IsSingleTryBoundary())
// Back edges generate a suspend check.
&& (loop_info == nullptr || !loop_info->IsBackEdge(*this));
}
void AddBackEdge(HBasicBlock* back_edge) {
if (loop_information_ == nullptr) {
loop_information_ = new (graph_->GetArena()) HLoopInformation(this, graph_);
}
DCHECK_EQ(loop_information_->GetHeader(), this);
loop_information_->AddBackEdge(back_edge);
}
HGraph* GetGraph() const { return graph_; }
void SetGraph(HGraph* graph) { graph_ = graph; }
uint32_t GetBlockId() const { return block_id_; }
void SetBlockId(int id) { block_id_ = id; }
uint32_t GetDexPc() const { return dex_pc_; }
HBasicBlock* GetDominator() const { return dominator_; }
void SetDominator(HBasicBlock* dominator) { dominator_ = dominator; }
void AddDominatedBlock(HBasicBlock* block) { dominated_blocks_.push_back(block); }
void RemoveDominatedBlock(HBasicBlock* block) {
RemoveElement(dominated_blocks_, block);
}
void ReplaceDominatedBlock(HBasicBlock* existing, HBasicBlock* new_block) {
ReplaceElement(dominated_blocks_, existing, new_block);
}
void ClearDominanceInformation();
int NumberOfBackEdges() const {
return IsLoopHeader() ? loop_information_->NumberOfBackEdges() : 0;
}
HInstruction* GetFirstInstruction() const { return instructions_.first_instruction_; }
HInstruction* GetLastInstruction() const { return instructions_.last_instruction_; }
const HInstructionList& GetInstructions() const { return instructions_; }
HInstruction* GetFirstPhi() const { return phis_.first_instruction_; }
HInstruction* GetLastPhi() const { return phis_.last_instruction_; }
const HInstructionList& GetPhis() const { return phis_; }
HInstruction* GetFirstInstructionDisregardMoves() const;
void AddSuccessor(HBasicBlock* block) {
successors_.push_back(block);
block->predecessors_.push_back(this);
}
void ReplaceSuccessor(HBasicBlock* existing, HBasicBlock* new_block) {
size_t successor_index = GetSuccessorIndexOf(existing);
existing->RemovePredecessor(this);
new_block->predecessors_.push_back(this);
successors_[successor_index] = new_block;
}
void ReplacePredecessor(HBasicBlock* existing, HBasicBlock* new_block) {
size_t predecessor_index = GetPredecessorIndexOf(existing);
existing->RemoveSuccessor(this);
new_block->successors_.push_back(this);
predecessors_[predecessor_index] = new_block;
}
// Insert `this` between `predecessor` and `successor. This method
// preserves the indicies, and will update the first edge found between
// `predecessor` and `successor`.
void InsertBetween(HBasicBlock* predecessor, HBasicBlock* successor) {
size_t predecessor_index = successor->GetPredecessorIndexOf(predecessor);
size_t successor_index = predecessor->GetSuccessorIndexOf(successor);
successor->predecessors_[predecessor_index] = this;
predecessor->successors_[successor_index] = this;
successors_.push_back(successor);
predecessors_.push_back(predecessor);
}
void RemovePredecessor(HBasicBlock* block) {
predecessors_.erase(predecessors_.begin() + GetPredecessorIndexOf(block));
}
void RemoveSuccessor(HBasicBlock* block) {
successors_.erase(successors_.begin() + GetSuccessorIndexOf(block));
}
void ClearAllPredecessors() {
predecessors_.clear();
}
void AddPredecessor(HBasicBlock* block) {
predecessors_.push_back(block);
block->successors_.push_back(this);
}
void SwapPredecessors() {
DCHECK_EQ(predecessors_.size(), 2u);
std::swap(predecessors_[0], predecessors_[1]);
}
void SwapSuccessors() {
DCHECK_EQ(successors_.size(), 2u);
std::swap(successors_[0], successors_[1]);
}
size_t GetPredecessorIndexOf(HBasicBlock* predecessor) const {
return IndexOfElement(predecessors_, predecessor);
}
size_t GetSuccessorIndexOf(HBasicBlock* successor) const {
return IndexOfElement(successors_, successor);
}
HBasicBlock* GetSinglePredecessor() const {
DCHECK_EQ(GetPredecessors().size(), 1u);
return GetPredecessors()[0];
}
HBasicBlock* GetSingleSuccessor() const {
DCHECK_EQ(GetSuccessors().size(), 1u);
return GetSuccessors()[0];
}
// Returns whether the first occurrence of `predecessor` in the list of
// predecessors is at index `idx`.
bool IsFirstIndexOfPredecessor(HBasicBlock* predecessor, size_t idx) const {
DCHECK_EQ(GetPredecessors()[idx], predecessor);
return GetPredecessorIndexOf(predecessor) == idx;
}
// Create a new block between this block and its predecessors. The new block
// is added to the graph, all predecessor edges are relinked to it and an edge
// is created to `this`. Returns the new empty block. Reverse post order or
// loop and try/catch information are not updated.
HBasicBlock* CreateImmediateDominator();
// Split the block into two blocks just before `cursor`. Returns the newly
// created, latter block. Note that this method will add the block to the
// graph, create a Goto at the end of the former block and will create an edge
// between the blocks. It will not, however, update the reverse post order or
// loop and try/catch information.
HBasicBlock* SplitBefore(HInstruction* cursor);
// Split the block into two blocks just before `cursor`. Returns the newly
// created block. Note that this method just updates raw block information,
// like predecessors, successors, dominators, and instruction list. It does not
// update the graph, reverse post order, loop information, nor make sure the
// blocks are consistent (for example ending with a control flow instruction).
HBasicBlock* SplitBeforeForInlining(HInstruction* cursor);
// Similar to `SplitBeforeForInlining` but does it after `cursor`.
HBasicBlock* SplitAfterForInlining(HInstruction* cursor);
// Merge `other` at the end of `this`. Successors and dominated blocks of
// `other` are changed to be successors and dominated blocks of `this`. Note
// that this method does not update the graph, reverse post order, loop
// information, nor make sure the blocks are consistent (for example ending
// with a control flow instruction).
void MergeWithInlined(HBasicBlock* other);
// Replace `this` with `other`. Predecessors, successors, and dominated blocks
// of `this` are moved to `other`.
// Note that this method does not update the graph, reverse post order, loop
// information, nor make sure the blocks are consistent (for example ending
// with a control flow instruction).
void ReplaceWith(HBasicBlock* other);
// Merge `other` at the end of `this`. This method updates loops, reverse post
// order, links to predecessors, successors, dominators and deletes the block
// from the graph. The two blocks must be successive, i.e. `this` the only
// predecessor of `other` and vice versa.
void MergeWith(HBasicBlock* other);
// Disconnects `this` from all its predecessors, successors and dominator,
// removes it from all loops it is included in and eventually from the graph.
// The block must not dominate any other block. Predecessors and successors
// are safely updated.
void DisconnectAndDelete();
void AddInstruction(HInstruction* instruction);
// Insert `instruction` before/after an existing instruction `cursor`.
void InsertInstructionBefore(HInstruction* instruction, HInstruction* cursor);
void InsertInstructionAfter(HInstruction* instruction, HInstruction* cursor);
// Replace instruction `initial` with `replacement` within this block.
void ReplaceAndRemoveInstructionWith(HInstruction* initial,
HInstruction* replacement);
void MoveInstructionBefore(HInstruction* insn, HInstruction* cursor);
void AddPhi(HPhi* phi);
void InsertPhiAfter(HPhi* instruction, HPhi* cursor);
// RemoveInstruction and RemovePhi delete a given instruction from the respective
// instruction list. With 'ensure_safety' set to true, it verifies that the
// instruction is not in use and removes it from the use lists of its inputs.
void RemoveInstruction(HInstruction* instruction, bool ensure_safety = true);
void RemovePhi(HPhi* phi, bool ensure_safety = true);
void RemoveInstructionOrPhi(HInstruction* instruction, bool ensure_safety = true);
bool IsLoopHeader() const {
return IsInLoop() && (loop_information_->GetHeader() == this);
}
bool IsLoopPreHeaderFirstPredecessor() const {
DCHECK(IsLoopHeader());
return GetPredecessors()[0] == GetLoopInformation()->GetPreHeader();
}
bool IsFirstPredecessorBackEdge() const {
DCHECK(IsLoopHeader());
return GetLoopInformation()->IsBackEdge(*GetPredecessors()[0]);
}
HLoopInformation* GetLoopInformation() const {
return loop_information_;
}
// Set the loop_information_ on this block. Overrides the current
// loop_information if it is an outer loop of the passed loop information.
// Note that this method is called while creating the loop information.
void SetInLoop(HLoopInformation* info) {
if (IsLoopHeader()) {
// Nothing to do. This just means `info` is an outer loop.
} else if (!IsInLoop()) {
loop_information_ = info;
} else if (loop_information_->Contains(*info->GetHeader())) {
// Block is currently part of an outer loop. Make it part of this inner loop.
// Note that a non loop header having a loop information means this loop information
// has already been populated
loop_information_ = info;
} else {
// Block is part of an inner loop. Do not update the loop information.
// Note that we cannot do the check `info->Contains(loop_information_)->GetHeader()`
// at this point, because this method is being called while populating `info`.
}
}
// Raw update of the loop information.
void SetLoopInformation(HLoopInformation* info) {
loop_information_ = info;
}
bool IsInLoop() const { return loop_information_ != nullptr; }
TryCatchInformation* GetTryCatchInformation() const { return try_catch_information_; }
void SetTryCatchInformation(TryCatchInformation* try_catch_information) {
try_catch_information_ = try_catch_information;
}
bool IsTryBlock() const {
return try_catch_information_ != nullptr && try_catch_information_->IsTryBlock();
}
bool IsCatchBlock() const {
return try_catch_information_ != nullptr && try_catch_information_->IsCatchBlock();
}
// Returns the try entry that this block's successors should have. They will
// be in the same try, unless the block ends in a try boundary. In that case,
// the appropriate try entry will be returned.
const HTryBoundary* ComputeTryEntryOfSuccessors() const;
bool HasThrowingInstructions() const;
// Returns whether this block dominates the blocked passed as parameter.
bool Dominates(HBasicBlock* block) const;
size_t GetLifetimeStart() const { return lifetime_start_; }
size_t GetLifetimeEnd() const { return lifetime_end_; }
void SetLifetimeStart(size_t start) { lifetime_start_ = start; }
void SetLifetimeEnd(size_t end) { lifetime_end_ = end; }
bool EndsWithControlFlowInstruction() const;
bool EndsWithIf() const;
bool EndsWithTryBoundary() const;
bool HasSinglePhi() const;
private:
HGraph* graph_;
ArenaVector<HBasicBlock*> predecessors_;
ArenaVector<HBasicBlock*> successors_;
HInstructionList instructions_;
HInstructionList phis_;
HLoopInformation* loop_information_;
HBasicBlock* dominator_;
ArenaVector<HBasicBlock*> dominated_blocks_;
uint32_t block_id_;
// The dex program counter of the first instruction of this block.
const uint32_t dex_pc_;
size_t lifetime_start_;
size_t lifetime_end_;
TryCatchInformation* try_catch_information_;
friend class HGraph;
friend class HInstruction;
DISALLOW_COPY_AND_ASSIGN(HBasicBlock);
};
// Iterates over the LoopInformation of all loops which contain 'block'
// from the innermost to the outermost.
class HLoopInformationOutwardIterator : public ValueObject {
public:
explicit HLoopInformationOutwardIterator(const HBasicBlock& block)
: current_(block.GetLoopInformation()) {}
bool Done() const { return current_ == nullptr; }
void Advance() {
DCHECK(!Done());
current_ = current_->GetPreHeader()->GetLoopInformation();
}
HLoopInformation* Current() const {
DCHECK(!Done());
return current_;
}
private:
HLoopInformation* current_;
DISALLOW_COPY_AND_ASSIGN(HLoopInformationOutwardIterator);
};
#define FOR_EACH_CONCRETE_INSTRUCTION_COMMON(M) \
M(Above, Condition) \
M(AboveOrEqual, Condition) \
M(Add, BinaryOperation) \
M(And, BinaryOperation) \
M(ArrayGet, Instruction) \
M(ArrayLength, Instruction) \
M(ArraySet, Instruction) \
M(Below, Condition) \
M(BelowOrEqual, Condition) \
M(BooleanNot, UnaryOperation) \
M(BoundsCheck, Instruction) \
M(BoundType, Instruction) \
M(CheckCast, Instruction) \
M(ClassTableGet, Instruction) \
M(ClearException, Instruction) \
M(ClinitCheck, Instruction) \
M(Compare, BinaryOperation) \
M(CurrentMethod, Instruction) \
M(Deoptimize, Instruction) \
M(Div, BinaryOperation) \
M(DivZeroCheck, Instruction) \
M(DoubleConstant, Constant) \
M(Equal, Condition) \
M(Exit, Instruction) \
M(FloatConstant, Constant) \
M(Goto, Instruction) \
M(GreaterThan, Condition) \
M(GreaterThanOrEqual, Condition) \
M(If, Instruction) \
M(InstanceFieldGet, Instruction) \
M(InstanceFieldSet, Instruction) \
M(InstanceOf, Instruction) \
M(IntConstant, Constant) \
M(InvokeUnresolved, Invoke) \
M(InvokeInterface, Invoke) \
M(InvokeStaticOrDirect, Invoke) \
M(InvokeVirtual, Invoke) \
M(LessThan, Condition) \
M(LessThanOrEqual, Condition) \
M(LoadClass, Instruction) \
M(LoadException, Instruction) \
M(LoadString, Instruction) \
M(LongConstant, Constant) \
M(MemoryBarrier, Instruction) \
M(MonitorOperation, Instruction) \
M(Mul, BinaryOperation) \
M(NativeDebugInfo, Instruction) \
M(Neg, UnaryOperation) \
M(NewArray, Instruction) \
M(NewInstance, Instruction) \
M(Not, UnaryOperation) \
M(NotEqual, Condition) \
M(NullConstant, Instruction) \
M(NullCheck, Instruction) \
M(Or, BinaryOperation) \
M(PackedSwitch, Instruction) \
M(ParallelMove, Instruction) \
M(ParameterValue, Instruction) \
M(Phi, Instruction) \
M(Rem, BinaryOperation) \
M(Return, Instruction) \
M(ReturnVoid, Instruction) \
M(Ror, BinaryOperation) \
M(Shl, BinaryOperation) \
M(Shr, BinaryOperation) \
M(StaticFieldGet, Instruction) \
M(StaticFieldSet, Instruction) \
M(UnresolvedInstanceFieldGet, Instruction) \
M(UnresolvedInstanceFieldSet, Instruction) \
M(UnresolvedStaticFieldGet, Instruction) \
M(UnresolvedStaticFieldSet, Instruction) \
M(Select, Instruction) \
M(Sub, BinaryOperation) \
M(SuspendCheck, Instruction) \
M(Throw, Instruction) \
M(TryBoundary, Instruction) \
M(TypeConversion, Instruction) \
M(UShr, BinaryOperation) \
M(Xor, BinaryOperation) \
/*
* Instructions, shared across several (not all) architectures.
*/
#if !defined(ART_ENABLE_CODEGEN_arm) && !defined(ART_ENABLE_CODEGEN_arm64)
#define FOR_EACH_CONCRETE_INSTRUCTION_SHARED(M)
#else
#define FOR_EACH_CONCRETE_INSTRUCTION_SHARED(M) \
M(BitwiseNegatedRight, Instruction) \
M(MultiplyAccumulate, Instruction)
#endif
#ifndef ART_ENABLE_CODEGEN_arm
#define FOR_EACH_CONCRETE_INSTRUCTION_ARM(M)
#else
#define FOR_EACH_CONCRETE_INSTRUCTION_ARM(M) \
M(ArmDexCacheArraysBase, Instruction)
#endif
#ifndef ART_ENABLE_CODEGEN_arm64
#define FOR_EACH_CONCRETE_INSTRUCTION_ARM64(M)
#else
#define FOR_EACH_CONCRETE_INSTRUCTION_ARM64(M) \
M(Arm64DataProcWithShifterOp, Instruction) \
M(Arm64IntermediateAddress, Instruction)
#endif
#define FOR_EACH_CONCRETE_INSTRUCTION_MIPS(M)
#define FOR_EACH_CONCRETE_INSTRUCTION_MIPS64(M)
#ifndef ART_ENABLE_CODEGEN_x86
#define FOR_EACH_CONCRETE_INSTRUCTION_X86(M)
#else
#define FOR_EACH_CONCRETE_INSTRUCTION_X86(M) \
M(X86ComputeBaseMethodAddress, Instruction) \
M(X86LoadFromConstantTable, Instruction) \
M(X86FPNeg, Instruction) \
M(X86PackedSwitch, Instruction)
#endif
#define FOR_EACH_CONCRETE_INSTRUCTION_X86_64(M)
#define FOR_EACH_CONCRETE_INSTRUCTION(M) \
FOR_EACH_CONCRETE_INSTRUCTION_COMMON(M) \
FOR_EACH_CONCRETE_INSTRUCTION_SHARED(M) \
FOR_EACH_CONCRETE_INSTRUCTION_ARM(M) \
FOR_EACH_CONCRETE_INSTRUCTION_ARM64(M) \
FOR_EACH_CONCRETE_INSTRUCTION_MIPS(M) \
FOR_EACH_CONCRETE_INSTRUCTION_MIPS64(M) \
FOR_EACH_CONCRETE_INSTRUCTION_X86(M) \
FOR_EACH_CONCRETE_INSTRUCTION_X86_64(M)
#define FOR_EACH_ABSTRACT_INSTRUCTION(M) \
M(Condition, BinaryOperation) \
M(Constant, Instruction) \
M(UnaryOperation, Instruction) \
M(BinaryOperation, Instruction) \
M(Invoke, Instruction)
#define FOR_EACH_INSTRUCTION(M) \
FOR_EACH_CONCRETE_INSTRUCTION(M) \
FOR_EACH_ABSTRACT_INSTRUCTION(M)
#define FORWARD_DECLARATION(type, super) class H##type;
FOR_EACH_INSTRUCTION(FORWARD_DECLARATION)
#undef FORWARD_DECLARATION
#define DECLARE_INSTRUCTION(type) \
InstructionKind GetKindInternal() const OVERRIDE { return k##type; } \
const char* DebugName() const OVERRIDE { return #type; } \
bool InstructionTypeEquals(HInstruction* other) const OVERRIDE { \
return other->Is##type(); \
} \
void Accept(HGraphVisitor* visitor) OVERRIDE
#define DECLARE_ABSTRACT_INSTRUCTION(type) \
bool Is##type() const { return As##type() != nullptr; } \
const H##type* As##type() const { return this; } \
H##type* As##type() { return this; }
template <typename T>
class HUseListNode : public ArenaObject<kArenaAllocUseListNode> {
public:
T GetUser() const { return user_; }
size_t GetIndex() const { return index_; }
void SetIndex(size_t index) { index_ = index; }
// Hook for the IntrusiveForwardList<>.
// TODO: Hide this better.
IntrusiveForwardListHook hook;
private:
HUseListNode(T user, size_t index)
: user_(user), index_(index) {}
T const user_;
size_t index_;
friend class HInstruction;
DISALLOW_COPY_AND_ASSIGN(HUseListNode);
};
template <typename T>
using HUseList = IntrusiveForwardList<HUseListNode<T>>;
// This class is used by HEnvironment and HInstruction classes to record the
// instructions they use and pointers to the corresponding HUseListNodes kept
// by the used instructions.
template <typename T>
class HUserRecord : public ValueObject {
public:
HUserRecord() : instruction_(nullptr), before_use_node_() {}
explicit HUserRecord(HInstruction* instruction) : instruction_(instruction), before_use_node_() {}
HUserRecord(const HUserRecord<T>& old_record, typename HUseList<T>::iterator before_use_node)
: HUserRecord(old_record.instruction_, before_use_node) {}
HUserRecord(HInstruction* instruction, typename HUseList<T>::iterator before_use_node)
: instruction_(instruction), before_use_node_(before_use_node) {
DCHECK(instruction_ != nullptr);
}
HInstruction* GetInstruction() const { return instruction_; }
typename HUseList<T>::iterator GetBeforeUseNode() const { return before_use_node_; }
typename HUseList<T>::iterator GetUseNode() const { return ++GetBeforeUseNode(); }
private:
// Instruction used by the user.
HInstruction* instruction_;
// Iterator before the corresponding entry in the use list kept by 'instruction_'.
typename HUseList<T>::iterator before_use_node_;
};
/**
* Side-effects representation.
*
* For write/read dependences on fields/arrays, the dependence analysis uses
* type disambiguation (e.g. a float field write cannot modify the value of an
* integer field read) and the access type (e.g. a reference array write cannot
* modify the value of a reference field read [although it may modify the
* reference fetch prior to reading the field, which is represented by its own
* write/read dependence]). The analysis makes conservative points-to
* assumptions on reference types (e.g. two same typed arrays are assumed to be
* the same, and any reference read depends on any reference read without
* further regard of its type).
*
* The internal representation uses 38-bit and is described in the table below.
* The first line indicates the side effect, and for field/array accesses the
* second line indicates the type of the access (in the order of the
* Primitive::Type enum).
* The two numbered lines below indicate the bit position in the bitfield (read
* vertically).
*
* |Depends on GC|ARRAY-R |FIELD-R |Can trigger GC|ARRAY-W |FIELD-W |
* +-------------+---------+---------+--------------+---------+---------+
* | |DFJISCBZL|DFJISCBZL| |DFJISCBZL|DFJISCBZL|
* | 3 |333333322|222222221| 1 |111111110|000000000|
* | 7 |654321098|765432109| 8 |765432109|876543210|
*
* Note that, to ease the implementation, 'changes' bits are least significant
* bits, while 'dependency' bits are most significant bits.
*/
class SideEffects : public ValueObject {
public:
SideEffects() : flags_(0) {}
static SideEffects None() {
return SideEffects(0);
}
static SideEffects All() {
return SideEffects(kAllChangeBits | kAllDependOnBits);
}
static SideEffects AllChanges() {
return SideEffects(kAllChangeBits);
}
static SideEffects AllDependencies() {
return SideEffects(kAllDependOnBits);
}
static SideEffects AllExceptGCDependency() {
return AllWritesAndReads().Union(SideEffects::CanTriggerGC());
}
static SideEffects AllWritesAndReads() {
return SideEffects(kAllWrites | kAllReads);
}
static SideEffects AllWrites() {
return SideEffects(kAllWrites);
}
static SideEffects AllReads() {
return SideEffects(kAllReads);
}
static SideEffects FieldWriteOfType(Primitive::Type type, bool is_volatile) {
return is_volatile
? AllWritesAndReads()
: SideEffects(TypeFlagWithAlias(type, kFieldWriteOffset));
}
static SideEffects ArrayWriteOfType(Primitive::Type type) {
return SideEffects(TypeFlagWithAlias(type, kArrayWriteOffset));
}
static SideEffects FieldReadOfType(Primitive::Type type, bool is_volatile) {
return is_volatile
? AllWritesAndReads()
: SideEffects(TypeFlagWithAlias(type, kFieldReadOffset));
}
static SideEffects ArrayReadOfType(Primitive::Type type) {
return SideEffects(TypeFlagWithAlias(type, kArrayReadOffset));
}
static SideEffects CanTriggerGC() {
return SideEffects(1ULL << kCanTriggerGCBit);
}
static SideEffects DependsOnGC() {
return SideEffects(1ULL << kDependsOnGCBit);
}
// Combines the side-effects of this and the other.
SideEffects Union(SideEffects other) const {
return SideEffects(flags_ | other.flags_);
}
SideEffects Exclusion(SideEffects other) const {
return SideEffects(flags_ & ~other.flags_);
}
void Add(SideEffects other) {
flags_ |= other.flags_;
}
bool Includes(SideEffects other) const {
return (other.flags_ & flags_) == other.flags_;
}
bool HasSideEffects() const {
return (flags_ & kAllChangeBits);
}
bool HasDependencies() const {
return (flags_ & kAllDependOnBits);
}
// Returns true if there are no side effects or dependencies.
bool DoesNothing() const {
return flags_ == 0;
}
// Returns true if something is written.
bool DoesAnyWrite() const {
return (flags_ & kAllWrites);
}
// Returns true if something is read.
bool DoesAnyRead() const {
return (flags_ & kAllReads);
}
// Returns true if potentially everything is written and read
// (every type and every kind of access).
bool DoesAllReadWrite() const {
return (flags_ & (kAllWrites | kAllReads)) == (kAllWrites | kAllReads);
}
bool DoesAll() const {
return flags_ == (kAllChangeBits | kAllDependOnBits);
}
// Returns true if `this` may read something written by `other`.
bool MayDependOn(SideEffects other) const {
const uint64_t depends_on_flags = (flags_ & kAllDependOnBits) >> kChangeBits;
return (other.flags_ & depends_on_flags);
}
// Returns string representation of flags (for debugging only).
// Format: |x|DFJISCBZL|DFJISCBZL|y|DFJISCBZL|DFJISCBZL|
std::string ToString() const {
std::string flags = "|";
for (int s = kLastBit; s >= 0; s--) {
bool current_bit_is_set = ((flags_ >> s) & 1) != 0;
if ((s == kDependsOnGCBit) || (s == kCanTriggerGCBit)) {
// This is a bit for the GC side effect.
if (current_bit_is_set) {
flags += "GC";
}
flags += "|";
} else {
// This is a bit for the array/field analysis.
// The underscore character stands for the 'can trigger GC' bit.
static const char *kDebug = "LZBCSIJFDLZBCSIJFD_LZBCSIJFDLZBCSIJFD";
if (current_bit_is_set) {
flags += kDebug[s];
}
if ((s == kFieldWriteOffset) || (s == kArrayWriteOffset) ||
(s == kFieldReadOffset) || (s == kArrayReadOffset)) {
flags += "|";
}
}
}
return flags;
}
bool Equals(const SideEffects& other) const { return flags_ == other.flags_; }
private:
static constexpr int kFieldArrayAnalysisBits = 9;
static constexpr int kFieldWriteOffset = 0;
static constexpr int kArrayWriteOffset = kFieldWriteOffset + kFieldArrayAnalysisBits;
static constexpr int kLastBitForWrites = kArrayWriteOffset + kFieldArrayAnalysisBits - 1;
static constexpr int kCanTriggerGCBit = kLastBitForWrites + 1;
static constexpr int kChangeBits = kCanTriggerGCBit + 1;
static constexpr int kFieldReadOffset = kCanTriggerGCBit + 1;
static constexpr int kArrayReadOffset = kFieldReadOffset + kFieldArrayAnalysisBits;
static constexpr int kLastBitForReads = kArrayReadOffset + kFieldArrayAnalysisBits - 1;
static constexpr int kDependsOnGCBit = kLastBitForReads + 1;
static constexpr int kLastBit = kDependsOnGCBit;
static constexpr int kDependOnBits = kLastBit + 1 - kChangeBits;
// Aliases.
static_assert(kChangeBits == kDependOnBits,
"the 'change' bits should match the 'depend on' bits.");
static constexpr uint64_t kAllChangeBits = ((1ULL << kChangeBits) - 1);
static constexpr uint64_t kAllDependOnBits = ((1ULL << kDependOnBits) - 1) << kChangeBits;
static constexpr uint64_t kAllWrites =
((1ULL << (kLastBitForWrites + 1 - kFieldWriteOffset)) - 1) << kFieldWriteOffset;
static constexpr uint64_t kAllReads =
((1ULL << (kLastBitForReads + 1 - kFieldReadOffset)) - 1) << kFieldReadOffset;
// Work around the fact that HIR aliases I/F and J/D.
// TODO: remove this interceptor once HIR types are clean
static uint64_t TypeFlagWithAlias(Primitive::Type type, int offset) {
switch (type) {
case Primitive::kPrimInt:
case Primitive::kPrimFloat:
return TypeFlag(Primitive::kPrimInt, offset) |
TypeFlag(Primitive::kPrimFloat, offset);
case Primitive::kPrimLong:
case Primitive::kPrimDouble:
return TypeFlag(Primitive::kPrimLong, offset) |
TypeFlag(Primitive::kPrimDouble, offset);
default:
return TypeFlag(type, offset);
}
}
// Translates type to bit flag.
static uint64_t TypeFlag(Primitive::Type type, int offset) {
CHECK_NE(type, Primitive::kPrimVoid);
const uint64_t one = 1;
const int shift = type; // 0-based consecutive enum
DCHECK_LE(kFieldWriteOffset, shift);
DCHECK_LT(shift, kArrayWriteOffset);
return one << (type + offset);
}
// Private constructor on direct flags value.
explicit SideEffects(uint64_t flags) : flags_(flags) {}
uint64_t flags_;
};
// A HEnvironment object contains the values of virtual registers at a given location.
class HEnvironment : public ArenaObject<kArenaAllocEnvironment> {
public:
HEnvironment(ArenaAllocator* arena,
size_t number_of_vregs,
const DexFile& dex_file,
uint32_t method_idx,
uint32_t dex_pc,
InvokeType invoke_type,
HInstruction* holder)
: vregs_(number_of_vregs, arena->Adapter(kArenaAllocEnvironmentVRegs)),
locations_(number_of_vregs, arena->Adapter(kArenaAllocEnvironmentLocations)),
parent_(nullptr),
dex_file_(dex_file),
method_idx_(method_idx),
dex_pc_(dex_pc),
invoke_type_(invoke_type),
holder_(holder) {
}
HEnvironment(ArenaAllocator* arena, const HEnvironment& to_copy, HInstruction* holder)
: HEnvironment(arena,
to_copy.Size(),
to_copy.GetDexFile(),
to_copy.GetMethodIdx(),
to_copy.GetDexPc(),
to_copy.GetInvokeType(),
holder) {}
void SetAndCopyParentChain(ArenaAllocator* allocator, HEnvironment* parent) {
if (parent_ != nullptr) {
parent_->SetAndCopyParentChain(allocator, parent);
} else {
parent_ = new (allocator) HEnvironment(allocator, *parent, holder_);
parent_->CopyFrom(parent);
if (parent->GetParent() != nullptr) {
parent_->SetAndCopyParentChain(allocator, parent->GetParent());
}
}
}
void CopyFrom(const ArenaVector<HInstruction*>& locals);
void CopyFrom(HEnvironment* environment);
// Copy from `env`. If it's a loop phi for `loop_header`, copy the first
// input to the loop phi instead. This is for inserting instructions that
// require an environment (like HDeoptimization) in the loop pre-header.
void CopyFromWithLoopPhiAdjustment(HEnvironment* env, HBasicBlock* loop_header);
void SetRawEnvAt(size_t index, HInstruction* instruction) {
vregs_[index] = HUserRecord<HEnvironment*>(instruction);
}
HInstruction* GetInstructionAt(size_t index) const {
return vregs_[index].GetInstruction();
}
void RemoveAsUserOfInput(size_t index) const;
size_t Size() const { return vregs_.size(); }
HEnvironment* GetParent() const { return parent_; }
void SetLocationAt(size_t index, Location location) {
locations_[index] = location;
}
Location GetLocationAt(size_t index) const {
return locations_[index];
}
uint32_t GetDexPc() const {
return dex_pc_;
}
uint32_t GetMethodIdx() const {
return method_idx_;
}
InvokeType GetInvokeType() const {
return invoke_type_;
}
const DexFile& GetDexFile() const {
return dex_file_;
}
HInstruction* GetHolder() const {
return holder_;
}
bool IsFromInlinedInvoke() const {
return GetParent() != nullptr;
}
private:
ArenaVector<HUserRecord<HEnvironment*>> vregs_;
ArenaVector<Location> locations_;
HEnvironment* parent_;
const DexFile& dex_file_;
const uint32_t method_idx_;
const uint32_t dex_pc_;
const InvokeType invoke_type_;
// The instruction that holds this environment.
HInstruction* const holder_;
friend class HInstruction;
DISALLOW_COPY_AND_ASSIGN(HEnvironment);
};
class HInstruction : public ArenaObject<kArenaAllocInstruction> {
public:
HInstruction(SideEffects side_effects, uint32_t dex_pc)
: previous_(nullptr),
next_(nullptr),
block_(nullptr),
dex_pc_(dex_pc),
id_(-1),
ssa_index_(-1),
packed_fields_(0u),
environment_(nullptr),
locations_(nullptr),
live_interval_(nullptr),
lifetime_position_(kNoLifetime),
side_effects_(side_effects),
reference_type_handle_(ReferenceTypeInfo::CreateInvalid().GetTypeHandle()) {
SetPackedFlag<kFlagReferenceTypeIsExact>(ReferenceTypeInfo::CreateInvalid().IsExact());
}
virtual ~HInstruction() {}
#define DECLARE_KIND(type, super) k##type,
enum InstructionKind {
FOR_EACH_INSTRUCTION(DECLARE_KIND)
};
#undef DECLARE_KIND
HInstruction* GetNext() const { return next_; }
HInstruction* GetPrevious() const { return previous_; }
HInstruction* GetNextDisregardingMoves() const;
HInstruction* GetPreviousDisregardingMoves() const;
HBasicBlock* GetBlock() const { return block_; }
ArenaAllocator* GetArena() const { return block_->GetGraph()->GetArena(); }
void SetBlock(HBasicBlock* block) { block_ = block; }
bool IsInBlock() const { return block_ != nullptr; }
bool IsInLoop() const { return block_->IsInLoop(); }
bool IsLoopHeaderPhi() const { return IsPhi() && block_->IsLoopHeader(); }
bool IsIrreducibleLoopHeaderPhi() const {
return IsLoopHeaderPhi() && GetBlock()->GetLoopInformation()->IsIrreducible();
}
virtual size_t InputCount() const = 0;
HInstruction* InputAt(size_t i) const { return InputRecordAt(i).GetInstruction(); }
virtual void Accept(HGraphVisitor* visitor) = 0;
virtual const char* DebugName() const = 0;
virtual Primitive::Type GetType() const { return Primitive::kPrimVoid; }
void SetRawInputAt(size_t index, HInstruction* input) {
SetRawInputRecordAt(index, HUserRecord<HInstruction*>(input));
}
virtual bool NeedsEnvironment() const { return false; }
uint32_t GetDexPc() const { return dex_pc_; }
virtual bool IsControlFlow() const { return false; }
virtual bool CanThrow() const { return false; }
bool CanThrowIntoCatchBlock() const { return CanThrow() && block_->IsTryBlock(); }
bool HasSideEffects() const { return side_effects_.HasSideEffects(); }
bool DoesAnyWrite() const { return side_effects_.DoesAnyWrite(); }
// Does not apply for all instructions, but having this at top level greatly
// simplifies the null check elimination.
// TODO: Consider merging can_be_null into ReferenceTypeInfo.
virtual bool CanBeNull() const {
DCHECK_EQ(GetType(), Primitive::kPrimNot) << "CanBeNull only applies to reference types";
return true;
}
virtual bool CanDoImplicitNullCheckOn(HInstruction* obj ATTRIBUTE_UNUSED) const {
return false;
}
virtual bool IsActualObject() const {
return GetType() == Primitive::kPrimNot;
}
void SetReferenceTypeInfo(ReferenceTypeInfo rti);
ReferenceTypeInfo GetReferenceTypeInfo() const {
DCHECK_EQ(GetType(), Primitive::kPrimNot);
return ReferenceTypeInfo::CreateUnchecked(reference_type_handle_,
GetPackedFlag<kFlagReferenceTypeIsExact>());
}
void AddUseAt(HInstruction* user, size_t index) {
DCHECK(user != nullptr);
// Note: fixup_end remains valid across push_front().
auto fixup_end = uses_.empty() ? uses_.begin() : ++uses_.begin();
HUseListNode<HInstruction*>* new_node =
new (GetBlock()->GetGraph()->GetArena()) HUseListNode<HInstruction*>(user, index);
uses_.push_front(*new_node);
FixUpUserRecordsAfterUseInsertion(fixup_end);
}
void AddEnvUseAt(HEnvironment* user, size_t index) {
DCHECK(user != nullptr);
// Note: env_fixup_end remains valid across push_front().
auto env_fixup_end = env_uses_.empty() ? env_uses_.begin() : ++env_uses_.begin();
HUseListNode<HEnvironment*>* new_node =
new (GetBlock()->GetGraph()->GetArena()) HUseListNode<HEnvironment*>(user, index);
env_uses_.push_front(*new_node);
FixUpUserRecordsAfterEnvUseInsertion(env_fixup_end);
}
void RemoveAsUserOfInput(size_t input) {
HUserRecord<HInstruction*> input_use = InputRecordAt(input);
HUseList<HInstruction*>::iterator before_use_node = input_use.GetBeforeUseNode();
input_use.GetInstruction()->uses_.erase_after(before_use_node);
input_use.GetInstruction()->FixUpUserRecordsAfterUseRemoval(before_use_node);
}
const HUseList<HInstruction*>& GetUses() const { return uses_; }
const HUseList<HEnvironment*>& GetEnvUses() const { return env_uses_; }
bool HasUses() const { return !uses_.empty() || !env_uses_.empty(); }
bool HasEnvironmentUses() const { return !env_uses_.empty(); }
bool HasNonEnvironmentUses() const { return !uses_.empty(); }
bool HasOnlyOneNonEnvironmentUse() const {
return !HasEnvironmentUses() && GetUses().HasExactlyOneElement();
}
// Does this instruction strictly dominate `other_instruction`?
// Returns false if this instruction and `other_instruction` are the same.
// Aborts if this instruction and `other_instruction` are both phis.
bool StrictlyDominates(HInstruction* other_instruction) const;
int GetId() const { return id_; }
void SetId(int id) { id_ = id; }
int GetSsaIndex() const { return ssa_index_; }
void SetSsaIndex(int ssa_index) { ssa_index_ = ssa_index; }
bool HasSsaIndex() const { return ssa_index_ != -1; }
bool HasEnvironment() const { return environment_ != nullptr; }
HEnvironment* GetEnvironment() const { return environment_; }
// Set the `environment_` field. Raw because this method does not
// update the uses lists.
void SetRawEnvironment(HEnvironment* environment) {
DCHECK(environment_ == nullptr);
DCHECK_EQ(environment->GetHolder(), this);
environment_ = environment;
}
void RemoveEnvironment();
// Set the environment of this instruction, copying it from `environment`. While
// copying, the uses lists are being updated.
void CopyEnvironmentFrom(HEnvironment* environment) {
DCHECK(environment_ == nullptr);
ArenaAllocator* allocator = GetBlock()->GetGraph()->GetArena();
environment_ = new (allocator) HEnvironment(allocator, *environment, this);
environment_->CopyFrom(environment);
if (environment->GetParent() != nullptr) {
environment_->SetAndCopyParentChain(allocator, environment->GetParent());
}
}
void CopyEnvironmentFromWithLoopPhiAdjustment(HEnvironment* environment,
HBasicBlock* block) {
DCHECK(environment_ == nullptr);
ArenaAllocator* allocator = GetBlock()->GetGraph()->GetArena();
environment_ = new (allocator) HEnvironment(allocator, *environment, this);
environment_->CopyFromWithLoopPhiAdjustment(environment, block);
if (environment->GetParent() != nullptr) {
environment_->SetAndCopyParentChain(allocator, environment->GetParent());
}
}
// Returns the number of entries in the environment. Typically, that is the
// number of dex registers in a method. It could be more in case of inlining.
size_t EnvironmentSize() const;
LocationSummary* GetLocations() const { return locations_; }
void SetLocations(LocationSummary* locations) { locations_ = locations; }
void ReplaceWith(HInstruction* instruction);
void ReplaceInput(HInstruction* replacement, size_t index);
// This is almost the same as doing `ReplaceWith()`. But in this helper, the
// uses of this instruction by `other` are *not* updated.
void ReplaceWithExceptInReplacementAtIndex(HInstruction* other, size_t use_index) {
ReplaceWith(other);
other->ReplaceInput(this, use_index);
}
// Move `this` instruction before `cursor`.
void MoveBefore(HInstruction* cursor);
// Move `this` before its first user and out of any loops. If there is no
// out-of-loop user that dominates all other users, move the instruction
// to the end of the out-of-loop common dominator of the user's blocks.
//
// This can be used only on non-throwing instructions with no side effects that
// have at least one use but no environment uses.
void MoveBeforeFirstUserAndOutOfLoops();
#define INSTRUCTION_TYPE_CHECK(type, super) \
bool Is##type() const; \
const H##type* As##type() const; \
H##type* As##type();
FOR_EACH_CONCRETE_INSTRUCTION(INSTRUCTION_TYPE_CHECK)
#undef INSTRUCTION_TYPE_CHECK
#define INSTRUCTION_TYPE_CHECK(type, super) \
bool Is##type() const { return (As##type() != nullptr); } \
virtual const H##type* As##type() const { return nullptr; } \
virtual H##type* As##type() { return nullptr; }
FOR_EACH_ABSTRACT_INSTRUCTION(INSTRUCTION_TYPE_CHECK)
#undef INSTRUCTION_TYPE_CHECK
// Returns whether the instruction can be moved within the graph.
virtual bool CanBeMoved() const { return false; }
// Returns whether the two instructions are of the same kind.
virtual bool InstructionTypeEquals(HInstruction* other ATTRIBUTE_UNUSED) const {
return false;
}
// Returns whether any data encoded in the two instructions is equal.
// This method does not look at the inputs. Both instructions must be
// of the same type, otherwise the method has undefined behavior.
virtual bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const {
return false;
}
// Returns whether two instructions are equal, that is:
// 1) They have the same type and contain the same data (InstructionDataEquals).
// 2) Their inputs are identical.
bool Equals(HInstruction* other) const;
// TODO: Remove this indirection when the [[pure]] attribute proposal (n3744)
// is adopted and implemented by our C++ compiler(s). Fow now, we need to hide
// the virtual function because the __attribute__((__pure__)) doesn't really
// apply the strong requirement for virtual functions, preventing optimizations.
InstructionKind GetKind() const PURE;
virtual InstructionKind GetKindInternal() const = 0;
virtual size_t ComputeHashCode() const {
size_t result = GetKind();
for (size_t i = 0, e = InputCount(); i < e; ++i) {
result = (result * 31) + InputAt(i)->GetId();
}
return result;
}
SideEffects GetSideEffects() const { return side_effects_; }
void SetSideEffects(SideEffects other) { side_effects_ = other; }
void AddSideEffects(SideEffects other) { side_effects_.Add(other); }
size_t GetLifetimePosition() const { return lifetime_position_; }
void SetLifetimePosition(size_t position) { lifetime_position_ = position; }
LiveInterval* GetLiveInterval() const { return live_interval_; }
void SetLiveInterval(LiveInterval* interval) { live_interval_ = interval; }
bool HasLiveInterval() const { return live_interval_ != nullptr; }
bool IsSuspendCheckEntry() const { return IsSuspendCheck() && GetBlock()->IsEntryBlock(); }
// Returns whether the code generation of the instruction will require to have access
// to the current method. Such instructions are:
// (1): Instructions that require an environment, as calling the runtime requires
// to walk the stack and have the current method stored at a specific stack address.
// (2): Object literals like classes and strings, that are loaded from the dex cache
// fields of the current method.
bool NeedsCurrentMethod() const {
return NeedsEnvironment() || IsLoadClass() || IsLoadString();
}
// Returns whether the code generation of the instruction will require to have access
// to the dex cache of the current method's declaring class via the current method.
virtual bool NeedsDexCacheOfDeclaringClass() const { return false; }
// Does this instruction have any use in an environment before
// control flow hits 'other'?
bool HasAnyEnvironmentUseBefore(HInstruction* other);
// Remove all references to environment uses of this instruction.
// The caller must ensure that this is safe to do.
void RemoveEnvironmentUsers();
bool IsEmittedAtUseSite() const { return GetPackedFlag<kFlagEmittedAtUseSite>(); }
void MarkEmittedAtUseSite() { SetPackedFlag<kFlagEmittedAtUseSite>(true); }
protected:
// If set, the machine code for this instruction is assumed to be generated by
// its users. Used by liveness analysis to compute use positions accordingly.
static constexpr size_t kFlagEmittedAtUseSite = 0u;
static constexpr size_t kFlagReferenceTypeIsExact = kFlagEmittedAtUseSite + 1;
static constexpr size_t kNumberOfGenericPackedBits = kFlagReferenceTypeIsExact + 1;
static constexpr size_t kMaxNumberOfPackedBits = sizeof(uint32_t) * kBitsPerByte;
virtual const HUserRecord<HInstruction*> InputRecordAt(size_t i) const = 0;
virtual void SetRawInputRecordAt(size_t index, const HUserRecord<HInstruction*>& input) = 0;
uint32_t GetPackedFields() const {
return packed_fields_;
}
template <size_t flag>
bool GetPackedFlag() const {
return (packed_fields_ & (1u << flag)) != 0u;
}
template <size_t flag>
void SetPackedFlag(bool value = true) {
packed_fields_ = (packed_fields_ & ~(1u << flag)) | ((value ? 1u : 0u) << flag);
}
template <typename BitFieldType>
typename BitFieldType::value_type GetPackedField() const {
return BitFieldType::Decode(packed_fields_);
}
template <typename BitFieldType>
void SetPackedField(typename BitFieldType::value_type value) {
DCHECK(IsUint<BitFieldType::size>(static_cast<uintptr_t>(value)));
packed_fields_ = BitFieldType::Update(value, packed_fields_);
}
private:
void FixUpUserRecordsAfterUseInsertion(HUseList<HInstruction*>::iterator fixup_end) {
auto before_use_node = uses_.before_begin();
for (auto use_node = uses_.begin(); use_node != fixup_end; ++use_node) {
HInstruction* user = use_node->GetUser();
size_t input_index = use_node->GetIndex();
user->SetRawInputRecordAt(input_index, HUserRecord<HInstruction*>(this, before_use_node));
before_use_node = use_node;
}
}
void FixUpUserRecordsAfterUseRemoval(HUseList<HInstruction*>::iterator before_use_node) {
auto next = ++HUseList<HInstruction*>::iterator(before_use_node);
if (next != uses_.end()) {
HInstruction* next_user = next->GetUser();
size_t next_index = next->GetIndex();
DCHECK(next_user->InputRecordAt(next_index).GetInstruction() == this);
next_user->SetRawInputRecordAt(next_index, HUserRecord<HInstruction*>(this, before_use_node));
}
}
void FixUpUserRecordsAfterEnvUseInsertion(HUseList<HEnvironment*>::iterator env_fixup_end) {
auto before_env_use_node = env_uses_.before_begin();
for (auto env_use_node = env_uses_.begin(); env_use_node != env_fixup_end; ++env_use_node) {
HEnvironment* user = env_use_node->GetUser();
size_t input_index = env_use_node->GetIndex();
user->vregs_[input_index] = HUserRecord<HEnvironment*>(this, before_env_use_node);
before_env_use_node = env_use_node;
}
}
void FixUpUserRecordsAfterEnvUseRemoval(HUseList<HEnvironment*>::iterator before_env_use_node) {
auto next = ++HUseList<HEnvironment*>::iterator(before_env_use_node);
if (next != env_uses_.end()) {
HEnvironment* next_user = next->GetUser();
size_t next_index = next->GetIndex();
DCHECK(next_user->vregs_[next_index].GetInstruction() == this);
next_user->vregs_[next_index] = HUserRecord<HEnvironment*>(this, before_env_use_node);
}
}
HInstruction* previous_;
HInstruction* next_;
HBasicBlock* block_;
const uint32_t dex_pc_;
// An instruction gets an id when it is added to the graph.
// It reflects creation order. A negative id means the instruction
// has not been added to the graph.
int id_;
// When doing liveness analysis, instructions that have uses get an SSA index.
int ssa_index_;
// Packed fields.
uint32_t packed_fields_;
// List of instructions that have this instruction as input.
HUseList<HInstruction*> uses_;
// List of environments that contain this instruction.
HUseList<HEnvironment*> env_uses_;
// The environment associated with this instruction. Not null if the instruction
// might jump out of the method.
HEnvironment* environment_;
// Set by the code generator.
LocationSummary* locations_;
// Set by the liveness analysis.
LiveInterval* live_interval_;
// Set by the liveness analysis, this is the position in a linear
// order of blocks where this instruction's live interval start.
size_t lifetime_position_;
SideEffects side_effects_;
// The reference handle part of the reference type info.
// The IsExact() flag is stored in packed fields.
// TODO: for primitive types this should be marked as invalid.
ReferenceTypeInfo::TypeHandle reference_type_handle_;
friend class GraphChecker;
friend class HBasicBlock;
friend class HEnvironment;
friend class HGraph;
friend class HInstructionList;
DISALLOW_COPY_AND_ASSIGN(HInstruction);
};
std::ostream& operator<<(std::ostream& os, const HInstruction::InstructionKind& rhs);
class HInputIterator : public ValueObject {
public:
explicit HInputIterator(HInstruction* instruction) : instruction_(instruction), index_(0) {}
bool Done() const { return index_ == instruction_->InputCount(); }
HInstruction* Current() const { return instruction_->InputAt(index_); }
void Advance() { index_++; }
private:
HInstruction* instruction_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HInputIterator);
};
class HInstructionIterator : public ValueObject {
public:
explicit HInstructionIterator(const HInstructionList& instructions)
: instruction_(instructions.first_instruction_) {
next_ = Done() ? nullptr : instruction_->GetNext();
}
bool Done() const { return instruction_ == nullptr; }
HInstruction* Current() const { return instruction_; }
void Advance() {
instruction_ = next_;
next_ = Done() ? nullptr : instruction_->GetNext();
}
private:
HInstruction* instruction_;
HInstruction* next_;
DISALLOW_COPY_AND_ASSIGN(HInstructionIterator);
};
class HBackwardInstructionIterator : public ValueObject {
public:
explicit HBackwardInstructionIterator(const HInstructionList& instructions)
: instruction_(instructions.last_instruction_) {
next_ = Done() ? nullptr : instruction_->GetPrevious();
}
bool Done() const { return instruction_ == nullptr; }
HInstruction* Current() const { return instruction_; }
void Advance() {
instruction_ = next_;
next_ = Done() ? nullptr : instruction_->GetPrevious();
}
private:
HInstruction* instruction_;
HInstruction* next_;
DISALLOW_COPY_AND_ASSIGN(HBackwardInstructionIterator);
};
template<size_t N>
class HTemplateInstruction: public HInstruction {
public:
HTemplateInstruction<N>(SideEffects side_effects, uint32_t dex_pc)
: HInstruction(side_effects, dex_pc), inputs_() {}
virtual ~HTemplateInstruction() {}
size_t InputCount() const OVERRIDE { return N; }
protected:
const HUserRecord<HInstruction*> InputRecordAt(size_t i) const OVERRIDE {
DCHECK_LT(i, N);
return inputs_[i];
}
void SetRawInputRecordAt(size_t i, const HUserRecord<HInstruction*>& input) OVERRIDE {
DCHECK_LT(i, N);
inputs_[i] = input;
}
private:
std::array<HUserRecord<HInstruction*>, N> inputs_;
friend class SsaBuilder;
};
// HTemplateInstruction specialization for N=0.
template<>
class HTemplateInstruction<0>: public HInstruction {
public:
explicit HTemplateInstruction<0>(SideEffects side_effects, uint32_t dex_pc)
: HInstruction(side_effects, dex_pc) {}
virtual ~HTemplateInstruction() {}
size_t InputCount() const OVERRIDE { return 0; }
protected:
const HUserRecord<HInstruction*> InputRecordAt(size_t i ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << "Unreachable";
UNREACHABLE();
}
void SetRawInputRecordAt(size_t i ATTRIBUTE_UNUSED,
const HUserRecord<HInstruction*>& input ATTRIBUTE_UNUSED) OVERRIDE {
LOG(FATAL) << "Unreachable";
UNREACHABLE();
}
private:
friend class SsaBuilder;
};
template<intptr_t N>
class HExpression : public HTemplateInstruction<N> {
public:
HExpression<N>(Primitive::Type type, SideEffects side_effects, uint32_t dex_pc)
: HTemplateInstruction<N>(side_effects, dex_pc) {
this->template SetPackedField<TypeField>(type);
}
virtual ~HExpression() {}
Primitive::Type GetType() const OVERRIDE {
return TypeField::Decode(this->GetPackedFields());
}
protected:
static constexpr size_t kFieldType = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kNumberOfExpressionPackedBits = kFieldType + kFieldTypeSize;
static_assert(kNumberOfExpressionPackedBits <= HInstruction::kMaxNumberOfPackedBits,
"Too many packed fields.");
using TypeField = BitField<Primitive::Type, kFieldType, kFieldTypeSize>;
};
// Represents dex's RETURN_VOID opcode. A HReturnVoid is a control flow
// instruction that branches to the exit block.
class HReturnVoid : public HTemplateInstruction<0> {
public:
explicit HReturnVoid(uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc) {}
bool IsControlFlow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(ReturnVoid);
private:
DISALLOW_COPY_AND_ASSIGN(HReturnVoid);
};
// Represents dex's RETURN opcodes. A HReturn is a control flow
// instruction that branches to the exit block.
class HReturn : public HTemplateInstruction<1> {
public:
explicit HReturn(HInstruction* value, uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc) {
SetRawInputAt(0, value);
}
bool IsControlFlow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(Return);
private:
DISALLOW_COPY_AND_ASSIGN(HReturn);
};
class HPhi : public HInstruction {
public:
HPhi(ArenaAllocator* arena,
uint32_t reg_number,
size_t number_of_inputs,
Primitive::Type type,
uint32_t dex_pc = kNoDexPc)
: HInstruction(SideEffects::None(), dex_pc),
inputs_(number_of_inputs, arena->Adapter(kArenaAllocPhiInputs)),
reg_number_(reg_number) {
SetPackedField<TypeField>(ToPhiType(type));
DCHECK_NE(GetType(), Primitive::kPrimVoid);
// Phis are constructed live and marked dead if conflicting or unused.
// Individual steps of SsaBuilder should assume that if a phi has been
// marked dead, it can be ignored and will be removed by SsaPhiElimination.
SetPackedFlag<kFlagIsLive>(true);
SetPackedFlag<kFlagCanBeNull>(true);
}
// Returns a type equivalent to the given `type`, but that a `HPhi` can hold.
static Primitive::Type ToPhiType(Primitive::Type type) {
return Primitive::PrimitiveKind(type);
}
bool IsCatchPhi() const { return GetBlock()->IsCatchBlock(); }
size_t InputCount() const OVERRIDE { return inputs_.size(); }
void AddInput(HInstruction* input);
void RemoveInputAt(size_t index);
Primitive::Type GetType() const OVERRIDE { return GetPackedField<TypeField>(); }
void SetType(Primitive::Type new_type) {
// Make sure that only valid type changes occur. The following are allowed:
// (1) int -> float/ref (primitive type propagation),
// (2) long -> double (primitive type propagation).
DCHECK(GetType() == new_type ||
(GetType() == Primitive::kPrimInt && new_type == Primitive::kPrimFloat) ||
(GetType() == Primitive::kPrimInt && new_type == Primitive::kPrimNot) ||
(GetType() == Primitive::kPrimLong && new_type == Primitive::kPrimDouble));
SetPackedField<TypeField>(new_type);
}
bool CanBeNull() const OVERRIDE { return GetPackedFlag<kFlagCanBeNull>(); }
void SetCanBeNull(bool can_be_null) { SetPackedFlag<kFlagCanBeNull>(can_be_null); }
uint32_t GetRegNumber() const { return reg_number_; }
void SetDead() { SetPackedFlag<kFlagIsLive>(false); }
void SetLive() { SetPackedFlag<kFlagIsLive>(true); }
bool IsDead() const { return !IsLive(); }
bool IsLive() const { return GetPackedFlag<kFlagIsLive>(); }
bool IsVRegEquivalentOf(HInstruction* other) const {
return other != nullptr
&& other->IsPhi()
&& other->AsPhi()->GetBlock() == GetBlock()
&& other->AsPhi()->GetRegNumber() == GetRegNumber();
}
// Returns the next equivalent phi (starting from the current one) or null if there is none.
// An equivalent phi is a phi having the same dex register and type.
// It assumes that phis with the same dex register are adjacent.
HPhi* GetNextEquivalentPhiWithSameType() {
HInstruction* next = GetNext();
while (next != nullptr && next->AsPhi()->GetRegNumber() == reg_number_) {
if (next->GetType() == GetType()) {
return next->AsPhi();
}
next = next->GetNext();
}
return nullptr;
}
DECLARE_INSTRUCTION(Phi);
protected:
const HUserRecord<HInstruction*> InputRecordAt(size_t index) const OVERRIDE {
return inputs_[index];
}
void SetRawInputRecordAt(size_t index, const HUserRecord<HInstruction*>& input) OVERRIDE {
inputs_[index] = input;
}
private:
static constexpr size_t kFieldType = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kFlagIsLive = kFieldType + kFieldTypeSize;
static constexpr size_t kFlagCanBeNull = kFlagIsLive + 1;
static constexpr size_t kNumberOfPhiPackedBits = kFlagCanBeNull + 1;
static_assert(kNumberOfPhiPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using TypeField = BitField<Primitive::Type, kFieldType, kFieldTypeSize>;
ArenaVector<HUserRecord<HInstruction*> > inputs_;
const uint32_t reg_number_;
DISALLOW_COPY_AND_ASSIGN(HPhi);
};
// The exit instruction is the only instruction of the exit block.
// Instructions aborting the method (HThrow and HReturn) must branch to the
// exit block.
class HExit : public HTemplateInstruction<0> {
public:
explicit HExit(uint32_t dex_pc = kNoDexPc) : HTemplateInstruction(SideEffects::None(), dex_pc) {}
bool IsControlFlow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(Exit);
private:
DISALLOW_COPY_AND_ASSIGN(HExit);
};
// Jumps from one block to another.
class HGoto : public HTemplateInstruction<0> {
public:
explicit HGoto(uint32_t dex_pc = kNoDexPc) : HTemplateInstruction(SideEffects::None(), dex_pc) {}
bool IsControlFlow() const OVERRIDE { return true; }
HBasicBlock* GetSuccessor() const {
return GetBlock()->GetSingleSuccessor();
}
DECLARE_INSTRUCTION(Goto);
private:
DISALLOW_COPY_AND_ASSIGN(HGoto);
};
class HConstant : public HExpression<0> {
public:
explicit HConstant(Primitive::Type type, uint32_t dex_pc = kNoDexPc)
: HExpression(type, SideEffects::None(), dex_pc) {}
bool CanBeMoved() const OVERRIDE { return true; }
// Is this constant -1 in the arithmetic sense?
virtual bool IsMinusOne() const { return false; }
// Is this constant 0 in the arithmetic sense?
virtual bool IsArithmeticZero() const { return false; }
// Is this constant a 0-bit pattern?
virtual bool IsZeroBitPattern() const { return false; }
// Is this constant 1 in the arithmetic sense?
virtual bool IsOne() const { return false; }
virtual uint64_t GetValueAsUint64() const = 0;
DECLARE_ABSTRACT_INSTRUCTION(Constant);
private:
DISALLOW_COPY_AND_ASSIGN(HConstant);
};
class HNullConstant : public HConstant {
public:
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
uint64_t GetValueAsUint64() const OVERRIDE { return 0; }
size_t ComputeHashCode() const OVERRIDE { return 0; }
// The null constant representation is a 0-bit pattern.
virtual bool IsZeroBitPattern() const { return true; }
DECLARE_INSTRUCTION(NullConstant);
private:
explicit HNullConstant(uint32_t dex_pc = kNoDexPc) : HConstant(Primitive::kPrimNot, dex_pc) {}
friend class HGraph;
DISALLOW_COPY_AND_ASSIGN(HNullConstant);
};
// Constants of the type int. Those can be from Dex instructions, or
// synthesized (for example with the if-eqz instruction).
class HIntConstant : public HConstant {
public:
int32_t GetValue() const { return value_; }
uint64_t GetValueAsUint64() const OVERRIDE {
return static_cast<uint64_t>(static_cast<uint32_t>(value_));
}
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
DCHECK(other->IsIntConstant()) << other->DebugName();
return other->AsIntConstant()->value_ == value_;
}
size_t ComputeHashCode() const OVERRIDE { return GetValue(); }
bool IsMinusOne() const OVERRIDE { return GetValue() == -1; }
bool IsArithmeticZero() const OVERRIDE { return GetValue() == 0; }
bool IsZeroBitPattern() const OVERRIDE { return GetValue() == 0; }
bool IsOne() const OVERRIDE { return GetValue() == 1; }
// Integer constants are used to encode Boolean values as well,
// where 1 means true and 0 means false.
bool IsTrue() const { return GetValue() == 1; }
bool IsFalse() const { return GetValue() == 0; }
DECLARE_INSTRUCTION(IntConstant);
private:
explicit HIntConstant(int32_t value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimInt, dex_pc), value_(value) {}
explicit HIntConstant(bool value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimInt, dex_pc), value_(value ? 1 : 0) {}
const int32_t value_;
friend class HGraph;
ART_FRIEND_TEST(GraphTest, InsertInstructionBefore);
ART_FRIEND_TYPED_TEST(ParallelMoveTest, ConstantLast);
DISALLOW_COPY_AND_ASSIGN(HIntConstant);
};
class HLongConstant : public HConstant {
public:
int64_t GetValue() const { return value_; }
uint64_t GetValueAsUint64() const OVERRIDE { return value_; }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
DCHECK(other->IsLongConstant()) << other->DebugName();
return other->AsLongConstant()->value_ == value_;
}
size_t ComputeHashCode() const OVERRIDE { return static_cast<size_t>(GetValue()); }
bool IsMinusOne() const OVERRIDE { return GetValue() == -1; }
bool IsArithmeticZero() const OVERRIDE { return GetValue() == 0; }
bool IsZeroBitPattern() const OVERRIDE { return GetValue() == 0; }
bool IsOne() const OVERRIDE { return GetValue() == 1; }
DECLARE_INSTRUCTION(LongConstant);
private:
explicit HLongConstant(int64_t value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimLong, dex_pc), value_(value) {}
const int64_t value_;
friend class HGraph;
DISALLOW_COPY_AND_ASSIGN(HLongConstant);
};
class HFloatConstant : public HConstant {
public:
float GetValue() const { return value_; }
uint64_t GetValueAsUint64() const OVERRIDE {
return static_cast<uint64_t>(bit_cast<uint32_t, float>(value_));
}
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
DCHECK(other->IsFloatConstant()) << other->DebugName();
return other->AsFloatConstant()->GetValueAsUint64() == GetValueAsUint64();
}
size_t ComputeHashCode() const OVERRIDE { return static_cast<size_t>(GetValue()); }
bool IsMinusOne() const OVERRIDE {
return bit_cast<uint32_t, float>(value_) == bit_cast<uint32_t, float>((-1.0f));
}
bool IsArithmeticZero() const OVERRIDE {
return std::fpclassify(value_) == FP_ZERO;
}
bool IsArithmeticPositiveZero() const {
return IsArithmeticZero() && !std::signbit(value_);
}
bool IsArithmeticNegativeZero() const {
return IsArithmeticZero() && std::signbit(value_);
}
bool IsZeroBitPattern() const OVERRIDE {
return bit_cast<uint32_t, float>(value_) == bit_cast<uint32_t, float>(0.0f);
}
bool IsOne() const OVERRIDE {
return bit_cast<uint32_t, float>(value_) == bit_cast<uint32_t, float>(1.0f);
}
bool IsNaN() const {
return std::isnan(value_);
}
DECLARE_INSTRUCTION(FloatConstant);
private:
explicit HFloatConstant(float value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimFloat, dex_pc), value_(value) {}
explicit HFloatConstant(int32_t value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimFloat, dex_pc), value_(bit_cast<float, int32_t>(value)) {}
const float value_;
// Only the SsaBuilder and HGraph can create floating-point constants.
friend class SsaBuilder;
friend class HGraph;
DISALLOW_COPY_AND_ASSIGN(HFloatConstant);
};
class HDoubleConstant : public HConstant {
public:
double GetValue() const { return value_; }
uint64_t GetValueAsUint64() const OVERRIDE { return bit_cast<uint64_t, double>(value_); }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
DCHECK(other->IsDoubleConstant()) << other->DebugName();
return other->AsDoubleConstant()->GetValueAsUint64() == GetValueAsUint64();
}
size_t ComputeHashCode() const OVERRIDE { return static_cast<size_t>(GetValue()); }
bool IsMinusOne() const OVERRIDE {
return bit_cast<uint64_t, double>(value_) == bit_cast<uint64_t, double>((-1.0));
}
bool IsArithmeticZero() const OVERRIDE {
return std::fpclassify(value_) == FP_ZERO;
}
bool IsArithmeticPositiveZero() const {
return IsArithmeticZero() && !std::signbit(value_);
}
bool IsArithmeticNegativeZero() const {
return IsArithmeticZero() && std::signbit(value_);
}
bool IsZeroBitPattern() const OVERRIDE {
return bit_cast<uint64_t, double>(value_) == bit_cast<uint64_t, double>((0.0));
}
bool IsOne() const OVERRIDE {
return bit_cast<uint64_t, double>(value_) == bit_cast<uint64_t, double>(1.0);
}
bool IsNaN() const {
return std::isnan(value_);
}
DECLARE_INSTRUCTION(DoubleConstant);
private:
explicit HDoubleConstant(double value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimDouble, dex_pc), value_(value) {}
explicit HDoubleConstant(int64_t value, uint32_t dex_pc = kNoDexPc)
: HConstant(Primitive::kPrimDouble, dex_pc), value_(bit_cast<double, int64_t>(value)) {}
const double value_;
// Only the SsaBuilder and HGraph can create floating-point constants.
friend class SsaBuilder;
friend class HGraph;
DISALLOW_COPY_AND_ASSIGN(HDoubleConstant);
};
// Conditional branch. A block ending with an HIf instruction must have
// two successors.
class HIf : public HTemplateInstruction<1> {
public:
explicit HIf(HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc) {
SetRawInputAt(0, input);
}
bool IsControlFlow() const OVERRIDE { return true; }
HBasicBlock* IfTrueSuccessor() const {
return GetBlock()->GetSuccessors()[0];
}
HBasicBlock* IfFalseSuccessor() const {
return GetBlock()->GetSuccessors()[1];
}
DECLARE_INSTRUCTION(If);
private:
DISALLOW_COPY_AND_ASSIGN(HIf);
};
// Abstract instruction which marks the beginning and/or end of a try block and
// links it to the respective exception handlers. Behaves the same as a Goto in
// non-exceptional control flow.
// Normal-flow successor is stored at index zero, exception handlers under
// higher indices in no particular order.
class HTryBoundary : public HTemplateInstruction<0> {
public:
enum class BoundaryKind {
kEntry,
kExit,
kLast = kExit
};
explicit HTryBoundary(BoundaryKind kind, uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc) {
SetPackedField<BoundaryKindField>(kind);
}
bool IsControlFlow() const OVERRIDE { return true; }
// Returns the block's non-exceptional successor (index zero).
HBasicBlock* GetNormalFlowSuccessor() const { return GetBlock()->GetSuccessors()[0]; }
ArrayRef<HBasicBlock* const> GetExceptionHandlers() const {
return ArrayRef<HBasicBlock* const>(GetBlock()->GetSuccessors()).SubArray(1u);
}
// Returns whether `handler` is among its exception handlers (non-zero index
// successors).
bool HasExceptionHandler(const HBasicBlock& handler) const {
DCHECK(handler.IsCatchBlock());
return GetBlock()->HasSuccessor(&handler, 1u /* Skip first successor. */);
}
// If not present already, adds `handler` to its block's list of exception
// handlers.
void AddExceptionHandler(HBasicBlock* handler) {
if (!HasExceptionHandler(*handler)) {
GetBlock()->AddSuccessor(handler);
}
}
BoundaryKind GetBoundaryKind() const { return GetPackedField<BoundaryKindField>(); }
bool IsEntry() const { return GetBoundaryKind() == BoundaryKind::kEntry; }
bool HasSameExceptionHandlersAs(const HTryBoundary& other) const;
DECLARE_INSTRUCTION(TryBoundary);
private:
static constexpr size_t kFieldBoundaryKind = kNumberOfGenericPackedBits;
static constexpr size_t kFieldBoundaryKindSize =
MinimumBitsToStore(static_cast<size_t>(BoundaryKind::kLast));
static constexpr size_t kNumberOfTryBoundaryPackedBits =
kFieldBoundaryKind + kFieldBoundaryKindSize;
static_assert(kNumberOfTryBoundaryPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
using BoundaryKindField = BitField<BoundaryKind, kFieldBoundaryKind, kFieldBoundaryKindSize>;
DISALLOW_COPY_AND_ASSIGN(HTryBoundary);
};
// Deoptimize to interpreter, upon checking a condition.
class HDeoptimize : public HTemplateInstruction<1> {
public:
// We set CanTriggerGC to prevent any intermediate address to be live
// at the point of the `HDeoptimize`.
HDeoptimize(HInstruction* cond, uint32_t dex_pc)
: HTemplateInstruction(SideEffects::CanTriggerGC(), dex_pc) {
SetRawInputAt(0, cond);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(Deoptimize);
private:
DISALLOW_COPY_AND_ASSIGN(HDeoptimize);
};
// Represents the ArtMethod that was passed as a first argument to
// the method. It is used by instructions that depend on it, like
// instructions that work with the dex cache.
class HCurrentMethod : public HExpression<0> {
public:
explicit HCurrentMethod(Primitive::Type type, uint32_t dex_pc = kNoDexPc)
: HExpression(type, SideEffects::None(), dex_pc) {}
DECLARE_INSTRUCTION(CurrentMethod);
private:
DISALLOW_COPY_AND_ASSIGN(HCurrentMethod);
};
// Fetches an ArtMethod from the virtual table or the interface method table
// of a class.
class HClassTableGet : public HExpression<1> {
public:
enum class TableKind {
kVTable,
kIMTable,
kLast = kIMTable
};
HClassTableGet(HInstruction* cls,
Primitive::Type type,
TableKind kind,
size_t index,
uint32_t dex_pc)
: HExpression(type, SideEffects::None(), dex_pc),
index_(index) {
SetPackedField<TableKindField>(kind);
SetRawInputAt(0, cls);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
return other->AsClassTableGet()->GetIndex() == index_ &&
other->AsClassTableGet()->GetPackedFields() == GetPackedFields();
}
TableKind GetTableKind() const { return GetPackedField<TableKindField>(); }
size_t GetIndex() const { return index_; }
DECLARE_INSTRUCTION(ClassTableGet);
private:
static constexpr size_t kFieldTableKind = kNumberOfExpressionPackedBits;
static constexpr size_t kFieldTableKindSize =
MinimumBitsToStore(static_cast<size_t>(TableKind::kLast));
static constexpr size_t kNumberOfClassTableGetPackedBits = kFieldTableKind + kFieldTableKindSize;
static_assert(kNumberOfClassTableGetPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
using TableKindField = BitField<TableKind, kFieldTableKind, kFieldTableKind>;
// The index of the ArtMethod in the table.
const size_t index_;
DISALLOW_COPY_AND_ASSIGN(HClassTableGet);
};
// PackedSwitch (jump table). A block ending with a PackedSwitch instruction will
// have one successor for each entry in the switch table, and the final successor
// will be the block containing the next Dex opcode.
class HPackedSwitch : public HTemplateInstruction<1> {
public:
HPackedSwitch(int32_t start_value,
uint32_t num_entries,
HInstruction* input,
uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc),
start_value_(start_value),
num_entries_(num_entries) {
SetRawInputAt(0, input);
}
bool IsControlFlow() const OVERRIDE { return true; }
int32_t GetStartValue() const { return start_value_; }
uint32_t GetNumEntries() const { return num_entries_; }
HBasicBlock* GetDefaultBlock() const {
// Last entry is the default block.
return GetBlock()->GetSuccessors()[num_entries_];
}
DECLARE_INSTRUCTION(PackedSwitch);
private:
const int32_t start_value_;
const uint32_t num_entries_;
DISALLOW_COPY_AND_ASSIGN(HPackedSwitch);
};
class HUnaryOperation : public HExpression<1> {
public:
HUnaryOperation(Primitive::Type result_type, HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HExpression(result_type, SideEffects::None(), dex_pc) {
SetRawInputAt(0, input);
}
HInstruction* GetInput() const { return InputAt(0); }
Primitive::Type GetResultType() const { return GetType(); }
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
// Try to statically evaluate `this` and return a HConstant
// containing the result of this evaluation. If `this` cannot
// be evaluated as a constant, return null.
HConstant* TryStaticEvaluation() const;
// Apply this operation to `x`.
virtual HConstant* Evaluate(HIntConstant* x) const = 0;
virtual HConstant* Evaluate(HLongConstant* x) const = 0;
virtual HConstant* Evaluate(HFloatConstant* x) const = 0;
virtual HConstant* Evaluate(HDoubleConstant* x) const = 0;
DECLARE_ABSTRACT_INSTRUCTION(UnaryOperation);
private:
DISALLOW_COPY_AND_ASSIGN(HUnaryOperation);
};
class HBinaryOperation : public HExpression<2> {
public:
HBinaryOperation(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
SideEffects side_effects = SideEffects::None(),
uint32_t dex_pc = kNoDexPc)
: HExpression(result_type, side_effects, dex_pc) {
SetRawInputAt(0, left);
SetRawInputAt(1, right);
}
HInstruction* GetLeft() const { return InputAt(0); }
HInstruction* GetRight() const { return InputAt(1); }
Primitive::Type GetResultType() const { return GetType(); }
virtual bool IsCommutative() const { return false; }
// Put constant on the right.
// Returns whether order is changed.
bool OrderInputsWithConstantOnTheRight() {
HInstruction* left = InputAt(0);
HInstruction* right = InputAt(1);
if (left->IsConstant() && !right->IsConstant()) {
ReplaceInput(right, 0);
ReplaceInput(left, 1);
return true;
}
return false;
}
// Order inputs by instruction id, but favor constant on the right side.
// This helps GVN for commutative ops.
void OrderInputs() {
DCHECK(IsCommutative());
HInstruction* left = InputAt(0);
HInstruction* right = InputAt(1);
if (left == right || (!left->IsConstant() && right->IsConstant())) {
return;
}
if (OrderInputsWithConstantOnTheRight()) {
return;
}
// Order according to instruction id.
if (left->GetId() > right->GetId()) {
ReplaceInput(right, 0);
ReplaceInput(left, 1);
}
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
// Try to statically evaluate `this` and return a HConstant
// containing the result of this evaluation. If `this` cannot
// be evaluated as a constant, return null.
HConstant* TryStaticEvaluation() const;
// Apply this operation to `x` and `y`.
virtual HConstant* Evaluate(HNullConstant* x ATTRIBUTE_UNUSED,
HNullConstant* y ATTRIBUTE_UNUSED) const {
LOG(FATAL) << DebugName() << " is not defined for the (null, null) case.";
UNREACHABLE();
}
virtual HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const = 0;
virtual HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const = 0;
virtual HConstant* Evaluate(HLongConstant* x ATTRIBUTE_UNUSED,
HIntConstant* y ATTRIBUTE_UNUSED) const {
LOG(FATAL) << DebugName() << " is not defined for the (long, int) case.";
UNREACHABLE();
}
virtual HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const = 0;
virtual HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const = 0;
// Returns an input that can legally be used as the right input and is
// constant, or null.
HConstant* GetConstantRight() const;
// If `GetConstantRight()` returns one of the input, this returns the other
// one. Otherwise it returns null.
HInstruction* GetLeastConstantLeft() const;
DECLARE_ABSTRACT_INSTRUCTION(BinaryOperation);
private:
DISALLOW_COPY_AND_ASSIGN(HBinaryOperation);
};
// The comparison bias applies for floating point operations and indicates how NaN
// comparisons are treated:
enum class ComparisonBias {
kNoBias, // bias is not applicable (i.e. for long operation)
kGtBias, // return 1 for NaN comparisons
kLtBias, // return -1 for NaN comparisons
kLast = kLtBias
};
std::ostream& operator<<(std::ostream& os, const ComparisonBias& rhs);
class HCondition : public HBinaryOperation {
public:
HCondition(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(Primitive::kPrimBoolean, first, second, SideEffects::None(), dex_pc) {
SetPackedField<ComparisonBiasField>(ComparisonBias::kNoBias);
}
// For code generation purposes, returns whether this instruction is just before
// `instruction`, and disregard moves in between.
bool IsBeforeWhenDisregardMoves(HInstruction* instruction) const;
DECLARE_ABSTRACT_INSTRUCTION(Condition);
virtual IfCondition GetCondition() const = 0;
virtual IfCondition GetOppositeCondition() const = 0;
bool IsGtBias() const { return GetBias() == ComparisonBias::kGtBias; }
bool IsLtBias() const { return GetBias() == ComparisonBias::kLtBias; }
ComparisonBias GetBias() const { return GetPackedField<ComparisonBiasField>(); }
void SetBias(ComparisonBias bias) { SetPackedField<ComparisonBiasField>(bias); }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
return GetPackedFields() == other->AsCondition()->GetPackedFields();
}
bool IsFPConditionTrueIfNaN() const {
DCHECK(Primitive::IsFloatingPointType(InputAt(0)->GetType())) << InputAt(0)->GetType();
IfCondition if_cond = GetCondition();
if (if_cond == kCondNE) {
return true;
} else if (if_cond == kCondEQ) {
return false;
}
return ((if_cond == kCondGT) || (if_cond == kCondGE)) && IsGtBias();
}
bool IsFPConditionFalseIfNaN() const {
DCHECK(Primitive::IsFloatingPointType(InputAt(0)->GetType())) << InputAt(0)->GetType();
IfCondition if_cond = GetCondition();
if (if_cond == kCondEQ) {
return true;
} else if (if_cond == kCondNE) {
return false;
}
return ((if_cond == kCondLT) || (if_cond == kCondLE)) && IsGtBias();
}
protected:
// Needed if we merge a HCompare into a HCondition.
static constexpr size_t kFieldComparisonBias = kNumberOfExpressionPackedBits;
static constexpr size_t kFieldComparisonBiasSize =
MinimumBitsToStore(static_cast<size_t>(ComparisonBias::kLast));
static constexpr size_t kNumberOfConditionPackedBits =
kFieldComparisonBias + kFieldComparisonBiasSize;
static_assert(kNumberOfConditionPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using ComparisonBiasField =
BitField<ComparisonBias, kFieldComparisonBias, kFieldComparisonBiasSize>;
template <typename T>
int32_t Compare(T x, T y) const { return x > y ? 1 : (x < y ? -1 : 0); }
template <typename T>
int32_t CompareFP(T x, T y) const {
DCHECK(Primitive::IsFloatingPointType(InputAt(0)->GetType())) << InputAt(0)->GetType();
DCHECK_NE(GetBias(), ComparisonBias::kNoBias);
// Handle the bias.
return std::isunordered(x, y) ? (IsGtBias() ? 1 : -1) : Compare(x, y);
}
// Return an integer constant containing the result of a condition evaluated at compile time.
HIntConstant* MakeConstantCondition(bool value, uint32_t dex_pc) const {
return GetBlock()->GetGraph()->GetIntConstant(value, dex_pc);
}
private:
DISALLOW_COPY_AND_ASSIGN(HCondition);
};
// Instruction to check if two inputs are equal to each other.
class HEqual : public HCondition {
public:
HEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
HConstant* Evaluate(HNullConstant* x ATTRIBUTE_UNUSED,
HNullConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
return MakeConstantCondition(true, GetDexPc());
}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HEqual instruction; evaluate it as
// `Compare(x, y) == 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0),
GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(Equal);
IfCondition GetCondition() const OVERRIDE {
return kCondEQ;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondNE;
}
private:
template <typename T> bool Compute(T x, T y) const { return x == y; }
DISALLOW_COPY_AND_ASSIGN(HEqual);
};
class HNotEqual : public HCondition {
public:
HNotEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
HConstant* Evaluate(HNullConstant* x ATTRIBUTE_UNUSED,
HNullConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
return MakeConstantCondition(false, GetDexPc());
}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HNotEqual instruction; evaluate it as
// `Compare(x, y) != 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(NotEqual);
IfCondition GetCondition() const OVERRIDE {
return kCondNE;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondEQ;
}
private:
template <typename T> bool Compute(T x, T y) const { return x != y; }
DISALLOW_COPY_AND_ASSIGN(HNotEqual);
};
class HLessThan : public HCondition {
public:
HLessThan(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HLessThan instruction; evaluate it as
// `Compare(x, y) < 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(LessThan);
IfCondition GetCondition() const OVERRIDE {
return kCondLT;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondGE;
}
private:
template <typename T> bool Compute(T x, T y) const { return x < y; }
DISALLOW_COPY_AND_ASSIGN(HLessThan);
};
class HLessThanOrEqual : public HCondition {
public:
HLessThanOrEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HLessThanOrEqual instruction; evaluate it as
// `Compare(x, y) <= 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(LessThanOrEqual);
IfCondition GetCondition() const OVERRIDE {
return kCondLE;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondGT;
}
private:
template <typename T> bool Compute(T x, T y) const { return x <= y; }
DISALLOW_COPY_AND_ASSIGN(HLessThanOrEqual);
};
class HGreaterThan : public HCondition {
public:
HGreaterThan(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HGreaterThan instruction; evaluate it as
// `Compare(x, y) > 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(GreaterThan);
IfCondition GetCondition() const OVERRIDE {
return kCondGT;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondLE;
}
private:
template <typename T> bool Compute(T x, T y) const { return x > y; }
DISALLOW_COPY_AND_ASSIGN(HGreaterThan);
};
class HGreaterThanOrEqual : public HCondition {
public:
HGreaterThanOrEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
// In the following Evaluate methods, a HCompare instruction has
// been merged into this HGreaterThanOrEqual instruction; evaluate it as
// `Compare(x, y) >= 0`.
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(Compare(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(CompareFP(x->GetValue(), y->GetValue()), 0), GetDexPc());
}
DECLARE_INSTRUCTION(GreaterThanOrEqual);
IfCondition GetCondition() const OVERRIDE {
return kCondGE;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondLT;
}
private:
template <typename T> bool Compute(T x, T y) const { return x >= y; }
DISALLOW_COPY_AND_ASSIGN(HGreaterThanOrEqual);
};
class HBelow : public HCondition {
public:
HBelow(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Below);
IfCondition GetCondition() const OVERRIDE {
return kCondB;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondAE;
}
private:
template <typename T> bool Compute(T x, T y) const {
return MakeUnsigned(x) < MakeUnsigned(y);
}
DISALLOW_COPY_AND_ASSIGN(HBelow);
};
class HBelowOrEqual : public HCondition {
public:
HBelowOrEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(BelowOrEqual);
IfCondition GetCondition() const OVERRIDE {
return kCondBE;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondA;
}
private:
template <typename T> bool Compute(T x, T y) const {
return MakeUnsigned(x) <= MakeUnsigned(y);
}
DISALLOW_COPY_AND_ASSIGN(HBelowOrEqual);
};
class HAbove : public HCondition {
public:
HAbove(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Above);
IfCondition GetCondition() const OVERRIDE {
return kCondA;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondBE;
}
private:
template <typename T> bool Compute(T x, T y) const {
return MakeUnsigned(x) > MakeUnsigned(y);
}
DISALLOW_COPY_AND_ASSIGN(HAbove);
};
class HAboveOrEqual : public HCondition {
public:
HAboveOrEqual(HInstruction* first, HInstruction* second, uint32_t dex_pc = kNoDexPc)
: HCondition(first, second, dex_pc) {}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantCondition(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(AboveOrEqual);
IfCondition GetCondition() const OVERRIDE {
return kCondAE;
}
IfCondition GetOppositeCondition() const OVERRIDE {
return kCondB;
}
private:
template <typename T> bool Compute(T x, T y) const {
return MakeUnsigned(x) >= MakeUnsigned(y);
}
DISALLOW_COPY_AND_ASSIGN(HAboveOrEqual);
};
// Instruction to check how two inputs compare to each other.
// Result is 0 if input0 == input1, 1 if input0 > input1, or -1 if input0 < input1.
class HCompare : public HBinaryOperation {
public:
// Note that `comparison_type` is the type of comparison performed
// between the comparison's inputs, not the type of the instantiated
// HCompare instruction (which is always Primitive::kPrimInt).
HCompare(Primitive::Type comparison_type,
HInstruction* first,
HInstruction* second,
ComparisonBias bias,
uint32_t dex_pc)
: HBinaryOperation(Primitive::kPrimInt,
first,
second,
SideEffectsForArchRuntimeCalls(comparison_type),
dex_pc) {
SetPackedField<ComparisonBiasField>(bias);
DCHECK_EQ(comparison_type, Primitive::PrimitiveKind(first->GetType()));
DCHECK_EQ(comparison_type, Primitive::PrimitiveKind(second->GetType()));
}
template <typename T>
int32_t Compute(T x, T y) const { return x > y ? 1 : (x < y ? -1 : 0); }
template <typename T>
int32_t ComputeFP(T x, T y) const {
DCHECK(Primitive::IsFloatingPointType(InputAt(0)->GetType())) << InputAt(0)->GetType();
DCHECK_NE(GetBias(), ComparisonBias::kNoBias);
// Handle the bias.
return std::isunordered(x, y) ? (IsGtBias() ? 1 : -1) : Compute(x, y);
}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
// Note that there is no "cmp-int" Dex instruction so we shouldn't
// reach this code path when processing a freshly built HIR
// graph. However HCompare integer instructions can be synthesized
// by the instruction simplifier to implement IntegerCompare and
// IntegerSignum intrinsics, so we have to handle this case.
return MakeConstantComparison(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return MakeConstantComparison(Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return MakeConstantComparison(ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return MakeConstantComparison(ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
return GetPackedFields() == other->AsCompare()->GetPackedFields();
}
ComparisonBias GetBias() const { return GetPackedField<ComparisonBiasField>(); }
// Does this compare instruction have a "gt bias" (vs an "lt bias")?
// Only meaningful for floating-point comparisons.
bool IsGtBias() const {
DCHECK(Primitive::IsFloatingPointType(InputAt(0)->GetType())) << InputAt(0)->GetType();
return GetBias() == ComparisonBias::kGtBias;
}
static SideEffects SideEffectsForArchRuntimeCalls(Primitive::Type type ATTRIBUTE_UNUSED) {
// Comparisons do not require a runtime call in any back end.
return SideEffects::None();
}
DECLARE_INSTRUCTION(Compare);
protected:
static constexpr size_t kFieldComparisonBias = kNumberOfExpressionPackedBits;
static constexpr size_t kFieldComparisonBiasSize =
MinimumBitsToStore(static_cast<size_t>(ComparisonBias::kLast));
static constexpr size_t kNumberOfComparePackedBits =
kFieldComparisonBias + kFieldComparisonBiasSize;
static_assert(kNumberOfComparePackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using ComparisonBiasField =
BitField<ComparisonBias, kFieldComparisonBias, kFieldComparisonBiasSize>;
// Return an integer constant containing the result of a comparison evaluated at compile time.
HIntConstant* MakeConstantComparison(int32_t value, uint32_t dex_pc) const {
DCHECK(value == -1 || value == 0 || value == 1) << value;
return GetBlock()->GetGraph()->GetIntConstant(value, dex_pc);
}
private:
DISALLOW_COPY_AND_ASSIGN(HCompare);
};
class HNewInstance : public HExpression<2> {
public:
HNewInstance(HInstruction* cls,
HCurrentMethod* current_method,
uint32_t dex_pc,
uint16_t type_index,
const DexFile& dex_file,
bool can_throw,
bool finalizable,
QuickEntrypointEnum entrypoint)
: HExpression(Primitive::kPrimNot, SideEffects::CanTriggerGC(), dex_pc),
type_index_(type_index),
dex_file_(dex_file),
entrypoint_(entrypoint) {
SetPackedFlag<kFlagCanThrow>(can_throw);
SetPackedFlag<kFlagFinalizable>(finalizable);
SetRawInputAt(0, cls);
SetRawInputAt(1, current_method);
}
uint16_t GetTypeIndex() const { return type_index_; }
const DexFile& GetDexFile() const { return dex_file_; }
// Calls runtime so needs an environment.
bool NeedsEnvironment() const OVERRIDE { return true; }
// It may throw when called on type that's not instantiable/accessible.
// It can throw OOME.
// TODO: distinguish between the two cases so we can for example allow allocation elimination.
bool CanThrow() const OVERRIDE { return GetPackedFlag<kFlagCanThrow>() || true; }
bool IsFinalizable() const { return GetPackedFlag<kFlagFinalizable>(); }
bool CanBeNull() const OVERRIDE { return false; }
QuickEntrypointEnum GetEntrypoint() const { return entrypoint_; }
void SetEntrypoint(QuickEntrypointEnum entrypoint) {
entrypoint_ = entrypoint;
}
bool IsStringAlloc() const;
DECLARE_INSTRUCTION(NewInstance);
private:
static constexpr size_t kFlagCanThrow = kNumberOfExpressionPackedBits;
static constexpr size_t kFlagFinalizable = kFlagCanThrow + 1;
static constexpr size_t kNumberOfNewInstancePackedBits = kFlagFinalizable + 1;
static_assert(kNumberOfNewInstancePackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
const uint16_t type_index_;
const DexFile& dex_file_;
QuickEntrypointEnum entrypoint_;
DISALLOW_COPY_AND_ASSIGN(HNewInstance);
};
enum class Intrinsics {
#define OPTIMIZING_INTRINSICS(Name, IsStatic, NeedsEnvironmentOrCache, SideEffects, Exceptions) \
k ## Name,
#include "intrinsics_list.h"
kNone,
INTRINSICS_LIST(OPTIMIZING_INTRINSICS)
#undef INTRINSICS_LIST
#undef OPTIMIZING_INTRINSICS
};
std::ostream& operator<<(std::ostream& os, const Intrinsics& intrinsic);
enum IntrinsicNeedsEnvironmentOrCache {
kNoEnvironmentOrCache, // Intrinsic does not require an environment or dex cache.
kNeedsEnvironmentOrCache // Intrinsic requires an environment or requires a dex cache.
};
enum IntrinsicSideEffects {
kNoSideEffects, // Intrinsic does not have any heap memory side effects.
kReadSideEffects, // Intrinsic may read heap memory.
kWriteSideEffects, // Intrinsic may write heap memory.
kAllSideEffects // Intrinsic may read or write heap memory, or trigger GC.
};
enum IntrinsicExceptions {
kNoThrow, // Intrinsic does not throw any exceptions.
kCanThrow // Intrinsic may throw exceptions.
};
class HInvoke : public HInstruction {
public:
size_t InputCount() const OVERRIDE { return inputs_.size(); }
bool NeedsEnvironment() const OVERRIDE;
void SetArgumentAt(size_t index, HInstruction* argument) {
SetRawInputAt(index, argument);
}
// Return the number of arguments. This number can be lower than
// the number of inputs returned by InputCount(), as some invoke
// instructions (e.g. HInvokeStaticOrDirect) can have non-argument
// inputs at the end of their list of inputs.
uint32_t GetNumberOfArguments() const { return number_of_arguments_; }
Primitive::Type GetType() const OVERRIDE { return GetPackedField<ReturnTypeField>(); }
uint32_t GetDexMethodIndex() const { return dex_method_index_; }
const DexFile& GetDexFile() const { return GetEnvironment()->GetDexFile(); }
InvokeType GetOriginalInvokeType() const {
return GetPackedField<OriginalInvokeTypeField>();
}
Intrinsics GetIntrinsic() const {
return intrinsic_;
}
void SetIntrinsic(Intrinsics intrinsic,
IntrinsicNeedsEnvironmentOrCache needs_env_or_cache,
IntrinsicSideEffects side_effects,
IntrinsicExceptions exceptions);
bool IsFromInlinedInvoke() const {
return GetEnvironment()->IsFromInlinedInvoke();
}
bool CanThrow() const OVERRIDE { return GetPackedFlag<kFlagCanThrow>(); }
bool CanBeMoved() const OVERRIDE { return IsIntrinsic(); }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
return intrinsic_ != Intrinsics::kNone && intrinsic_ == other->AsInvoke()->intrinsic_;
}
uint32_t* GetIntrinsicOptimizations() {
return &intrinsic_optimizations_;
}
const uint32_t* GetIntrinsicOptimizations() const {
return &intrinsic_optimizations_;
}
bool IsIntrinsic() const { return intrinsic_ != Intrinsics::kNone; }
DECLARE_ABSTRACT_INSTRUCTION(Invoke);
protected:
static constexpr size_t kFieldOriginalInvokeType = kNumberOfGenericPackedBits;
static constexpr size_t kFieldOriginalInvokeTypeSize =
MinimumBitsToStore(static_cast<size_t>(kMaxInvokeType));
static constexpr size_t kFieldReturnType =
kFieldOriginalInvokeType + kFieldOriginalInvokeTypeSize;
static constexpr size_t kFieldReturnTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kFlagCanThrow = kFieldReturnType + kFieldReturnTypeSize;
static constexpr size_t kNumberOfInvokePackedBits = kFlagCanThrow + 1;
static_assert(kNumberOfInvokePackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using OriginalInvokeTypeField =
BitField<InvokeType, kFieldOriginalInvokeType, kFieldOriginalInvokeTypeSize>;
using ReturnTypeField = BitField<Primitive::Type, kFieldReturnType, kFieldReturnTypeSize>;
HInvoke(ArenaAllocator* arena,
uint32_t number_of_arguments,
uint32_t number_of_other_inputs,
Primitive::Type return_type,
uint32_t dex_pc,
uint32_t dex_method_index,
InvokeType original_invoke_type)
: HInstruction(
SideEffects::AllExceptGCDependency(), dex_pc), // Assume write/read on all fields/arrays.
number_of_arguments_(number_of_arguments),
inputs_(number_of_arguments + number_of_other_inputs,
arena->Adapter(kArenaAllocInvokeInputs)),
dex_method_index_(dex_method_index),
intrinsic_(Intrinsics::kNone),
intrinsic_optimizations_(0) {
SetPackedField<ReturnTypeField>(return_type);
SetPackedField<OriginalInvokeTypeField>(original_invoke_type);
SetPackedFlag<kFlagCanThrow>(true);
}
const HUserRecord<HInstruction*> InputRecordAt(size_t index) const OVERRIDE {
return inputs_[index];
}
void SetRawInputRecordAt(size_t index, const HUserRecord<HInstruction*>& input) OVERRIDE {
inputs_[index] = input;
}
void SetCanThrow(bool can_throw) { SetPackedFlag<kFlagCanThrow>(can_throw); }
uint32_t number_of_arguments_;
ArenaVector<HUserRecord<HInstruction*>> inputs_;
const uint32_t dex_method_index_;
Intrinsics intrinsic_;
// A magic word holding optimizations for intrinsics. See intrinsics.h.
uint32_t intrinsic_optimizations_;
private:
DISALLOW_COPY_AND_ASSIGN(HInvoke);
};
class HInvokeUnresolved : public HInvoke {
public:
HInvokeUnresolved(ArenaAllocator* arena,
uint32_t number_of_arguments,
Primitive::Type return_type,
uint32_t dex_pc,
uint32_t dex_method_index,
InvokeType invoke_type)
: HInvoke(arena,
number_of_arguments,
0u /* number_of_other_inputs */,
return_type,
dex_pc,
dex_method_index,
invoke_type) {
}
DECLARE_INSTRUCTION(InvokeUnresolved);
private:
DISALLOW_COPY_AND_ASSIGN(HInvokeUnresolved);
};
class HInvokeStaticOrDirect : public HInvoke {
public:
// Requirements of this method call regarding the class
// initialization (clinit) check of its declaring class.
enum class ClinitCheckRequirement {
kNone, // Class already initialized.
kExplicit, // Static call having explicit clinit check as last input.
kImplicit, // Static call implicitly requiring a clinit check.
kLast = kImplicit
};
// Determines how to load the target ArtMethod*.
enum class MethodLoadKind {
// Use a String init ArtMethod* loaded from Thread entrypoints.
kStringInit,
// Use the method's own ArtMethod* loaded by the register allocator.
kRecursive,
// Use ArtMethod* at a known address, embed the direct address in the code.
// Used for app->boot calls with non-relocatable image and for JIT-compiled calls.
kDirectAddress,
// Use ArtMethod* at an address that will be known at link time, embed the direct
// address in the code. If the image is relocatable, emit .patch_oat entry.
// Used for app->boot calls with relocatable image and boot->boot calls, whether
// the image relocatable or not.
kDirectAddressWithFixup,
// Load from resolved methods array in the dex cache using a PC-relative load.
// Used when we need to use the dex cache, for example for invoke-static that
// may cause class initialization (the entry may point to a resolution method),
// and we know that we can access the dex cache arrays using a PC-relative load.
kDexCachePcRelative,
// Use ArtMethod* from the resolved methods of the compiled method's own ArtMethod*.
// Used for JIT when we need to use the dex cache. This is also the last-resort-kind
// used when other kinds are unavailable (say, dex cache arrays are not PC-relative)
// or unimplemented or impractical (i.e. slow) on a particular architecture.
kDexCacheViaMethod,
};
// Determines the location of the code pointer.
enum class CodePtrLocation {
// Recursive call, use local PC-relative call instruction.
kCallSelf,
// Use PC-relative call instruction patched at link time.
// Used for calls within an oat file, boot->boot or app->app.
kCallPCRelative,
// Call to a known target address, embed the direct address in code.
// Used for app->boot call with non-relocatable image and for JIT-compiled calls.
kCallDirect,
// Call to a target address that will be known at link time, embed the direct
// address in code. If the image is relocatable, emit .patch_oat entry.
// Used for app->boot calls with relocatable image and boot->boot calls, whether
// the image relocatable or not.
kCallDirectWithFixup,
// Use code pointer from the ArtMethod*.
// Used when we don't know the target code. This is also the last-resort-kind used when
// other kinds are unimplemented or impractical (i.e. slow) on a particular architecture.
kCallArtMethod,
};
struct DispatchInfo {
MethodLoadKind method_load_kind;
CodePtrLocation code_ptr_location;
// The method load data holds
// - thread entrypoint offset for kStringInit method if this is a string init invoke.
// Note that there are multiple string init methods, each having its own offset.
// - the method address for kDirectAddress
// - the dex cache arrays offset for kDexCachePcRel.
uint64_t method_load_data;
uint64_t direct_code_ptr;
};
HInvokeStaticOrDirect(ArenaAllocator* arena,
uint32_t number_of_arguments,
Primitive::Type return_type,
uint32_t dex_pc,
uint32_t method_index,
MethodReference target_method,
DispatchInfo dispatch_info,
InvokeType original_invoke_type,
InvokeType optimized_invoke_type,
ClinitCheckRequirement clinit_check_requirement)
: HInvoke(arena,
number_of_arguments,
// There is potentially one extra argument for the HCurrentMethod node, and
// potentially one other if the clinit check is explicit, and potentially
// one other if the method is a string factory.
(NeedsCurrentMethodInput(dispatch_info.method_load_kind) ? 1u : 0u) +
(clinit_check_requirement == ClinitCheckRequirement::kExplicit ? 1u : 0u),
return_type,
dex_pc,
method_index,
original_invoke_type),
target_method_(target_method),
dispatch_info_(dispatch_info) {
SetPackedField<OptimizedInvokeTypeField>(optimized_invoke_type);
SetPackedField<ClinitCheckRequirementField>(clinit_check_requirement);
}
void SetDispatchInfo(const DispatchInfo& dispatch_info) {
bool had_current_method_input = HasCurrentMethodInput();
bool needs_current_method_input = NeedsCurrentMethodInput(dispatch_info.method_load_kind);
// Using the current method is the default and once we find a better
// method load kind, we should not go back to using the current method.
DCHECK(had_current_method_input || !needs_current_method_input);
if (had_current_method_input && !needs_current_method_input) {
DCHECK_EQ(InputAt(GetSpecialInputIndex()), GetBlock()->GetGraph()->GetCurrentMethod());
RemoveInputAt(GetSpecialInputIndex());
}
dispatch_info_ = dispatch_info;
}
void AddSpecialInput(HInstruction* input) {
// We allow only one special input.
DCHECK(!IsStringInit() && !HasCurrentMethodInput());
DCHECK(InputCount() == GetSpecialInputIndex() ||
(InputCount() == GetSpecialInputIndex() + 1 && IsStaticWithExplicitClinitCheck()));
InsertInputAt(GetSpecialInputIndex(), input);
}
bool CanDoImplicitNullCheckOn(HInstruction* obj ATTRIBUTE_UNUSED) const OVERRIDE {
// We access the method via the dex cache so we can't do an implicit null check.
// TODO: for intrinsics we can generate implicit null checks.
return false;
}
bool CanBeNull() const OVERRIDE {
return GetPackedField<ReturnTypeField>() == Primitive::kPrimNot && !IsStringInit();
}
// Get the index of the special input, if any.
//
// If the invoke HasCurrentMethodInput(), the "special input" is the current
// method pointer; otherwise there may be one platform-specific special input,
// such as PC-relative addressing base.
uint32_t GetSpecialInputIndex() const { return GetNumberOfArguments(); }
bool HasSpecialInput() const { return GetNumberOfArguments() != InputCount(); }
InvokeType GetOptimizedInvokeType() const {
return GetPackedField<OptimizedInvokeTypeField>();
}
void SetOptimizedInvokeType(InvokeType invoke_type) {
SetPackedField<OptimizedInvokeTypeField>(invoke_type);
}
MethodLoadKind GetMethodLoadKind() const { return dispatch_info_.method_load_kind; }
CodePtrLocation GetCodePtrLocation() const { return dispatch_info_.code_ptr_location; }
bool IsRecursive() const { return GetMethodLoadKind() == MethodLoadKind::kRecursive; }
bool NeedsDexCacheOfDeclaringClass() const OVERRIDE;
bool IsStringInit() const { return GetMethodLoadKind() == MethodLoadKind::kStringInit; }
bool HasMethodAddress() const { return GetMethodLoadKind() == MethodLoadKind::kDirectAddress; }
bool HasPcRelativeDexCache() const {
return GetMethodLoadKind() == MethodLoadKind::kDexCachePcRelative;
}
bool HasCurrentMethodInput() const {
// This function can be called only after the invoke has been fully initialized by the builder.
if (NeedsCurrentMethodInput(GetMethodLoadKind())) {
DCHECK(InputAt(GetSpecialInputIndex())->IsCurrentMethod());
return true;
} else {
DCHECK(InputCount() == GetSpecialInputIndex() ||
!InputAt(GetSpecialInputIndex())->IsCurrentMethod());
return false;
}
}
bool HasDirectCodePtr() const { return GetCodePtrLocation() == CodePtrLocation::kCallDirect; }
MethodReference GetTargetMethod() const { return target_method_; }
void SetTargetMethod(MethodReference method) { target_method_ = method; }
int32_t GetStringInitOffset() const {
DCHECK(IsStringInit());
return dispatch_info_.method_load_data;
}
uint64_t GetMethodAddress() const {
DCHECK(HasMethodAddress());
return dispatch_info_.method_load_data;
}
uint32_t GetDexCacheArrayOffset() const {
DCHECK(HasPcRelativeDexCache());
return dispatch_info_.method_load_data;
}
uint64_t GetDirectCodePtr() const {
DCHECK(HasDirectCodePtr());
return dispatch_info_.direct_code_ptr;
}
ClinitCheckRequirement GetClinitCheckRequirement() const {
return GetPackedField<ClinitCheckRequirementField>();
}
// Is this instruction a call to a static method?
bool IsStatic() const {
return GetOriginalInvokeType() == kStatic;
}
// Remove the HClinitCheck or the replacement HLoadClass (set as last input by
// PrepareForRegisterAllocation::VisitClinitCheck() in lieu of the initial HClinitCheck)
// instruction; only relevant for static calls with explicit clinit check.
void RemoveExplicitClinitCheck(ClinitCheckRequirement new_requirement) {
DCHECK(IsStaticWithExplicitClinitCheck());
size_t last_input_index = InputCount() - 1;
HInstruction* last_input = InputAt(last_input_index);
DCHECK(last_input != nullptr);
DCHECK(last_input->IsLoadClass() || last_input->IsClinitCheck()) << last_input->DebugName();
RemoveAsUserOfInput(last_input_index);
inputs_.pop_back();
SetPackedField<ClinitCheckRequirementField>(new_requirement);
DCHECK(!IsStaticWithExplicitClinitCheck());
}
// Is this a call to a static method whose declaring class has an
// explicit initialization check in the graph?
bool IsStaticWithExplicitClinitCheck() const {
return IsStatic() && (GetClinitCheckRequirement() == ClinitCheckRequirement::kExplicit);
}
// Is this a call to a static method whose declaring class has an
// implicit intialization check requirement?
bool IsStaticWithImplicitClinitCheck() const {
return IsStatic() && (GetClinitCheckRequirement() == ClinitCheckRequirement::kImplicit);
}
// Does this method load kind need the current method as an input?
static bool NeedsCurrentMethodInput(MethodLoadKind kind) {
return kind == MethodLoadKind::kRecursive || kind == MethodLoadKind::kDexCacheViaMethod;
}
DECLARE_INSTRUCTION(InvokeStaticOrDirect);
protected:
const HUserRecord<HInstruction*> InputRecordAt(size_t i) const OVERRIDE {
const HUserRecord<HInstruction*> input_record = HInvoke::InputRecordAt(i);
if (kIsDebugBuild && IsStaticWithExplicitClinitCheck() && (i == InputCount() - 1)) {
HInstruction* input = input_record.GetInstruction();
// `input` is the last input of a static invoke marked as having
// an explicit clinit check. It must either be:
// - an art::HClinitCheck instruction, set by art::HGraphBuilder; or
// - an art::HLoadClass instruction, set by art::PrepareForRegisterAllocation.
DCHECK(input != nullptr);
DCHECK(input->IsClinitCheck() || input->IsLoadClass()) << input->DebugName();
}
return input_record;
}
void InsertInputAt(size_t index, HInstruction* input);
void RemoveInputAt(size_t index);
private:
static constexpr size_t kFieldOptimizedInvokeType = kNumberOfInvokePackedBits;
static constexpr size_t kFieldOptimizedInvokeTypeSize =
MinimumBitsToStore(static_cast<size_t>(kMaxInvokeType));
static constexpr size_t kFieldClinitCheckRequirement =
kFieldOptimizedInvokeType + kFieldOptimizedInvokeTypeSize;
static constexpr size_t kFieldClinitCheckRequirementSize =
MinimumBitsToStore(static_cast<size_t>(ClinitCheckRequirement::kLast));
static constexpr size_t kNumberOfInvokeStaticOrDirectPackedBits =
kFieldClinitCheckRequirement + kFieldClinitCheckRequirementSize;
static_assert(kNumberOfInvokeStaticOrDirectPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
using OptimizedInvokeTypeField =
BitField<InvokeType, kFieldOptimizedInvokeType, kFieldOptimizedInvokeTypeSize>;
using ClinitCheckRequirementField = BitField<ClinitCheckRequirement,
kFieldClinitCheckRequirement,
kFieldClinitCheckRequirementSize>;
// The target method may refer to different dex file or method index than the original
// invoke. This happens for sharpened calls and for calls where a method was redeclared
// in derived class to increase visibility.
MethodReference target_method_;
DispatchInfo dispatch_info_;
DISALLOW_COPY_AND_ASSIGN(HInvokeStaticOrDirect);
};
std::ostream& operator<<(std::ostream& os, HInvokeStaticOrDirect::MethodLoadKind rhs);
std::ostream& operator<<(std::ostream& os, HInvokeStaticOrDirect::ClinitCheckRequirement rhs);
class HInvokeVirtual : public HInvoke {
public:
HInvokeVirtual(ArenaAllocator* arena,
uint32_t number_of_arguments,
Primitive::Type return_type,
uint32_t dex_pc,
uint32_t dex_method_index,
uint32_t vtable_index)
: HInvoke(arena, number_of_arguments, 0u, return_type, dex_pc, dex_method_index, kVirtual),
vtable_index_(vtable_index) {}
bool CanDoImplicitNullCheckOn(HInstruction* obj) const OVERRIDE {
// TODO: Add implicit null checks in intrinsics.
return (obj == InputAt(0)) && !GetLocations()->Intrinsified();
}
uint32_t GetVTableIndex() const { return vtable_index_; }
DECLARE_INSTRUCTION(InvokeVirtual);
private:
const uint32_t vtable_index_;
DISALLOW_COPY_AND_ASSIGN(HInvokeVirtual);
};
class HInvokeInterface : public HInvoke {
public:
HInvokeInterface(ArenaAllocator* arena,
uint32_t number_of_arguments,
Primitive::Type return_type,
uint32_t dex_pc,
uint32_t dex_method_index,
uint32_t imt_index)
: HInvoke(arena, number_of_arguments, 0u, return_type, dex_pc, dex_method_index, kInterface),
imt_index_(imt_index) {}
bool CanDoImplicitNullCheckOn(HInstruction* obj) const OVERRIDE {
// TODO: Add implicit null checks in intrinsics.
return (obj == InputAt(0)) && !GetLocations()->Intrinsified();
}
uint32_t GetImtIndex() const { return imt_index_; }
uint32_t GetDexMethodIndex() const { return dex_method_index_; }
DECLARE_INSTRUCTION(InvokeInterface);
private:
const uint32_t imt_index_;
DISALLOW_COPY_AND_ASSIGN(HInvokeInterface);
};
class HNeg : public HUnaryOperation {
public:
HNeg(Primitive::Type result_type, HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HUnaryOperation(result_type, input, dex_pc) {
DCHECK_EQ(result_type, Primitive::PrimitiveKind(input->GetType()));
}
template <typename T> T Compute(T x) const { return -x; }
HConstant* Evaluate(HIntConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(Compute(x->GetValue()), GetDexPc());
}
DECLARE_INSTRUCTION(Neg);
private:
DISALLOW_COPY_AND_ASSIGN(HNeg);
};
class HNewArray : public HExpression<2> {
public:
HNewArray(HInstruction* length,
HCurrentMethod* current_method,
uint32_t dex_pc,
uint16_t type_index,
const DexFile& dex_file,
QuickEntrypointEnum entrypoint)
: HExpression(Primitive::kPrimNot, SideEffects::CanTriggerGC(), dex_pc),
type_index_(type_index),
dex_file_(dex_file),
entrypoint_(entrypoint) {
SetRawInputAt(0, length);
SetRawInputAt(1, current_method);
}
uint16_t GetTypeIndex() const { return type_index_; }
const DexFile& GetDexFile() const { return dex_file_; }
// Calls runtime so needs an environment.
bool NeedsEnvironment() const OVERRIDE { return true; }
// May throw NegativeArraySizeException, OutOfMemoryError, etc.
bool CanThrow() const OVERRIDE { return true; }
bool CanBeNull() const OVERRIDE { return false; }
QuickEntrypointEnum GetEntrypoint() const { return entrypoint_; }
DECLARE_INSTRUCTION(NewArray);
private:
const uint16_t type_index_;
const DexFile& dex_file_;
const QuickEntrypointEnum entrypoint_;
DISALLOW_COPY_AND_ASSIGN(HNewArray);
};
class HAdd : public HBinaryOperation {
public:
HAdd(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
template <typename T> T Compute(T x, T y) const { return x + y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
DECLARE_INSTRUCTION(Add);
private:
DISALLOW_COPY_AND_ASSIGN(HAdd);
};
class HSub : public HBinaryOperation {
public:
HSub(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
template <typename T> T Compute(T x, T y) const { return x - y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
DECLARE_INSTRUCTION(Sub);
private:
DISALLOW_COPY_AND_ASSIGN(HSub);
};
class HMul : public HBinaryOperation {
public:
HMul(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
template <typename T> T Compute(T x, T y) const { return x * y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
DECLARE_INSTRUCTION(Mul);
private:
DISALLOW_COPY_AND_ASSIGN(HMul);
};
class HDiv : public HBinaryOperation {
public:
HDiv(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc)
: HBinaryOperation(result_type, left, right, SideEffectsForArchRuntimeCalls(), dex_pc) {}
template <typename T>
T ComputeIntegral(T x, T y) const {
DCHECK(!Primitive::IsFloatingPointType(GetType())) << GetType();
// Our graph structure ensures we never have 0 for `y` during
// constant folding.
DCHECK_NE(y, 0);
// Special case -1 to avoid getting a SIGFPE on x86(_64).
return (y == -1) ? -x : x / y;
}
template <typename T>
T ComputeFP(T x, T y) const {
DCHECK(Primitive::IsFloatingPointType(GetType())) << GetType();
return x / y;
}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
ComputeIntegral(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
ComputeIntegral(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(
ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(
ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
static SideEffects SideEffectsForArchRuntimeCalls() {
// The generated code can use a runtime call.
return SideEffects::CanTriggerGC();
}
DECLARE_INSTRUCTION(Div);
private:
DISALLOW_COPY_AND_ASSIGN(HDiv);
};
class HRem : public HBinaryOperation {
public:
HRem(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc)
: HBinaryOperation(result_type, left, right, SideEffectsForArchRuntimeCalls(), dex_pc) {}
template <typename T>
T ComputeIntegral(T x, T y) const {
DCHECK(!Primitive::IsFloatingPointType(GetType())) << GetType();
// Our graph structure ensures we never have 0 for `y` during
// constant folding.
DCHECK_NE(y, 0);
// Special case -1 to avoid getting a SIGFPE on x86(_64).
return (y == -1) ? 0 : x % y;
}
template <typename T>
T ComputeFP(T x, T y) const {
DCHECK(Primitive::IsFloatingPointType(GetType())) << GetType();
return std::fmod(x, y);
}
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
ComputeIntegral(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
ComputeIntegral(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x, HFloatConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetFloatConstant(
ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HDoubleConstant* x, HDoubleConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetDoubleConstant(
ComputeFP(x->GetValue(), y->GetValue()), GetDexPc());
}
static SideEffects SideEffectsForArchRuntimeCalls() {
return SideEffects::CanTriggerGC();
}
DECLARE_INSTRUCTION(Rem);
private:
DISALLOW_COPY_AND_ASSIGN(HRem);
};
class HDivZeroCheck : public HExpression<1> {
public:
// `HDivZeroCheck` can trigger GC, as it may call the `ArithmeticException`
// constructor.
HDivZeroCheck(HInstruction* value, uint32_t dex_pc)
: HExpression(value->GetType(), SideEffects::CanTriggerGC(), dex_pc) {
SetRawInputAt(0, value);
}
Primitive::Type GetType() const OVERRIDE { return InputAt(0)->GetType(); }
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(DivZeroCheck);
private:
DISALLOW_COPY_AND_ASSIGN(HDivZeroCheck);
};
class HShl : public HBinaryOperation {
public:
HShl(Primitive::Type result_type,
HInstruction* value,
HInstruction* distance,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, value, distance, SideEffects::None(), dex_pc) {
DCHECK_EQ(result_type, Primitive::PrimitiveKind(value->GetType()));
DCHECK_EQ(Primitive::kPrimInt, Primitive::PrimitiveKind(distance->GetType()));
}
template <typename T>
T Compute(T value, int32_t distance, int32_t max_shift_distance) const {
return value << (distance & max_shift_distance);
}
HConstant* Evaluate(HIntConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxIntShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxLongShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value ATTRIBUTE_UNUSED,
HLongConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for the (long, long) case.";
UNREACHABLE();
}
HConstant* Evaluate(HFloatConstant* value ATTRIBUTE_UNUSED,
HFloatConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* value ATTRIBUTE_UNUSED,
HDoubleConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Shl);
private:
DISALLOW_COPY_AND_ASSIGN(HShl);
};
class HShr : public HBinaryOperation {
public:
HShr(Primitive::Type result_type,
HInstruction* value,
HInstruction* distance,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, value, distance, SideEffects::None(), dex_pc) {
DCHECK_EQ(result_type, Primitive::PrimitiveKind(value->GetType()));
DCHECK_EQ(Primitive::kPrimInt, Primitive::PrimitiveKind(distance->GetType()));
}
template <typename T>
T Compute(T value, int32_t distance, int32_t max_shift_distance) const {
return value >> (distance & max_shift_distance);
}
HConstant* Evaluate(HIntConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxIntShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxLongShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value ATTRIBUTE_UNUSED,
HLongConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for the (long, long) case.";
UNREACHABLE();
}
HConstant* Evaluate(HFloatConstant* value ATTRIBUTE_UNUSED,
HFloatConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* value ATTRIBUTE_UNUSED,
HDoubleConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Shr);
private:
DISALLOW_COPY_AND_ASSIGN(HShr);
};
class HUShr : public HBinaryOperation {
public:
HUShr(Primitive::Type result_type,
HInstruction* value,
HInstruction* distance,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, value, distance, SideEffects::None(), dex_pc) {
DCHECK_EQ(result_type, Primitive::PrimitiveKind(value->GetType()));
DCHECK_EQ(Primitive::kPrimInt, Primitive::PrimitiveKind(distance->GetType()));
}
template <typename T>
T Compute(T value, int32_t distance, int32_t max_shift_distance) const {
typedef typename std::make_unsigned<T>::type V;
V ux = static_cast<V>(value);
return static_cast<T>(ux >> (distance & max_shift_distance));
}
HConstant* Evaluate(HIntConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxIntShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxLongShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value ATTRIBUTE_UNUSED,
HLongConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for the (long, long) case.";
UNREACHABLE();
}
HConstant* Evaluate(HFloatConstant* value ATTRIBUTE_UNUSED,
HFloatConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* value ATTRIBUTE_UNUSED,
HDoubleConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(UShr);
private:
DISALLOW_COPY_AND_ASSIGN(HUShr);
};
class HAnd : public HBinaryOperation {
public:
HAnd(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
template <typename T> T Compute(T x, T y) const { return x & y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(And);
private:
DISALLOW_COPY_AND_ASSIGN(HAnd);
};
class HOr : public HBinaryOperation {
public:
HOr(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
template <typename T> T Compute(T x, T y) const { return x | y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Or);
private:
DISALLOW_COPY_AND_ASSIGN(HOr);
};
class HXor : public HBinaryOperation {
public:
HXor(Primitive::Type result_type,
HInstruction* left,
HInstruction* right,
uint32_t dex_pc = kNoDexPc)
: HBinaryOperation(result_type, left, right, SideEffects::None(), dex_pc) {}
bool IsCommutative() const OVERRIDE { return true; }
template <typename T> T Compute(T x, T y) const { return x ^ y; }
HConstant* Evaluate(HIntConstant* x, HIntConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x, HLongConstant* y) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(x->GetValue(), y->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED,
HFloatConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED,
HDoubleConstant* y ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Xor);
private:
DISALLOW_COPY_AND_ASSIGN(HXor);
};
class HRor : public HBinaryOperation {
public:
HRor(Primitive::Type result_type, HInstruction* value, HInstruction* distance)
: HBinaryOperation(result_type, value, distance) {
DCHECK_EQ(result_type, Primitive::PrimitiveKind(value->GetType()));
DCHECK_EQ(Primitive::kPrimInt, Primitive::PrimitiveKind(distance->GetType()));
}
template <typename T>
T Compute(T value, int32_t distance, int32_t max_shift_value) const {
typedef typename std::make_unsigned<T>::type V;
V ux = static_cast<V>(value);
if ((distance & max_shift_value) == 0) {
return static_cast<T>(ux);
} else {
const V reg_bits = sizeof(T) * 8;
return static_cast<T>(ux >> (distance & max_shift_value)) |
(value << (reg_bits - (distance & max_shift_value)));
}
}
HConstant* Evaluate(HIntConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxIntShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value, HIntConstant* distance) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(
Compute(value->GetValue(), distance->GetValue(), kMaxLongShiftDistance), GetDexPc());
}
HConstant* Evaluate(HLongConstant* value ATTRIBUTE_UNUSED,
HLongConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for the (long, long) case.";
UNREACHABLE();
}
HConstant* Evaluate(HFloatConstant* value ATTRIBUTE_UNUSED,
HFloatConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* value ATTRIBUTE_UNUSED,
HDoubleConstant* distance ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Ror);
private:
DISALLOW_COPY_AND_ASSIGN(HRor);
};
// The value of a parameter in this method. Its location depends on
// the calling convention.
class HParameterValue : public HExpression<0> {
public:
HParameterValue(const DexFile& dex_file,
uint16_t type_index,
uint8_t index,
Primitive::Type parameter_type,
bool is_this = false)
: HExpression(parameter_type, SideEffects::None(), kNoDexPc),
dex_file_(dex_file),
type_index_(type_index),
index_(index) {
SetPackedFlag<kFlagIsThis>(is_this);
SetPackedFlag<kFlagCanBeNull>(!is_this);
}
const DexFile& GetDexFile() const { return dex_file_; }
uint16_t GetTypeIndex() const { return type_index_; }
uint8_t GetIndex() const { return index_; }
bool IsThis() const { return GetPackedFlag<kFlagIsThis>(); }
bool CanBeNull() const OVERRIDE { return GetPackedFlag<kFlagCanBeNull>(); }
void SetCanBeNull(bool can_be_null) { SetPackedFlag<kFlagCanBeNull>(can_be_null); }
DECLARE_INSTRUCTION(ParameterValue);
private:
// Whether or not the parameter value corresponds to 'this' argument.
static constexpr size_t kFlagIsThis = kNumberOfExpressionPackedBits;
static constexpr size_t kFlagCanBeNull = kFlagIsThis + 1;
static constexpr size_t kNumberOfParameterValuePackedBits = kFlagCanBeNull + 1;
static_assert(kNumberOfParameterValuePackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
const DexFile& dex_file_;
const uint16_t type_index_;
// The index of this parameter in the parameters list. Must be less
// than HGraph::number_of_in_vregs_.
const uint8_t index_;
DISALLOW_COPY_AND_ASSIGN(HParameterValue);
};
class HNot : public HUnaryOperation {
public:
HNot(Primitive::Type result_type, HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HUnaryOperation(result_type, input, dex_pc) {}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
template <typename T> T Compute(T x) const { return ~x; }
HConstant* Evaluate(HIntConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetLongConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(Not);
private:
DISALLOW_COPY_AND_ASSIGN(HNot);
};
class HBooleanNot : public HUnaryOperation {
public:
explicit HBooleanNot(HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HUnaryOperation(Primitive::Type::kPrimBoolean, input, dex_pc) {}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
template <typename T> bool Compute(T x) const {
DCHECK(IsUint<1>(x)) << x;
return !x;
}
HConstant* Evaluate(HIntConstant* x) const OVERRIDE {
return GetBlock()->GetGraph()->GetIntConstant(Compute(x->GetValue()), GetDexPc());
}
HConstant* Evaluate(HLongConstant* x ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for long values";
UNREACHABLE();
}
HConstant* Evaluate(HFloatConstant* x ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for float values";
UNREACHABLE();
}
HConstant* Evaluate(HDoubleConstant* x ATTRIBUTE_UNUSED) const OVERRIDE {
LOG(FATAL) << DebugName() << " is not defined for double values";
UNREACHABLE();
}
DECLARE_INSTRUCTION(BooleanNot);
private:
DISALLOW_COPY_AND_ASSIGN(HBooleanNot);
};
class HTypeConversion : public HExpression<1> {
public:
// Instantiate a type conversion of `input` to `result_type`.
HTypeConversion(Primitive::Type result_type, HInstruction* input, uint32_t dex_pc)
: HExpression(result_type,
SideEffectsForArchRuntimeCalls(input->GetType(), result_type),
dex_pc) {
SetRawInputAt(0, input);
// Invariant: We should never generate a conversion to a Boolean value.
DCHECK_NE(Primitive::kPrimBoolean, result_type);
}
HInstruction* GetInput() const { return InputAt(0); }
Primitive::Type GetInputType() const { return GetInput()->GetType(); }
Primitive::Type GetResultType() const { return GetType(); }
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE { return true; }
// Try to statically evaluate the conversion and return a HConstant
// containing the result. If the input cannot be converted, return nullptr.
HConstant* TryStaticEvaluation() const;
static SideEffects SideEffectsForArchRuntimeCalls(Primitive::Type input_type,
Primitive::Type result_type) {
// Some architectures may not require the 'GC' side effects, but at this point
// in the compilation process we do not know what architecture we will
// generate code for, so we must be conservative.
if ((Primitive::IsFloatingPointType(input_type) && Primitive::IsIntegralType(result_type))
|| (input_type == Primitive::kPrimLong && Primitive::IsFloatingPointType(result_type))) {
return SideEffects::CanTriggerGC();
}
return SideEffects::None();
}
DECLARE_INSTRUCTION(TypeConversion);
private:
DISALLOW_COPY_AND_ASSIGN(HTypeConversion);
};
static constexpr uint32_t kNoRegNumber = -1;
class HNullCheck : public HExpression<1> {
public:
// `HNullCheck` can trigger GC, as it may call the `NullPointerException`
// constructor.
HNullCheck(HInstruction* value, uint32_t dex_pc)
: HExpression(value->GetType(), SideEffects::CanTriggerGC(), dex_pc) {
SetRawInputAt(0, value);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
bool CanBeNull() const OVERRIDE { return false; }
DECLARE_INSTRUCTION(NullCheck);
private:
DISALLOW_COPY_AND_ASSIGN(HNullCheck);
};
class FieldInfo : public ValueObject {
public:
FieldInfo(MemberOffset field_offset,
Primitive::Type field_type,
bool is_volatile,
uint32_t index,
uint16_t declaring_class_def_index,
const DexFile& dex_file,
Handle<mirror::DexCache> dex_cache)
: field_offset_(field_offset),
field_type_(field_type),
is_volatile_(is_volatile),
index_(index),
declaring_class_def_index_(declaring_class_def_index),
dex_file_(dex_file),
dex_cache_(dex_cache) {}
MemberOffset GetFieldOffset() const { return field_offset_; }
Primitive::Type GetFieldType() const { return field_type_; }
uint32_t GetFieldIndex() const { return index_; }
uint16_t GetDeclaringClassDefIndex() const { return declaring_class_def_index_;}
const DexFile& GetDexFile() const { return dex_file_; }
bool IsVolatile() const { return is_volatile_; }
Handle<mirror::DexCache> GetDexCache() const { return dex_cache_; }
private:
const MemberOffset field_offset_;
const Primitive::Type field_type_;
const bool is_volatile_;
const uint32_t index_;
const uint16_t declaring_class_def_index_;
const DexFile& dex_file_;
const Handle<mirror::DexCache> dex_cache_;
};
class HInstanceFieldGet : public HExpression<1> {
public:
HInstanceFieldGet(HInstruction* value,
Primitive::Type field_type,
MemberOffset field_offset,
bool is_volatile,
uint32_t field_idx,
uint16_t declaring_class_def_index,
const DexFile& dex_file,
Handle<mirror::DexCache> dex_cache,
uint32_t dex_pc)
: HExpression(field_type,
SideEffects::FieldReadOfType(field_type, is_volatile),
dex_pc),
field_info_(field_offset,
field_type,
is_volatile,
field_idx,
declaring_class_def_index,
dex_file,
dex_cache) {
SetRawInputAt(0, value);
}
bool CanBeMoved() const OVERRIDE { return !IsVolatile(); }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
HInstanceFieldGet* other_get = other->AsInstanceFieldGet();
return GetFieldOffset().SizeValue() == other_get->GetFieldOffset().SizeValue();
}
bool CanDoImplicitNullCheckOn(HInstruction* obj) const OVERRIDE {
return (obj == InputAt(0)) && GetFieldOffset().Uint32Value() < kPageSize;
}
size_t ComputeHashCode() const OVERRIDE {
return (HInstruction::ComputeHashCode() << 7) | GetFieldOffset().SizeValue();
}
const FieldInfo& GetFieldInfo() const { return field_info_; }
MemberOffset GetFieldOffset() const { return field_info_.GetFieldOffset(); }
Primitive::Type GetFieldType() const { return field_info_.GetFieldType(); }
bool IsVolatile() const { return field_info_.IsVolatile(); }
DECLARE_INSTRUCTION(InstanceFieldGet);
private:
const FieldInfo field_info_;
DISALLOW_COPY_AND_ASSIGN(HInstanceFieldGet);
};
class HInstanceFieldSet : public HTemplateInstruction<2> {
public:
HInstanceFieldSet(HInstruction* object,
HInstruction* value,
Primitive::Type field_type,
MemberOffset field_offset,
bool is_volatile,
uint32_t field_idx,
uint16_t declaring_class_def_index,
const DexFile& dex_file,
Handle<mirror::DexCache> dex_cache,
uint32_t dex_pc)
: HTemplateInstruction(SideEffects::FieldWriteOfType(field_type, is_volatile),
dex_pc),
field_info_(field_offset,
field_type,
is_volatile,
field_idx,
declaring_class_def_index,
dex_file,
dex_cache) {
SetPackedFlag<kFlagValueCanBeNull>(true);
SetRawInputAt(0, object);
SetRawInputAt(1, value);
}
bool CanDoImplicitNullCheckOn(HInstruction* obj) const OVERRIDE {
return (obj == InputAt(0)) && GetFieldOffset().Uint32Value() < kPageSize;
}
const FieldInfo& GetFieldInfo() const { return field_info_; }
MemberOffset GetFieldOffset() const { return field_info_.GetFieldOffset(); }
Primitive::Type GetFieldType() const { return field_info_.GetFieldType(); }
bool IsVolatile() const { return field_info_.IsVolatile(); }
HInstruction* GetValue() const { return InputAt(1); }
bool GetValueCanBeNull() const { return GetPackedFlag<kFlagValueCanBeNull>(); }
void ClearValueCanBeNull() { SetPackedFlag<kFlagValueCanBeNull>(false); }
DECLARE_INSTRUCTION(InstanceFieldSet);
private:
static constexpr size_t kFlagValueCanBeNull = kNumberOfGenericPackedBits;
static constexpr size_t kNumberOfInstanceFieldSetPackedBits = kFlagValueCanBeNull + 1;
static_assert(kNumberOfInstanceFieldSetPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
const FieldInfo field_info_;
DISALLOW_COPY_AND_ASSIGN(HInstanceFieldSet);
};
class HArrayGet : public HExpression<2> {
public:
HArrayGet(HInstruction* array,
HInstruction* index,
Primitive::Type type,
uint32_t dex_pc,
SideEffects additional_side_effects = SideEffects::None())
: HExpression(type,
SideEffects::ArrayReadOfType(type).Union(additional_side_effects),
dex_pc) {
SetRawInputAt(0, array);
SetRawInputAt(1, index);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool CanDoImplicitNullCheckOn(HInstruction* obj ATTRIBUTE_UNUSED) const OVERRIDE {
// TODO: We can be smarter here.
// Currently, the array access is always preceded by an ArrayLength or a NullCheck
// which generates the implicit null check. There are cases when these can be removed
// to produce better code. If we ever add optimizations to do so we should allow an
// implicit check here (as long as the address falls in the first page).
return false;
}
bool IsEquivalentOf(HArrayGet* other) const {
bool result = (GetDexPc() == other->GetDexPc());
if (kIsDebugBuild && result) {
DCHECK_EQ(GetBlock(), other->GetBlock());
DCHECK_EQ(GetArray(), other->GetArray());
DCHECK_EQ(GetIndex(), other->GetIndex());
if (Primitive::IsIntOrLongType(GetType())) {
DCHECK(Primitive::IsFloatingPointType(other->GetType())) << other->GetType();
} else {
DCHECK(Primitive::IsFloatingPointType(GetType())) << GetType();
DCHECK(Primitive::IsIntOrLongType(other->GetType())) << other->GetType();
}
}
return result;
}
HInstruction* GetArray() const { return InputAt(0); }
HInstruction* GetIndex() const { return InputAt(1); }
DECLARE_INSTRUCTION(ArrayGet);
private:
DISALLOW_COPY_AND_ASSIGN(HArrayGet);
};
class HArraySet : public HTemplateInstruction<3> {
public:
HArraySet(HInstruction* array,
HInstruction* index,
HInstruction* value,
Primitive::Type expected_component_type,
uint32_t dex_pc,
SideEffects additional_side_effects = SideEffects::None())
: HTemplateInstruction(
SideEffects::ArrayWriteOfType(expected_component_type).Union(
SideEffectsForArchRuntimeCalls(value->GetType())).Union(
additional_side_effects),
dex_pc) {
SetPackedField<ExpectedComponentTypeField>(expected_component_type);
SetPackedFlag<kFlagNeedsTypeCheck>(value->GetType() == Primitive::kPrimNot);
SetPackedFlag<kFlagValueCanBeNull>(true);
SetPackedFlag<kFlagStaticTypeOfArrayIsObjectArray>(false);
SetRawInputAt(0, array);
SetRawInputAt(1, index);
SetRawInputAt(2, value);
}
bool NeedsEnvironment() const OVERRIDE {
// We call a runtime method to throw ArrayStoreException.
return NeedsTypeCheck();
}
// Can throw ArrayStoreException.
bool CanThrow() const OVERRIDE { return NeedsTypeCheck(); }
bool CanDoImplicitNullCheckOn(HInstruction* obj ATTRIBUTE_UNUSED) const OVERRIDE {
// TODO: Same as for ArrayGet.
return false;
}
void ClearNeedsTypeCheck() {
SetPackedFlag<kFlagNeedsTypeCheck>(false);
}
void ClearValueCanBeNull() {
SetPackedFlag<kFlagValueCanBeNull>(false);
}
void SetStaticTypeOfArrayIsObjectArray() {
SetPackedFlag<kFlagStaticTypeOfArrayIsObjectArray>(true);
}
bool GetValueCanBeNull() const { return GetPackedFlag<kFlagValueCanBeNull>(); }
bool NeedsTypeCheck() const { return GetPackedFlag<kFlagNeedsTypeCheck>(); }
bool StaticTypeOfArrayIsObjectArray() const {
return GetPackedFlag<kFlagStaticTypeOfArrayIsObjectArray>();
}
HInstruction* GetArray() const { return InputAt(0); }
HInstruction* GetIndex() const { return InputAt(1); }
HInstruction* GetValue() const { return InputAt(2); }
Primitive::Type GetComponentType() const {
// The Dex format does not type floating point index operations. Since the
// `expected_component_type_` is set during building and can therefore not
// be correct, we also check what is the value type. If it is a floating
// point type, we must use that type.
Primitive::Type value_type = GetValue()->GetType();
return ((value_type == Primitive::kPrimFloat) || (value_type == Primitive::kPrimDouble))
? value_type
: GetRawExpectedComponentType();
}
Primitive::Type GetRawExpectedComponentType() const {
return GetPackedField<ExpectedComponentTypeField>();
}
static SideEffects SideEffectsForArchRuntimeCalls(Primitive::Type value_type) {
return (value_type == Primitive::kPrimNot) ? SideEffects::CanTriggerGC() : SideEffects::None();
}
DECLARE_INSTRUCTION(ArraySet);
private:
static constexpr size_t kFieldExpectedComponentType = kNumberOfGenericPackedBits;
static constexpr size_t kFieldExpectedComponentTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kFlagNeedsTypeCheck =
kFieldExpectedComponentType + kFieldExpectedComponentTypeSize;
static constexpr size_t kFlagValueCanBeNull = kFlagNeedsTypeCheck + 1;
// Cached information for the reference_type_info_ so that codegen
// does not need to inspect the static type.
static constexpr size_t kFlagStaticTypeOfArrayIsObjectArray = kFlagValueCanBeNull + 1;
static constexpr size_t kNumberOfArraySetPackedBits =
kFlagStaticTypeOfArrayIsObjectArray + 1;
static_assert(kNumberOfArraySetPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using ExpectedComponentTypeField =
BitField<Primitive::Type, kFieldExpectedComponentType, kFieldExpectedComponentTypeSize>;
DISALLOW_COPY_AND_ASSIGN(HArraySet);
};
class HArrayLength : public HExpression<1> {
public:
HArrayLength(HInstruction* array, uint32_t dex_pc)
: HExpression(Primitive::kPrimInt, SideEffects::None(), dex_pc) {
// Note that arrays do not change length, so the instruction does not
// depend on any write.
SetRawInputAt(0, array);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool CanDoImplicitNullCheckOn(HInstruction* obj) const OVERRIDE {
return obj == InputAt(0);
}
DECLARE_INSTRUCTION(ArrayLength);
private:
DISALLOW_COPY_AND_ASSIGN(HArrayLength);
};
class HBoundsCheck : public HExpression<2> {
public:
// `HBoundsCheck` can trigger GC, as it may call the `IndexOutOfBoundsException`
// constructor.
HBoundsCheck(HInstruction* index, HInstruction* length, uint32_t dex_pc)
: HExpression(index->GetType(), SideEffects::CanTriggerGC(), dex_pc) {
DCHECK_EQ(Primitive::kPrimInt, Primitive::PrimitiveKind(index->GetType()));
SetRawInputAt(0, index);
SetRawInputAt(1, length);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
HInstruction* GetIndex() const { return InputAt(0); }
DECLARE_INSTRUCTION(BoundsCheck);
private:
DISALLOW_COPY_AND_ASSIGN(HBoundsCheck);
};
class HSuspendCheck : public HTemplateInstruction<0> {
public:
explicit HSuspendCheck(uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::CanTriggerGC(), dex_pc), slow_path_(nullptr) {}
bool NeedsEnvironment() const OVERRIDE {
return true;
}
void SetSlowPath(SlowPathCode* slow_path) { slow_path_ = slow_path; }
SlowPathCode* GetSlowPath() const { return slow_path_; }
DECLARE_INSTRUCTION(SuspendCheck);
private:
// Only used for code generation, in order to share the same slow path between back edges
// of a same loop.
SlowPathCode* slow_path_;
DISALLOW_COPY_AND_ASSIGN(HSuspendCheck);
};
// Pseudo-instruction which provides the native debugger with mapping information.
// It ensures that we can generate line number and local variables at this point.
class HNativeDebugInfo : public HTemplateInstruction<0> {
public:
explicit HNativeDebugInfo(uint32_t dex_pc)
: HTemplateInstruction<0>(SideEffects::None(), dex_pc) {}
bool NeedsEnvironment() const OVERRIDE {
return true;
}
DECLARE_INSTRUCTION(NativeDebugInfo);
private:
DISALLOW_COPY_AND_ASSIGN(HNativeDebugInfo);
};
/**
* Instruction to load a Class object.
*/
class HLoadClass : public HExpression<1> {
public:
HLoadClass(HCurrentMethod* current_method,
uint16_t type_index,
const DexFile& dex_file,
bool is_referrers_class,
uint32_t dex_pc,
bool needs_access_check,
bool is_in_dex_cache)
: HExpression(Primitive::kPrimNot, SideEffectsForArchRuntimeCalls(), dex_pc),
type_index_(type_index),
dex_file_(dex_file),
loaded_class_rti_(ReferenceTypeInfo::CreateInvalid()) {
// Referrers class should not need access check. We never inline unverified
// methods so we can't possibly end up in this situation.
DCHECK(!is_referrers_class || !needs_access_check);
SetPackedFlag<kFlagIsReferrersClass>(is_referrers_class);
SetPackedFlag<kFlagNeedsAccessCheck>(needs_access_check);
SetPackedFlag<kFlagIsInDexCache>(is_in_dex_cache);
SetPackedFlag<kFlagGenerateClInitCheck>(false);
SetRawInputAt(0, current_method);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
// Note that we don't need to test for generate_clinit_check_.
// Whether or not we need to generate the clinit check is processed in
// prepare_for_register_allocator based on existing HInvokes and HClinitChecks.
return other->AsLoadClass()->type_index_ == type_index_ &&
other->AsLoadClass()->GetPackedFields() == GetPackedFields();
}
size_t ComputeHashCode() const OVERRIDE { return type_index_; }
uint16_t GetTypeIndex() const { return type_index_; }
bool CanBeNull() const OVERRIDE { return false; }
bool NeedsEnvironment() const OVERRIDE {
return CanCallRuntime();
}
void SetMustGenerateClinitCheck(bool generate_clinit_check) {
// The entrypoint the code generator is going to call does not do
// clinit of the class.
DCHECK(!NeedsAccessCheck());
SetPackedFlag<kFlagGenerateClInitCheck>(generate_clinit_check);
}
bool CanCallRuntime() const {
return MustGenerateClinitCheck() ||
(!IsReferrersClass() && !IsInDexCache()) ||
NeedsAccessCheck();
}
bool CanThrow() const OVERRIDE {
return CanCallRuntime();
}
ReferenceTypeInfo GetLoadedClassRTI() {
return loaded_class_rti_;
}
void SetLoadedClassRTI(ReferenceTypeInfo rti) {
// Make sure we only set exact types (the loaded class should never be merged).
DCHECK(rti.IsExact());
loaded_class_rti_ = rti;
}
const DexFile& GetDexFile() { return dex_file_; }
bool NeedsDexCacheOfDeclaringClass() const OVERRIDE { return !IsReferrersClass(); }
static SideEffects SideEffectsForArchRuntimeCalls() {
return SideEffects::CanTriggerGC();
}
bool IsReferrersClass() const { return GetPackedFlag<kFlagIsReferrersClass>(); }
bool NeedsAccessCheck() const { return GetPackedFlag<kFlagNeedsAccessCheck>(); }
bool IsInDexCache() const { return GetPackedFlag<kFlagIsInDexCache>(); }
bool MustGenerateClinitCheck() const { return GetPackedFlag<kFlagGenerateClInitCheck>(); }
DECLARE_INSTRUCTION(LoadClass);
private:
static constexpr size_t kFlagIsReferrersClass = kNumberOfExpressionPackedBits;
static constexpr size_t kFlagNeedsAccessCheck = kFlagIsReferrersClass + 1;
static constexpr size_t kFlagIsInDexCache = kFlagNeedsAccessCheck + 1;
// Whether this instruction must generate the initialization check.
// Used for code generation.
static constexpr size_t kFlagGenerateClInitCheck = kFlagIsInDexCache + 1;
static constexpr size_t kNumberOfLoadClassPackedBits = kFlagGenerateClInitCheck + 1;
static_assert(kNumberOfLoadClassPackedBits < kMaxNumberOfPackedBits, "Too many packed fields.");
const uint16_t type_index_;
const DexFile& dex_file_;
ReferenceTypeInfo loaded_class_rti_;
DISALLOW_COPY_AND_ASSIGN(HLoadClass);
};
class HLoadString : public HExpression<1> {
public:
// Determines how to load the String.
enum class LoadKind {
// Use boot image String* address that will be known at link time.
// Used for boot image strings referenced by boot image code in non-PIC mode.
kBootImageLinkTimeAddress,
// Use PC-relative boot image String* address that will be known at link time.
// Used for boot image strings referenced by boot image code in PIC mode.
kBootImageLinkTimePcRelative,
// Use a known boot image String* address, embedded in the code by the codegen.
// Used for boot image strings referenced by apps in AOT- and JIT-compiled code.
// Note: codegen needs to emit a linker patch if indicated by compiler options'
// GetIncludePatchInformation().
kBootImageAddress,
// Load from the resolved strings array at an absolute address.
// Used for strings outside the boot image referenced by JIT-compiled code.
kDexCacheAddress,
// Load from resolved strings array in the dex cache using a PC-relative load.
// Used for strings outside boot image when we know that we can access
// the dex cache arrays using a PC-relative load.
kDexCachePcRelative,
// Load from resolved strings array accessed through the class loaded from
// the compiled method's own ArtMethod*. This is the default access type when
// all other types are unavailable.
kDexCacheViaMethod,
kLast = kDexCacheViaMethod
};
HLoadString(HCurrentMethod* current_method,
uint32_t string_index,
const DexFile& dex_file,
uint32_t dex_pc)
: HExpression(Primitive::kPrimNot, SideEffectsForArchRuntimeCalls(), dex_pc),
string_index_(string_index) {
SetPackedFlag<kFlagIsInDexCache>(false);
SetPackedField<LoadKindField>(LoadKind::kDexCacheViaMethod);
load_data_.ref.dex_file = &dex_file;
SetRawInputAt(0, current_method);
}
void SetLoadKindWithAddress(LoadKind load_kind, uint64_t address) {
DCHECK(HasAddress(load_kind));
load_data_.address = address;
SetLoadKindInternal(load_kind);
}
void SetLoadKindWithStringReference(LoadKind load_kind,
const DexFile& dex_file,
uint32_t string_index) {
DCHECK(HasStringReference(load_kind));
load_data_.ref.dex_file = &dex_file;
string_index_ = string_index;
SetLoadKindInternal(load_kind);
}
void SetLoadKindWithDexCacheReference(LoadKind load_kind,
const DexFile& dex_file,
uint32_t element_index) {
DCHECK(HasDexCacheReference(load_kind));
load_data_.ref.dex_file = &dex_file;
load_data_.ref.dex_cache_element_index = element_index;
SetLoadKindInternal(load_kind);
}
LoadKind GetLoadKind() const {
return GetPackedField<LoadKindField>();
}
const DexFile& GetDexFile() const;
uint32_t GetStringIndex() const {
DCHECK(HasStringReference(GetLoadKind()) || /* For slow paths. */ !IsInDexCache());
return string_index_;
}
uint32_t GetDexCacheElementOffset() const;
uint64_t GetAddress() const {
DCHECK(HasAddress(GetLoadKind()));
return load_data_.address;
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE;
size_t ComputeHashCode() const OVERRIDE { return string_index_; }
// Will call the runtime if we need to load the string through
// the dex cache and the string is not guaranteed to be there yet.
bool NeedsEnvironment() const OVERRIDE {
LoadKind load_kind = GetLoadKind();
if (load_kind == LoadKind::kBootImageLinkTimeAddress ||
load_kind == LoadKind::kBootImageLinkTimePcRelative ||
load_kind == LoadKind::kBootImageAddress) {
return false;
}
return !IsInDexCache();
}
bool NeedsDexCacheOfDeclaringClass() const OVERRIDE {
return GetLoadKind() == LoadKind::kDexCacheViaMethod;
}
bool CanBeNull() const OVERRIDE { return false; }
bool CanThrow() const OVERRIDE { return NeedsEnvironment(); }
static SideEffects SideEffectsForArchRuntimeCalls() {
return SideEffects::CanTriggerGC();
}
bool IsInDexCache() const { return GetPackedFlag<kFlagIsInDexCache>(); }
void MarkInDexCache() {
SetPackedFlag<kFlagIsInDexCache>(true);
DCHECK(!NeedsEnvironment());
RemoveEnvironment();
SetSideEffects(SideEffects::None());
}
size_t InputCount() const OVERRIDE {
return (InputAt(0) != nullptr) ? 1u : 0u;
}
void AddSpecialInput(HInstruction* special_input);
DECLARE_INSTRUCTION(LoadString);
private:
static constexpr size_t kFlagIsInDexCache = kNumberOfExpressionPackedBits;
static constexpr size_t kFieldLoadKind = kFlagIsInDexCache + 1;
static constexpr size_t kFieldLoadKindSize =
MinimumBitsToStore(static_cast<size_t>(LoadKind::kLast));
static constexpr size_t kNumberOfLoadStringPackedBits = kFieldLoadKind + kFieldLoadKindSize;
static_assert(kNumberOfLoadStringPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using LoadKindField = BitField<LoadKind, kFieldLoadKind, kFieldLoadKindSize>;
static bool HasStringReference(LoadKind load_kind) {
return load_kind == LoadKind::kBootImageLinkTimeAddress ||
load_kind == LoadKind::kBootImageLinkTimePcRelative ||
load_kind == LoadKind::kDexCacheViaMethod;
}
static bool HasAddress(LoadKind load_kind) {
return load_kind == LoadKind::kBootImageAddress || load_kind == LoadKind::kDexCacheAddress;
}
static bool HasDexCacheReference(LoadKind load_kind) {
return load_kind == LoadKind::kDexCachePcRelative;
}
void SetLoadKindInternal(LoadKind load_kind);
// String index serves also as the hash code and it's also needed for slow-paths,
// so it must not be overwritten with other load data.
uint32_t string_index_;
union {
struct {
const DexFile* dex_file; // For string reference and dex cache reference.
uint32_t dex_cache_element_index; // Only for dex cache reference.
} ref;
uint64_t address; // Up to 64-bit, needed for kDexCacheAddress on 64-bit targets.
} load_data_;
DISALLOW_COPY_AND_ASSIGN(HLoadString);
};
std::ostream& operator<<(std::ostream& os, HLoadString::LoadKind rhs);
// Note: defined outside class to see operator<<(., HLoadString::LoadKind).
inline const DexFile& HLoadString::GetDexFile() const {
DCHECK(HasStringReference(GetLoadKind()) || HasDexCacheReference(GetLoadKind()))
<< GetLoadKind();
return *load_data_.ref.dex_file;
}
// Note: defined outside class to see operator<<(., HLoadString::LoadKind).
inline uint32_t HLoadString::GetDexCacheElementOffset() const {
DCHECK(HasDexCacheReference(GetLoadKind())) << GetLoadKind();
return load_data_.ref.dex_cache_element_index;
}
// Note: defined outside class to see operator<<(., HLoadString::LoadKind).
inline void HLoadString::AddSpecialInput(HInstruction* special_input) {
// The special input is used for PC-relative loads on some architectures.
DCHECK(GetLoadKind() == LoadKind::kBootImageLinkTimePcRelative ||
GetLoadKind() == LoadKind::kDexCachePcRelative) << GetLoadKind();
DCHECK(InputAt(0) == nullptr);
SetRawInputAt(0u, special_input);
special_input->AddUseAt(this, 0);
}
/**
* Performs an initialization check on its Class object input.
*/
class HClinitCheck : public HExpression<1> {
public:
HClinitCheck(HLoadClass* constant, uint32_t dex_pc)
: HExpression(
Primitive::kPrimNot,
SideEffects::AllChanges(), // Assume write/read on all fields/arrays.
dex_pc) {
SetRawInputAt(0, constant);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE {
// May call runtime to initialize the class.
return true;
}
bool CanThrow() const OVERRIDE { return true; }
HLoadClass* GetLoadClass() const { return InputAt(0)->AsLoadClass(); }
DECLARE_INSTRUCTION(ClinitCheck);
private:
DISALLOW_COPY_AND_ASSIGN(HClinitCheck);
};
class HStaticFieldGet : public HExpression<1> {
public:
HStaticFieldGet(HInstruction* cls,
Primitive::Type field_type,
MemberOffset field_offset,
bool is_volatile,
uint32_t field_idx,
uint16_t declaring_class_def_index,
const DexFile& dex_file,
Handle<mirror::DexCache> dex_cache,
uint32_t dex_pc)
: HExpression(field_type,
SideEffects::FieldReadOfType(field_type, is_volatile),
dex_pc),
field_info_(field_offset,
field_type,
is_volatile,
field_idx,
declaring_class_def_index,
dex_file,
dex_cache) {
SetRawInputAt(0, cls);
}
bool CanBeMoved() const OVERRIDE { return !IsVolatile(); }
bool InstructionDataEquals(HInstruction* other) const OVERRIDE {
HStaticFieldGet* other_get = other->AsStaticFieldGet();
return GetFieldOffset().SizeValue() == other_get->GetFieldOffset().SizeValue();
}
size_t ComputeHashCode() const OVERRIDE {
return (HInstruction::ComputeHashCode() << 7) | GetFieldOffset().SizeValue();
}
const FieldInfo& GetFieldInfo() const { return field_info_; }
MemberOffset GetFieldOffset() const { return field_info_.GetFieldOffset(); }
Primitive::Type GetFieldType() const { return field_info_.GetFieldType(); }
bool IsVolatile() const { return field_info_.IsVolatile(); }
DECLARE_INSTRUCTION(StaticFieldGet);
private:
const FieldInfo field_info_;
DISALLOW_COPY_AND_ASSIGN(HStaticFieldGet);
};
class HStaticFieldSet : public HTemplateInstruction<2> {
public:
HStaticFieldSet(HInstruction* cls,
HInstruction* value,
Primitive::Type field_type,
MemberOffset field_offset,
bool is_volatile,
uint32_t field_idx,
uint16_t declaring_class_def_index,
const DexFile& dex_file,
Handle<mirror::DexCache> dex_cache,
uint32_t dex_pc)
: HTemplateInstruction(SideEffects::FieldWriteOfType(field_type, is_volatile),
dex_pc),
field_info_(field_offset,
field_type,
is_volatile,
field_idx,
declaring_class_def_index,
dex_file,
dex_cache) {
SetPackedFlag<kFlagValueCanBeNull>(true);
SetRawInputAt(0, cls);
SetRawInputAt(1, value);
}
const FieldInfo& GetFieldInfo() const { return field_info_; }
MemberOffset GetFieldOffset() const { return field_info_.GetFieldOffset(); }
Primitive::Type GetFieldType() const { return field_info_.GetFieldType(); }
bool IsVolatile() const { return field_info_.IsVolatile(); }
HInstruction* GetValue() const { return InputAt(1); }
bool GetValueCanBeNull() const { return GetPackedFlag<kFlagValueCanBeNull>(); }
void ClearValueCanBeNull() { SetPackedFlag<kFlagValueCanBeNull>(false); }
DECLARE_INSTRUCTION(StaticFieldSet);
private:
static constexpr size_t kFlagValueCanBeNull = kNumberOfGenericPackedBits;
static constexpr size_t kNumberOfStaticFieldSetPackedBits = kFlagValueCanBeNull + 1;
static_assert(kNumberOfStaticFieldSetPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
const FieldInfo field_info_;
DISALLOW_COPY_AND_ASSIGN(HStaticFieldSet);
};
class HUnresolvedInstanceFieldGet : public HExpression<1> {
public:
HUnresolvedInstanceFieldGet(HInstruction* obj,
Primitive::Type field_type,
uint32_t field_index,
uint32_t dex_pc)
: HExpression(field_type, SideEffects::AllExceptGCDependency(), dex_pc),
field_index_(field_index) {
SetRawInputAt(0, obj);
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
Primitive::Type GetFieldType() const { return GetType(); }
uint32_t GetFieldIndex() const { return field_index_; }
DECLARE_INSTRUCTION(UnresolvedInstanceFieldGet);
private:
const uint32_t field_index_;
DISALLOW_COPY_AND_ASSIGN(HUnresolvedInstanceFieldGet);
};
class HUnresolvedInstanceFieldSet : public HTemplateInstruction<2> {
public:
HUnresolvedInstanceFieldSet(HInstruction* obj,
HInstruction* value,
Primitive::Type field_type,
uint32_t field_index,
uint32_t dex_pc)
: HTemplateInstruction(SideEffects::AllExceptGCDependency(), dex_pc),
field_index_(field_index) {
SetPackedField<FieldTypeField>(field_type);
DCHECK_EQ(Primitive::PrimitiveKind(field_type), Primitive::PrimitiveKind(value->GetType()));
SetRawInputAt(0, obj);
SetRawInputAt(1, value);
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
Primitive::Type GetFieldType() const { return GetPackedField<FieldTypeField>(); }
uint32_t GetFieldIndex() const { return field_index_; }
DECLARE_INSTRUCTION(UnresolvedInstanceFieldSet);
private:
static constexpr size_t kFieldFieldType = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldFieldTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kNumberOfUnresolvedStaticFieldSetPackedBits =
kFieldFieldType + kFieldFieldTypeSize;
static_assert(kNumberOfUnresolvedStaticFieldSetPackedBits <= HInstruction::kMaxNumberOfPackedBits,
"Too many packed fields.");
using FieldTypeField = BitField<Primitive::Type, kFieldFieldType, kFieldFieldTypeSize>;
const uint32_t field_index_;
DISALLOW_COPY_AND_ASSIGN(HUnresolvedInstanceFieldSet);
};
class HUnresolvedStaticFieldGet : public HExpression<0> {
public:
HUnresolvedStaticFieldGet(Primitive::Type field_type,
uint32_t field_index,
uint32_t dex_pc)
: HExpression(field_type, SideEffects::AllExceptGCDependency(), dex_pc),
field_index_(field_index) {
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
Primitive::Type GetFieldType() const { return GetType(); }
uint32_t GetFieldIndex() const { return field_index_; }
DECLARE_INSTRUCTION(UnresolvedStaticFieldGet);
private:
const uint32_t field_index_;
DISALLOW_COPY_AND_ASSIGN(HUnresolvedStaticFieldGet);
};
class HUnresolvedStaticFieldSet : public HTemplateInstruction<1> {
public:
HUnresolvedStaticFieldSet(HInstruction* value,
Primitive::Type field_type,
uint32_t field_index,
uint32_t dex_pc)
: HTemplateInstruction(SideEffects::AllExceptGCDependency(), dex_pc),
field_index_(field_index) {
SetPackedField<FieldTypeField>(field_type);
DCHECK_EQ(Primitive::PrimitiveKind(field_type), Primitive::PrimitiveKind(value->GetType()));
SetRawInputAt(0, value);
}
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
Primitive::Type GetFieldType() const { return GetPackedField<FieldTypeField>(); }
uint32_t GetFieldIndex() const { return field_index_; }
DECLARE_INSTRUCTION(UnresolvedStaticFieldSet);
private:
static constexpr size_t kFieldFieldType = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldFieldTypeSize =
MinimumBitsToStore(static_cast<size_t>(Primitive::kPrimLast));
static constexpr size_t kNumberOfUnresolvedStaticFieldSetPackedBits =
kFieldFieldType + kFieldFieldTypeSize;
static_assert(kNumberOfUnresolvedStaticFieldSetPackedBits <= HInstruction::kMaxNumberOfPackedBits,
"Too many packed fields.");
using FieldTypeField = BitField<Primitive::Type, kFieldFieldType, kFieldFieldTypeSize>;
const uint32_t field_index_;
DISALLOW_COPY_AND_ASSIGN(HUnresolvedStaticFieldSet);
};
// Implement the move-exception DEX instruction.
class HLoadException : public HExpression<0> {
public:
explicit HLoadException(uint32_t dex_pc = kNoDexPc)
: HExpression(Primitive::kPrimNot, SideEffects::None(), dex_pc) {}
bool CanBeNull() const OVERRIDE { return false; }
DECLARE_INSTRUCTION(LoadException);
private:
DISALLOW_COPY_AND_ASSIGN(HLoadException);
};
// Implicit part of move-exception which clears thread-local exception storage.
// Must not be removed because the runtime expects the TLS to get cleared.
class HClearException : public HTemplateInstruction<0> {
public:
explicit HClearException(uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::AllWrites(), dex_pc) {}
DECLARE_INSTRUCTION(ClearException);
private:
DISALLOW_COPY_AND_ASSIGN(HClearException);
};
class HThrow : public HTemplateInstruction<1> {
public:
HThrow(HInstruction* exception, uint32_t dex_pc)
: HTemplateInstruction(SideEffects::CanTriggerGC(), dex_pc) {
SetRawInputAt(0, exception);
}
bool IsControlFlow() const OVERRIDE { return true; }
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE { return true; }
DECLARE_INSTRUCTION(Throw);
private:
DISALLOW_COPY_AND_ASSIGN(HThrow);
};
/**
* Implementation strategies for the code generator of a HInstanceOf
* or `HCheckCast`.
*/
enum class TypeCheckKind {
kUnresolvedCheck, // Check against an unresolved type.
kExactCheck, // Can do a single class compare.
kClassHierarchyCheck, // Can just walk the super class chain.
kAbstractClassCheck, // Can just walk the super class chain, starting one up.
kInterfaceCheck, // No optimization yet when checking against an interface.
kArrayObjectCheck, // Can just check if the array is not primitive.
kArrayCheck, // No optimization yet when checking against a generic array.
kLast = kArrayCheck
};
std::ostream& operator<<(std::ostream& os, TypeCheckKind rhs);
class HInstanceOf : public HExpression<2> {
public:
HInstanceOf(HInstruction* object,
HLoadClass* constant,
TypeCheckKind check_kind,
uint32_t dex_pc)
: HExpression(Primitive::kPrimBoolean,
SideEffectsForArchRuntimeCalls(check_kind),
dex_pc) {
SetPackedField<TypeCheckKindField>(check_kind);
SetPackedFlag<kFlagMustDoNullCheck>(true);
SetRawInputAt(0, object);
SetRawInputAt(1, constant);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE {
return CanCallRuntime(GetTypeCheckKind());
}
// Used only in code generation.
bool MustDoNullCheck() const { return GetPackedFlag<kFlagMustDoNullCheck>(); }
void ClearMustDoNullCheck() { SetPackedFlag<kFlagMustDoNullCheck>(false); }
TypeCheckKind GetTypeCheckKind() const { return GetPackedField<TypeCheckKindField>(); }
bool IsExactCheck() const { return GetTypeCheckKind() == TypeCheckKind::kExactCheck; }
static bool CanCallRuntime(TypeCheckKind check_kind) {
// Mips currently does runtime calls for any other checks.
return check_kind != TypeCheckKind::kExactCheck;
}
static SideEffects SideEffectsForArchRuntimeCalls(TypeCheckKind check_kind) {
return CanCallRuntime(check_kind) ? SideEffects::CanTriggerGC() : SideEffects::None();
}
DECLARE_INSTRUCTION(InstanceOf);
private:
static constexpr size_t kFieldTypeCheckKind = kNumberOfExpressionPackedBits;
static constexpr size_t kFieldTypeCheckKindSize =
MinimumBitsToStore(static_cast<size_t>(TypeCheckKind::kLast));
static constexpr size_t kFlagMustDoNullCheck = kFieldTypeCheckKind + kFieldTypeCheckKindSize;
static constexpr size_t kNumberOfInstanceOfPackedBits = kFlagMustDoNullCheck + 1;
static_assert(kNumberOfInstanceOfPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using TypeCheckKindField = BitField<TypeCheckKind, kFieldTypeCheckKind, kFieldTypeCheckKindSize>;
DISALLOW_COPY_AND_ASSIGN(HInstanceOf);
};
class HBoundType : public HExpression<1> {
public:
HBoundType(HInstruction* input, uint32_t dex_pc = kNoDexPc)
: HExpression(Primitive::kPrimNot, SideEffects::None(), dex_pc),
upper_bound_(ReferenceTypeInfo::CreateInvalid()) {
SetPackedFlag<kFlagUpperCanBeNull>(true);
SetPackedFlag<kFlagCanBeNull>(true);
DCHECK_EQ(input->GetType(), Primitive::kPrimNot);
SetRawInputAt(0, input);
}
// {Get,Set}Upper* should only be used in reference type propagation.
const ReferenceTypeInfo& GetUpperBound() const { return upper_bound_; }
bool GetUpperCanBeNull() const { return GetPackedFlag<kFlagUpperCanBeNull>(); }
void SetUpperBound(const ReferenceTypeInfo& upper_bound, bool can_be_null);
void SetCanBeNull(bool can_be_null) {
DCHECK(GetUpperCanBeNull() || !can_be_null);
SetPackedFlag<kFlagCanBeNull>(can_be_null);
}
bool CanBeNull() const OVERRIDE { return GetPackedFlag<kFlagCanBeNull>(); }
DECLARE_INSTRUCTION(BoundType);
private:
// Represents the top constraint that can_be_null_ cannot exceed (i.e. if this
// is false then CanBeNull() cannot be true).
static constexpr size_t kFlagUpperCanBeNull = kNumberOfExpressionPackedBits;
static constexpr size_t kFlagCanBeNull = kFlagUpperCanBeNull + 1;
static constexpr size_t kNumberOfBoundTypePackedBits = kFlagCanBeNull + 1;
static_assert(kNumberOfBoundTypePackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
// Encodes the most upper class that this instruction can have. In other words
// it is always the case that GetUpperBound().IsSupertypeOf(GetReferenceType()).
// It is used to bound the type in cases like:
// if (x instanceof ClassX) {
// // uper_bound_ will be ClassX
// }
ReferenceTypeInfo upper_bound_;
DISALLOW_COPY_AND_ASSIGN(HBoundType);
};
class HCheckCast : public HTemplateInstruction<2> {
public:
HCheckCast(HInstruction* object,
HLoadClass* constant,
TypeCheckKind check_kind,
uint32_t dex_pc)
: HTemplateInstruction(SideEffects::CanTriggerGC(), dex_pc) {
SetPackedField<TypeCheckKindField>(check_kind);
SetPackedFlag<kFlagMustDoNullCheck>(true);
SetRawInputAt(0, object);
SetRawInputAt(1, constant);
}
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE {
return true;
}
bool NeedsEnvironment() const OVERRIDE {
// Instruction may throw a CheckCastError.
return true;
}
bool CanThrow() const OVERRIDE { return true; }
bool MustDoNullCheck() const { return GetPackedFlag<kFlagMustDoNullCheck>(); }
void ClearMustDoNullCheck() { SetPackedFlag<kFlagMustDoNullCheck>(false); }
TypeCheckKind GetTypeCheckKind() const { return GetPackedField<TypeCheckKindField>(); }
bool IsExactCheck() const { return GetTypeCheckKind() == TypeCheckKind::kExactCheck; }
DECLARE_INSTRUCTION(CheckCast);
private:
static constexpr size_t kFieldTypeCheckKind = kNumberOfGenericPackedBits;
static constexpr size_t kFieldTypeCheckKindSize =
MinimumBitsToStore(static_cast<size_t>(TypeCheckKind::kLast));
static constexpr size_t kFlagMustDoNullCheck = kFieldTypeCheckKind + kFieldTypeCheckKindSize;
static constexpr size_t kNumberOfCheckCastPackedBits = kFlagMustDoNullCheck + 1;
static_assert(kNumberOfCheckCastPackedBits <= kMaxNumberOfPackedBits, "Too many packed fields.");
using TypeCheckKindField = BitField<TypeCheckKind, kFieldTypeCheckKind, kFieldTypeCheckKindSize>;
DISALLOW_COPY_AND_ASSIGN(HCheckCast);
};
class HMemoryBarrier : public HTemplateInstruction<0> {
public:
explicit HMemoryBarrier(MemBarrierKind barrier_kind, uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(
SideEffects::AllWritesAndReads(), dex_pc) { // Assume write/read on all fields/arrays.
SetPackedField<BarrierKindField>(barrier_kind);
}
MemBarrierKind GetBarrierKind() { return GetPackedField<BarrierKindField>(); }
DECLARE_INSTRUCTION(MemoryBarrier);
private:
static constexpr size_t kFieldBarrierKind = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldBarrierKindSize =
MinimumBitsToStore(static_cast<size_t>(kLastBarrierKind));
static constexpr size_t kNumberOfMemoryBarrierPackedBits =
kFieldBarrierKind + kFieldBarrierKindSize;
static_assert(kNumberOfMemoryBarrierPackedBits <= kMaxNumberOfPackedBits,
"Too many packed fields.");
using BarrierKindField = BitField<MemBarrierKind, kFieldBarrierKind, kFieldBarrierKindSize>;
DISALLOW_COPY_AND_ASSIGN(HMemoryBarrier);
};
class HMonitorOperation : public HTemplateInstruction<1> {
public:
enum class OperationKind {
kEnter,
kExit,
kLast = kExit
};
HMonitorOperation(HInstruction* object, OperationKind kind, uint32_t dex_pc)
: HTemplateInstruction(
SideEffects::AllExceptGCDependency(), // Assume write/read on all fields/arrays.
dex_pc) {
SetPackedField<OperationKindField>(kind);
SetRawInputAt(0, object);
}
// Instruction may go into runtime, so we need an environment.
bool NeedsEnvironment() const OVERRIDE { return true; }
bool CanThrow() const OVERRIDE {
// Verifier guarantees that monitor-exit cannot throw.
// This is important because it allows the HGraphBuilder to remove
// a dead throw-catch loop generated for `synchronized` blocks/methods.
return IsEnter();
}
OperationKind GetOperationKind() const { return GetPackedField<OperationKindField>(); }
bool IsEnter() const { return GetOperationKind() == OperationKind::kEnter; }
DECLARE_INSTRUCTION(MonitorOperation);
private:
static constexpr size_t kFieldOperationKind = HInstruction::kNumberOfGenericPackedBits;
static constexpr size_t kFieldOperationKindSize =
MinimumBitsToStore(static_cast<size_t>(OperationKind::kLast));
static constexpr size_t kNumberOfMonitorOperationPackedBits =
kFieldOperationKind + kFieldOperationKindSize;
static_assert(kNumberOfMonitorOperationPackedBits <= HInstruction::kMaxNumberOfPackedBits,
"Too many packed fields.");
using OperationKindField = BitField<OperationKind, kFieldOperationKind, kFieldOperationKindSize>;
private:
DISALLOW_COPY_AND_ASSIGN(HMonitorOperation);
};
class HSelect : public HExpression<3> {
public:
HSelect(HInstruction* condition,
HInstruction* true_value,
HInstruction* false_value,
uint32_t dex_pc)
: HExpression(HPhi::ToPhiType(true_value->GetType()), SideEffects::None(), dex_pc) {
DCHECK_EQ(HPhi::ToPhiType(true_value->GetType()), HPhi::ToPhiType(false_value->GetType()));
// First input must be `true_value` or `false_value` to allow codegens to
// use the SameAsFirstInput allocation policy. We make it `false_value`, so
// that architectures which implement HSelect as a conditional move also
// will not need to invert the condition.
SetRawInputAt(0, false_value);
SetRawInputAt(1, true_value);
SetRawInputAt(2, condition);
}
HInstruction* GetFalseValue() const { return InputAt(0); }
HInstruction* GetTrueValue() const { return InputAt(1); }
HInstruction* GetCondition() const { return InputAt(2); }
bool CanBeMoved() const OVERRIDE { return true; }
bool InstructionDataEquals(HInstruction* other ATTRIBUTE_UNUSED) const OVERRIDE { return true; }
bool CanBeNull() const OVERRIDE {
return GetTrueValue()->CanBeNull() || GetFalseValue()->CanBeNull();
}
DECLARE_INSTRUCTION(Select);
private:
DISALLOW_COPY_AND_ASSIGN(HSelect);
};
class MoveOperands : public ArenaObject<kArenaAllocMoveOperands> {
public:
MoveOperands(Location source,
Location destination,
Primitive::Type type,
HInstruction* instruction)
: source_(source), destination_(destination), type_(type), instruction_(instruction) {}
Location GetSource() const { return source_; }
Location GetDestination() const { return destination_; }
void SetSource(Location value) { source_ = value; }
void SetDestination(Location value) { destination_ = value; }
// The parallel move resolver marks moves as "in-progress" by clearing the
// destination (but not the source).
Location MarkPending() {
DCHECK(!IsPending());
Location dest = destination_;
destination_ = Location::NoLocation();
return dest;
}
void ClearPending(Location dest) {
DCHECK(IsPending());
destination_ = dest;
}
bool IsPending() const {
DCHECK(source_.IsValid() || destination_.IsInvalid());
return destination_.IsInvalid() && source_.IsValid();
}
// True if this blocks a move from the given location.
bool Blocks(Location loc) const {
return !IsEliminated() && source_.OverlapsWith(loc);
}
// A move is redundant if it's been eliminated, if its source and
// destination are the same, or if its destination is unneeded.
bool IsRedundant() const {
return IsEliminated() || destination_.IsInvalid() || source_.Equals(destination_);
}
// We clear both operands to indicate move that's been eliminated.
void Eliminate() {
source_ = destination_ = Location::NoLocation();
}
bool IsEliminated() const {
DCHECK(!source_.IsInvalid() || destination_.IsInvalid());
return source_.IsInvalid();
}
Primitive::Type GetType() const { return type_; }
bool Is64BitMove() const {
return Primitive::Is64BitType(type_);
}
HInstruction* GetInstruction() const { return instruction_; }
private:
Location source_;
Location destination_;
// The type this move is for.
Primitive::Type type_;
// The instruction this move is assocatied with. Null when this move is
// for moving an input in the expected locations of user (including a phi user).
// This is only used in debug mode, to ensure we do not connect interval siblings
// in the same parallel move.
HInstruction* instruction_;
};
std::ostream& operator<<(std::ostream& os, const MoveOperands& rhs);
static constexpr size_t kDefaultNumberOfMoves = 4;
class HParallelMove : public HTemplateInstruction<0> {
public:
explicit HParallelMove(ArenaAllocator* arena, uint32_t dex_pc = kNoDexPc)
: HTemplateInstruction(SideEffects::None(), dex_pc),
moves_(arena->Adapter(kArenaAllocMoveOperands)) {
moves_.reserve(kDefaultNumberOfMoves);
}
void AddMove(Location source,
Location destination,
Primitive::Type type,
HInstruction* instruction) {
DCHECK(source.IsValid());
DCHECK(destination.IsValid());
if (kIsDebugBuild) {
if (instruction != nullptr) {
for (const MoveOperands& move : moves_) {
if (move.GetInstruction() == instruction) {
// Special case the situation where the move is for the spill slot
// of the instruction.
if ((GetPrevious() == instruction)
|| ((GetPrevious() == nullptr)
&& instruction->IsPhi()
&& instruction->GetBlock() == GetBlock())) {
DCHECK_NE(destination.GetKind(), move.GetDestination().GetKind())
<< "Doing parallel moves for the same instruction.";
} else {
DCHECK(false) << "Doing parallel moves for the same instruction.";
}
}
}
}
for (const MoveOperands& move : moves_) {
DCHECK(!destination.OverlapsWith(move.GetDestination()))
<< "Overlapped destination for two moves in a parallel move: "
<< move.GetSource() << " ==> " << move.GetDestination() << " and "
<< source << " ==> " << destination;
}
}
moves_.emplace_back(source, destination, type, instruction);
}
MoveOperands* MoveOperandsAt(size_t index) {
return &moves_[index];
}
size_t NumMoves() const { return moves_.size(); }
DECLARE_INSTRUCTION(ParallelMove);
private:
ArenaVector<MoveOperands> moves_;
DISALLOW_COPY_AND_ASSIGN(HParallelMove);
};
} // namespace art
#if defined(ART_ENABLE_CODEGEN_arm) || defined(ART_ENABLE_CODEGEN_arm64)
#include "nodes_shared.h"
#endif
#ifdef ART_ENABLE_CODEGEN_arm
#include "nodes_arm.h"
#endif
#ifdef ART_ENABLE_CODEGEN_arm64
#include "nodes_arm64.h"
#endif
#ifdef ART_ENABLE_CODEGEN_x86
#include "nodes_x86.h"
#endif
namespace art {
class HGraphVisitor : public ValueObject {
public:
explicit HGraphVisitor(HGraph* graph) : graph_(graph) {}
virtual ~HGraphVisitor() {}
virtual void VisitInstruction(HInstruction* instruction ATTRIBUTE_UNUSED) {}
virtual void VisitBasicBlock(HBasicBlock* block);
// Visit the graph following basic block insertion order.
void VisitInsertionOrder();
// Visit the graph following dominator tree reverse post-order.
void VisitReversePostOrder();
HGraph* GetGraph() const { return graph_; }
// Visit functions for instruction classes.
#define DECLARE_VISIT_INSTRUCTION(name, super) \
virtual void Visit##name(H##name* instr) { VisitInstruction(instr); }
FOR_EACH_INSTRUCTION(DECLARE_VISIT_INSTRUCTION)
#undef DECLARE_VISIT_INSTRUCTION
private:
HGraph* const graph_;
DISALLOW_COPY_AND_ASSIGN(HGraphVisitor);
};
class HGraphDelegateVisitor : public HGraphVisitor {
public:
explicit HGraphDelegateVisitor(HGraph* graph) : HGraphVisitor(graph) {}
virtual ~HGraphDelegateVisitor() {}
// Visit functions that delegate to to super class.
#define DECLARE_VISIT_INSTRUCTION(name, super) \
void Visit##name(H##name* instr) OVERRIDE { Visit##super(instr); }
FOR_EACH_INSTRUCTION(DECLARE_VISIT_INSTRUCTION)
#undef DECLARE_VISIT_INSTRUCTION
private:
DISALLOW_COPY_AND_ASSIGN(HGraphDelegateVisitor);
};
class HInsertionOrderIterator : public ValueObject {
public:
explicit HInsertionOrderIterator(const HGraph& graph) : graph_(graph), index_(0) {}
bool Done() const { return index_ == graph_.GetBlocks().size(); }
HBasicBlock* Current() const { return graph_.GetBlocks()[index_]; }
void Advance() { ++index_; }
private:
const HGraph& graph_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HInsertionOrderIterator);
};
class HReversePostOrderIterator : public ValueObject {
public:
explicit HReversePostOrderIterator(const HGraph& graph) : graph_(graph), index_(0) {
// Check that reverse post order of the graph has been built.
DCHECK(!graph.GetReversePostOrder().empty());
}
bool Done() const { return index_ == graph_.GetReversePostOrder().size(); }
HBasicBlock* Current() const { return graph_.GetReversePostOrder()[index_]; }
void Advance() { ++index_; }
private:
const HGraph& graph_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HReversePostOrderIterator);
};
class HPostOrderIterator : public ValueObject {
public:
explicit HPostOrderIterator(const HGraph& graph)
: graph_(graph), index_(graph_.GetReversePostOrder().size()) {
// Check that reverse post order of the graph has been built.
DCHECK(!graph.GetReversePostOrder().empty());
}
bool Done() const { return index_ == 0; }
HBasicBlock* Current() const { return graph_.GetReversePostOrder()[index_ - 1u]; }
void Advance() { --index_; }
private:
const HGraph& graph_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HPostOrderIterator);
};
class HLinearPostOrderIterator : public ValueObject {
public:
explicit HLinearPostOrderIterator(const HGraph& graph)
: order_(graph.GetLinearOrder()), index_(graph.GetLinearOrder().size()) {}
bool Done() const { return index_ == 0; }
HBasicBlock* Current() const { return order_[index_ - 1u]; }
void Advance() {
--index_;
DCHECK_GE(index_, 0U);
}
private:
const ArenaVector<HBasicBlock*>& order_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HLinearPostOrderIterator);
};
class HLinearOrderIterator : public ValueObject {
public:
explicit HLinearOrderIterator(const HGraph& graph)
: order_(graph.GetLinearOrder()), index_(0) {}
bool Done() const { return index_ == order_.size(); }
HBasicBlock* Current() const { return order_[index_]; }
void Advance() { ++index_; }
private:
const ArenaVector<HBasicBlock*>& order_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HLinearOrderIterator);
};
// Iterator over the blocks that art part of the loop. Includes blocks part
// of an inner loop. The order in which the blocks are iterated is on their
// block id.
class HBlocksInLoopIterator : public ValueObject {
public:
explicit HBlocksInLoopIterator(const HLoopInformation& info)
: blocks_in_loop_(info.GetBlocks()),
blocks_(info.GetHeader()->GetGraph()->GetBlocks()),
index_(0) {
if (!blocks_in_loop_.IsBitSet(index_)) {
Advance();
}
}
bool Done() const { return index_ == blocks_.size(); }
HBasicBlock* Current() const { return blocks_[index_]; }
void Advance() {
++index_;
for (size_t e = blocks_.size(); index_ < e; ++index_) {
if (blocks_in_loop_.IsBitSet(index_)) {
break;
}
}
}
private:
const BitVector& blocks_in_loop_;
const ArenaVector<HBasicBlock*>& blocks_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HBlocksInLoopIterator);
};
// Iterator over the blocks that art part of the loop. Includes blocks part
// of an inner loop. The order in which the blocks are iterated is reverse
// post order.
class HBlocksInLoopReversePostOrderIterator : public ValueObject {
public:
explicit HBlocksInLoopReversePostOrderIterator(const HLoopInformation& info)
: blocks_in_loop_(info.GetBlocks()),
blocks_(info.GetHeader()->GetGraph()->GetReversePostOrder()),
index_(0) {
if (!blocks_in_loop_.IsBitSet(blocks_[index_]->GetBlockId())) {
Advance();
}
}
bool Done() const { return index_ == blocks_.size(); }
HBasicBlock* Current() const { return blocks_[index_]; }
void Advance() {
++index_;
for (size_t e = blocks_.size(); index_ < e; ++index_) {
if (blocks_in_loop_.IsBitSet(blocks_[index_]->GetBlockId())) {
break;
}
}
}
private:
const BitVector& blocks_in_loop_;
const ArenaVector<HBasicBlock*>& blocks_;
size_t index_;
DISALLOW_COPY_AND_ASSIGN(HBlocksInLoopReversePostOrderIterator);
};
inline int64_t Int64FromConstant(HConstant* constant) {
if (constant->IsIntConstant()) {
return constant->AsIntConstant()->GetValue();
} else if (constant->IsLongConstant()) {
return constant->AsLongConstant()->GetValue();
} else {
DCHECK(constant->IsNullConstant()) << constant->DebugName();
return 0;
}
}
inline bool IsSameDexFile(const DexFile& lhs, const DexFile& rhs) {
// For the purposes of the compiler, the dex files must actually be the same object
// if we want to safely treat them as the same. This is especially important for JIT
// as custom class loaders can open the same underlying file (or memory) multiple
// times and provide different class resolution but no two class loaders should ever
// use the same DexFile object - doing so is an unsupported hack that can lead to
// all sorts of weird failures.
return &lhs == &rhs;
}
#define INSTRUCTION_TYPE_CHECK(type, super) \
inline bool HInstruction::Is##type() const { return GetKind() == k##type; } \
inline const H##type* HInstruction::As##type() const { \
return Is##type() ? down_cast<const H##type*>(this) : nullptr; \
} \
inline H##type* HInstruction::As##type() { \
return Is##type() ? static_cast<H##type*>(this) : nullptr; \
}
FOR_EACH_CONCRETE_INSTRUCTION(INSTRUCTION_TYPE_CHECK)
#undef INSTRUCTION_TYPE_CHECK
// Create space in `blocks` for adding `number_of_new_blocks` entries
// starting at location `at`. Blocks after `at` are moved accordingly.
inline void MakeRoomFor(ArenaVector<HBasicBlock*>* blocks,
size_t number_of_new_blocks,
size_t after) {
DCHECK_LT(after, blocks->size());
size_t old_size = blocks->size();
size_t new_size = old_size + number_of_new_blocks;
blocks->resize(new_size);
std::copy_backward(blocks->begin() + after + 1u, blocks->begin() + old_size, blocks->end());
}
} // namespace art
#endif // ART_COMPILER_OPTIMIZING_NODES_H_