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dart / sdk.git / refs/tags/1.25.0-dev.8.0 / . / runtime / vm / flow_graph_compiler.h
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// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#ifndef RUNTIME_VM_FLOW_GRAPH_COMPILER_H_
#define RUNTIME_VM_FLOW_GRAPH_COMPILER_H_
#include "vm/allocation.h"
#include "vm/assembler.h"
#include "vm/code_descriptors.h"
#include "vm/intermediate_language.h"
#include "vm/runtime_entry.h"
namespace dart {
// Forward declarations.
class Code;
class DeoptInfoBuilder;
class FlowGraph;
class FlowGraphCompiler;
class Function;
template <typename T>
class GrowableArray;
class ParsedFunction;
class ParallelMoveResolver : public ValueObject {
public:
explicit ParallelMoveResolver(FlowGraphCompiler* compiler);
// Resolve a set of parallel moves, emitting assembler instructions.
void EmitNativeCode(ParallelMoveInstr* parallel_move);
private:
class ScratchFpuRegisterScope : public ValueObject {
public:
ScratchFpuRegisterScope(ParallelMoveResolver* resolver,
FpuRegister blocked);
~ScratchFpuRegisterScope();
FpuRegister reg() const { return reg_; }
private:
ParallelMoveResolver* resolver_;
FpuRegister reg_;
bool spilled_;
};
class ScratchRegisterScope : public ValueObject {
public:
ScratchRegisterScope(ParallelMoveResolver* resolver, Register blocked);
~ScratchRegisterScope();
Register reg() const { return reg_; }
private:
ParallelMoveResolver* resolver_;
Register reg_;
bool spilled_;
};
bool IsScratchLocation(Location loc);
intptr_t AllocateScratchRegister(Location::Kind kind,
uword blocked_mask,
intptr_t first_free_register,
intptr_t last_free_register,
bool* spilled);
void SpillScratch(Register reg);
void RestoreScratch(Register reg);
void SpillFpuScratch(FpuRegister reg);
void RestoreFpuScratch(FpuRegister reg);
// friend class ScratchXmmRegisterScope;
// Build the initial list of moves.
void BuildInitialMoveList(ParallelMoveInstr* parallel_move);
// Perform the move at the moves_ index in question (possibly requiring
// other moves to satisfy dependencies).
void PerformMove(int index);
// Emit a move and remove it from the move graph.
void EmitMove(int index);
// Execute a move by emitting a swap of two operands. The move from
// source to destination is removed from the move graph.
void EmitSwap(int index);
// Verify the move list before performing moves.
void Verify();
// Helpers for non-trivial source-destination combinations that cannot
// be handled by a single instruction.
void MoveMemoryToMemory(const Address& dst, const Address& src);
void StoreObject(const Address& dst, const Object& obj);
void Exchange(Register reg, const Address& mem);
void Exchange(const Address& mem1, const Address& mem2);
void Exchange(Register reg, Register base_reg, intptr_t stack_offset);
void Exchange(Register base_reg1,
intptr_t stack_offset1,
Register base_reg2,
intptr_t stack_offset2);
FlowGraphCompiler* compiler_;
// List of moves not yet resolved.
GrowableArray<MoveOperands*> moves_;
};
// Used for describing a deoptimization point after call (lazy deoptimization).
// For deoptimization before instruction use class CompilerDeoptInfoWithStub.
class CompilerDeoptInfo : public ZoneAllocated {
public:
CompilerDeoptInfo(intptr_t deopt_id,
ICData::DeoptReasonId reason,
uint32_t flags,
Environment* deopt_env)
: pc_offset_(-1),
deopt_id_(deopt_id),
reason_(reason),
flags_(flags),
#if defined(TARGET_ARCH_DBC)
lazy_deopt_with_result_(false),
#endif
deopt_env_(deopt_env) {
ASSERT(deopt_env != NULL);
}
virtual ~CompilerDeoptInfo() {}
RawTypedData* CreateDeoptInfo(FlowGraphCompiler* compiler,
DeoptInfoBuilder* builder,
const Array& deopt_table);
// No code needs to be generated.
virtual void GenerateCode(FlowGraphCompiler* compiler, intptr_t stub_ix) {}
intptr_t pc_offset() const { return pc_offset_; }
void set_pc_offset(intptr_t offset) { pc_offset_ = offset; }
intptr_t deopt_id() const { return deopt_id_; }
ICData::DeoptReasonId reason() const { return reason_; }
uint32_t flags() const { return flags_; }
const Environment* deopt_env() const { return deopt_env_; }
#if defined(TARGET_ARCH_DBC)
// On DBC calls return results on the stack but not all calls have a result.
// This needs to be taken into account when constructing lazy deoptimization
// environment.
// For calls with results we add a deopt instruction that would copy top
// of the stack from optimized frame to unoptimized frame effectively
// preserving the result of the call.
// For calls with no results we don't emit such instruction - because there
// is no result pushed by the return sequence.
void mark_lazy_deopt_with_result() { lazy_deopt_with_result_ = true; }
#endif
private:
void EmitMaterializations(Environment* env, DeoptInfoBuilder* builder);
void AllocateIncomingParametersRecursive(Environment* env,
intptr_t* stack_height);
intptr_t pc_offset_;
const intptr_t deopt_id_;
const ICData::DeoptReasonId reason_;
const uint32_t flags_;
#if defined(TARGET_ARCH_DBC)
bool lazy_deopt_with_result_;
#endif
Environment* deopt_env_;
DISALLOW_COPY_AND_ASSIGN(CompilerDeoptInfo);
};
class CompilerDeoptInfoWithStub : public CompilerDeoptInfo {
public:
CompilerDeoptInfoWithStub(intptr_t deopt_id,
ICData::DeoptReasonId reason,
uint32_t flags,
Environment* deopt_env)
: CompilerDeoptInfo(deopt_id, reason, flags, deopt_env), entry_label_() {
ASSERT(reason != ICData::kDeoptAtCall);
}
Label* entry_label() { return &entry_label_; }
// Implementation is in architecture specific file.
virtual void GenerateCode(FlowGraphCompiler* compiler, intptr_t stub_ix);
const char* Name() const {
const char* kFormat = "Deopt stub for id %d, reason: %s";
const intptr_t len = OS::SNPrint(NULL, 0, kFormat, deopt_id(),
DeoptReasonToCString(reason())) +
1;
char* chars = Thread::Current()->zone()->Alloc<char>(len);
OS::SNPrint(chars, len, kFormat, deopt_id(),
DeoptReasonToCString(reason()));
return chars;
}
private:
Label entry_label_;
DISALLOW_COPY_AND_ASSIGN(CompilerDeoptInfoWithStub);
};
class SlowPathCode : public ZoneAllocated {
public:
SlowPathCode() : entry_label_(), exit_label_() {}
virtual ~SlowPathCode() {}
Label* entry_label() { return &entry_label_; }
Label* exit_label() { return &exit_label_; }
void GenerateCode(FlowGraphCompiler* compiler) {
EmitNativeCode(compiler);
ASSERT(entry_label_.IsBound());
}
private:
virtual void EmitNativeCode(FlowGraphCompiler* compiler) = 0;
Label entry_label_;
Label exit_label_;
DISALLOW_COPY_AND_ASSIGN(SlowPathCode);
};
class FlowGraphCompiler : public ValueObject {
private:
class BlockInfo : public ZoneAllocated {
public:
BlockInfo()
: block_label_(),
jump_label_(&block_label_),
next_nonempty_label_(NULL),
is_marked_(false) {}
// The label to jump to when control is transferred to this block. For
// nonempty blocks it is the label of the block itself. For empty
// blocks it is the label of the first nonempty successor block.
Label* jump_label() const { return jump_label_; }
void set_jump_label(Label* label) { jump_label_ = label; }
// The label of the first nonempty block after this one in the block
// order, or NULL if there is no nonempty block following this one.
Label* next_nonempty_label() const { return next_nonempty_label_; }
void set_next_nonempty_label(Label* label) { next_nonempty_label_ = label; }
bool WasCompacted() const { return jump_label_ != &block_label_; }
// Block compaction is recursive. Block info for already-compacted
// blocks is marked so as to avoid cycles in the graph.
bool is_marked() const { return is_marked_; }
void mark() { is_marked_ = true; }
private:
Label block_label_;
Label* jump_label_;
Label* next_nonempty_label_;
bool is_marked_;
};
public:
FlowGraphCompiler(Assembler* assembler,
FlowGraph* flow_graph,
const ParsedFunction& parsed_function,
bool is_optimizing,
const GrowableArray<const Function*>& inline_id_to_function,
const GrowableArray<TokenPosition>& inline_id_to_token_pos,
const GrowableArray<intptr_t>& caller_inline_id);
~FlowGraphCompiler();
static bool SupportsUnboxedDoubles();
static bool SupportsUnboxedMints();
static bool SupportsUnboxedSimd128();
static bool SupportsHardwareDivision();
static bool CanConvertUnboxedMintToDouble();
static bool IsUnboxedField(const Field& field);
static bool IsPotentialUnboxedField(const Field& field);
// Accessors.
Assembler* assembler() const { return assembler_; }
const ParsedFunction& parsed_function() const { return parsed_function_; }
const GrowableArray<BlockEntryInstr*>& block_order() const {
return block_order_;
}
const FlowGraph& flow_graph() const { return flow_graph_; }
BlockEntryInstr* current_block() const { return current_block_; }
void set_current_block(BlockEntryInstr* value) { current_block_ = value; }
static bool CanOptimize();
bool CanOptimizeFunction() const;
bool CanOSRFunction() const;
bool is_optimizing() const { return is_optimizing_; }
void EnterIntrinsicMode();
void ExitIntrinsicMode();
bool intrinsic_mode() const { return intrinsic_mode_; }
Label* intrinsic_slow_path_label() { return &intrinsic_slow_path_label_; }
bool ForceSlowPathForStackOverflow() const;
const GrowableArray<BlockInfo*>& block_info() const { return block_info_; }
ParallelMoveResolver* parallel_move_resolver() {
return &parallel_move_resolver_;
}
// Constructor is lighweight, major initialization work should occur here.
// This makes it easier to measure time spent in the compiler.
void InitCompiler();
void CompileGraph();
void VisitBlocks();
// Bail out of the flow graph compiler. Does not return to the caller.
void Bailout(const char* reason);
// Returns 'true' if regular code generation should be skipped.
bool TryIntrinsify();
void GenerateAssertAssignable(TokenPosition token_pos,
intptr_t deopt_id,
const AbstractType& dst_type,
const String& dst_name,
LocationSummary* locs);
// DBC emits calls very differently from all other architectures due to its
// interpreted nature.
#if !defined(TARGET_ARCH_DBC)
void GenerateRuntimeCall(TokenPosition token_pos,
intptr_t deopt_id,
const RuntimeEntry& entry,
intptr_t argument_count,
LocationSummary* locs);
void GenerateCall(TokenPosition token_pos,
const StubEntry& stub_entry,
RawPcDescriptors::Kind kind,
LocationSummary* locs);
void GenerateCallWithDeopt(TokenPosition token_pos,
intptr_t deopt_id,
const StubEntry& stub_entry,
RawPcDescriptors::Kind kind,
LocationSummary* locs);
void GeneratePatchableCall(TokenPosition token_pos,
const StubEntry& stub_entry,
RawPcDescriptors::Kind kind,
LocationSummary* locs);
void GenerateDartCall(intptr_t deopt_id,
TokenPosition token_pos,
const StubEntry& stub_entry,
RawPcDescriptors::Kind kind,
LocationSummary* locs);
void GenerateStaticDartCall(intptr_t deopt_id,
TokenPosition token_pos,
const StubEntry& stub_entry,
RawPcDescriptors::Kind kind,
LocationSummary* locs,
const Function& target);
void GenerateInstanceOf(TokenPosition token_pos,
intptr_t deopt_id,
const AbstractType& type,
LocationSummary* locs);
void GenerateInstanceCall(intptr_t deopt_id,
TokenPosition token_pos,
intptr_t argument_count,
LocationSummary* locs,
const ICData& ic_data);
void GenerateStaticCall(intptr_t deopt_id,
TokenPosition token_pos,
const Function& function,
ArgumentsInfo args_info,
LocationSummary* locs,
const ICData& ic_data);
void GenerateNumberTypeCheck(Register kClassIdReg,
const AbstractType& type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
void GenerateStringTypeCheck(Register kClassIdReg,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
void GenerateListTypeCheck(Register kClassIdReg, Label* is_instance_lbl);
void EmitOptimizedInstanceCall(const StubEntry& stub_entry,
const ICData& ic_data,
intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs);
void EmitInstanceCall(const StubEntry& stub_entry,
const ICData& ic_data,
intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs);
void EmitPolymorphicInstanceCall(
const CallTargets& targets,
const InstanceCallInstr& original_instruction,
ArgumentsInfo args_info,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs,
bool complete,
intptr_t total_call_count);
// Pass a value for try-index where block is not available (e.g. slow path).
void EmitMegamorphicInstanceCall(const String& function_name,
const Array& arguments_descriptor,
intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs,
intptr_t try_index,
intptr_t slow_path_argument_count = 0);
void EmitSwitchableInstanceCall(const ICData& ic_data,
intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs);
void EmitTestAndCall(const CallTargets& targets,
const String& function_name,
ArgumentsInfo args_info,
Label* failed,
Label* match_found,
intptr_t deopt_id,
TokenPosition token_index,
LocationSummary* locs,
bool complete,
intptr_t total_ic_calls);
Condition EmitEqualityRegConstCompare(Register reg,
const Object& obj,
bool needs_number_check,
TokenPosition token_pos,
intptr_t deopt_id);
Condition EmitEqualityRegRegCompare(Register left,
Register right,
bool needs_number_check,
TokenPosition token_pos,
intptr_t deopt_id);
bool NeedsEdgeCounter(TargetEntryInstr* block);
void EmitEdgeCounter(intptr_t edge_id);
#endif // !defined(TARGET_ARCH_DBC)
void EmitCatchEntryState(
Environment* env = NULL,
intptr_t try_index = CatchClauseNode::kInvalidTryIndex);
void EmitCallsiteMetaData(TokenPosition token_pos,
intptr_t deopt_id,
RawPcDescriptors::Kind kind,
LocationSummary* locs);
void EmitComment(Instruction* instr);
intptr_t StackSize() const;
// Returns assembler label associated with the given block entry.
Label* GetJumpLabel(BlockEntryInstr* block_entry) const;
bool WasCompacted(BlockEntryInstr* block_entry) const;
// Returns the label of the fall-through of the current block.
Label* NextNonEmptyLabel() const;
// Returns true if there is a next block after the current one in
// the block order and if it is the given block.
bool CanFallThroughTo(BlockEntryInstr* block_entry) const;
// Return true-, false- and fall-through label for a branch instruction.
BranchLabels CreateBranchLabels(BranchInstr* branch) const;
void AddExceptionHandler(intptr_t try_index,
intptr_t outer_try_index,
intptr_t pc_offset,
TokenPosition token_pos,
bool is_generated,
const Array& handler_types,
bool needs_stacktrace);
void SetNeedsStackTrace(intptr_t try_index);
void AddCurrentDescriptor(RawPcDescriptors::Kind kind,
intptr_t deopt_id,
TokenPosition token_pos);
void AddDescriptor(RawPcDescriptors::Kind kind,
intptr_t pc_offset,
intptr_t deopt_id,
TokenPosition token_pos,
intptr_t try_index);
void RecordSafepoint(LocationSummary* locs,
intptr_t slow_path_argument_count = 0);
Label* AddDeoptStub(intptr_t deopt_id,
ICData::DeoptReasonId reason,
uint32_t flags = 0);
#if defined(TARGET_ARCH_DBC)
void EmitDeopt(intptr_t deopt_id,
ICData::DeoptReasonId reason,
uint32_t flags = 0);
// If the cid does not fit in 16 bits, then this will cause a bailout.
uint16_t ToEmbeddableCid(intptr_t cid, Instruction* instruction);
// In optimized code, variables at the catch block entry reside at the top
// of the allocatable register range.
// Must be in sync with FlowGraphAllocator::ProcessInitialDefinition.
intptr_t CatchEntryRegForVariable(const LocalVariable& var);
#endif // defined(TARGET_ARCH_DBC)
CompilerDeoptInfo* AddDeoptIndexAtCall(intptr_t deopt_id);
void AddSlowPathCode(SlowPathCode* slow_path);
void FinalizeExceptionHandlers(const Code& code);
void FinalizePcDescriptors(const Code& code);
RawArray* CreateDeoptInfo(Assembler* assembler);
void FinalizeStackMaps(const Code& code);
void FinalizeVarDescriptors(const Code& code);
void FinalizeCatchEntryStateMap(const Code& code);
void FinalizeStaticCallTargetsTable(const Code& code);
void FinalizeCodeSourceMap(const Code& code);
const Class& double_class() const { return double_class_; }
const Class& mint_class() const { return mint_class_; }
const Class& float32x4_class() const { return float32x4_class_; }
const Class& float64x2_class() const { return float64x2_class_; }
const Class& int32x4_class() const { return int32x4_class_; }
const Class& BoxClassFor(Representation rep);
void SaveLiveRegisters(LocationSummary* locs);
void RestoreLiveRegisters(LocationSummary* locs);
#if defined(DEBUG)
void ClobberDeadTempRegisters(LocationSummary* locs);
#endif
Environment* SlowPathEnvironmentFor(Instruction* instruction);
intptr_t CurrentTryIndex() const {
if (current_block_ == NULL) {
return CatchClauseNode::kInvalidTryIndex;
}
return current_block_->try_index();
}
bool may_reoptimize() const { return may_reoptimize_; }
// Use in unoptimized compilation to preserve/reuse ICData.
const ICData* GetOrAddInstanceCallICData(intptr_t deopt_id,
const String& target_name,
const Array& arguments_descriptor,
intptr_t num_args_tested);
const ICData* GetOrAddStaticCallICData(intptr_t deopt_id,
const Function& target,
const Array& arguments_descriptor,
intptr_t num_args_tested);
static const CallTargets* ResolveCallTargetsForReceiverCid(
intptr_t cid,
const String& selector,
const Array& args_desc_array);
const ZoneGrowableArray<const ICData*>& deopt_id_to_ic_data() const {
return *deopt_id_to_ic_data_;
}
Thread* thread() const { return thread_; }
Isolate* isolate() const { return thread_->isolate(); }
Zone* zone() const { return zone_; }
void AddStubCallTarget(const Code& code);
RawArray* edge_counters_array() const { return edge_counters_array_.raw(); }
RawArray* InliningIdToFunction() const;
void BeginCodeSourceRange();
void EndCodeSourceRange(TokenPosition token_pos);
static bool LookupMethodFor(int class_id,
const String& name,
const ArgumentsDescriptor& args_desc,
Function* fn_return,
bool* class_is_abstract_return = NULL);
#if defined(TARGET_ARCH_DBC)
enum CallResult {
kHasResult,
kNoResult,
};
void RecordAfterCallHelper(TokenPosition token_pos,
intptr_t deopt_id,
intptr_t argument_count,
CallResult result,
LocationSummary* locs);
void RecordAfterCall(Instruction* instr, CallResult result);
#endif
private:
friend class CheckStackOverflowSlowPath; // For pending_deoptimization_env_.
friend class CheckedSmiSlowPath; // Same.
friend class CheckedSmiComparisonSlowPath; // Same.
void EmitFrameEntry();
void AddStaticCallTarget(const Function& function);
void GenerateDeferredCode();
void EmitInstructionPrologue(Instruction* instr);
void EmitInstructionEpilogue(Instruction* instr);
// Emit code to load a Value into register 'dst'.
void LoadValue(Register dst, Value* value);
void EmitOptimizedStaticCall(const Function& function,
const Array& arguments_descriptor,
intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs);
void EmitUnoptimizedStaticCall(intptr_t argument_count,
intptr_t deopt_id,
TokenPosition token_pos,
LocationSummary* locs,
const ICData& ic_data);
// Helper for TestAndCall that calculates a good bias that
// allows more compact instructions to be emitted.
intptr_t ComputeGoodBiasForCidComparison(const CallTargets& sorted,
intptr_t max_immediate);
// More helpers for EmitTestAndCall.
void EmitTestAndCallLoadReceiver(intptr_t argument_count,
const Array& arguments_descriptor);
void EmitTestAndCallSmiBranch(Label* label, bool jump_if_smi);
void EmitTestAndCallLoadCid();
// Returns new class-id bias.
int EmitTestAndCallCheckCid(Label* next_label,
const CidRange& range,
int bias);
// DBC handles type tests differently from all other architectures due
// to its interpreted nature.
#if !defined(TARGET_ARCH_DBC)
// Type checking helper methods.
void CheckClassIds(Register class_id_reg,
const GrowableArray<intptr_t>& class_ids,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
RawSubtypeTestCache* GenerateInlineInstanceof(TokenPosition token_pos,
const AbstractType& type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
RawSubtypeTestCache* GenerateInstantiatedTypeWithArgumentsTest(
TokenPosition token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
bool GenerateInstantiatedTypeNoArgumentsTest(TokenPosition token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
RawSubtypeTestCache* GenerateUninstantiatedTypeTest(
TokenPosition token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_label);
RawSubtypeTestCache* GenerateSubtype1TestCacheLookup(
TokenPosition token_pos,
const Class& type_class,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
enum TypeTestStubKind {
kTestTypeOneArg,
kTestTypeTwoArgs,
kTestTypeFourArgs,
};
RawSubtypeTestCache* GenerateCallSubtypeTestStub(
TypeTestStubKind test_kind,
Register instance_reg,
Register instantiator_type_arguments_reg,
Register function_type_arguments_reg,
Register temp_reg,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
void GenerateBoolToJump(Register bool_reg, Label* is_true, Label* is_false);
void CopyParameters();
#endif // !defined(TARGET_ARCH_DBC)
void GenerateInlinedGetter(intptr_t offset);
void GenerateInlinedSetter(intptr_t offset);
// Perform a greedy local register allocation. Consider all registers free.
void AllocateRegistersLocally(Instruction* instr);
// Map a block number in a forward iteration into the block number in the
// corresponding reverse iteration. Used to obtain an index into
// block_order for reverse iterations.
intptr_t reverse_index(intptr_t index) const {
return block_order_.length() - index - 1;
}
void CompactBlock(BlockEntryInstr* block);
void CompactBlocks();
bool IsListClass(const Class& cls) const {
return cls.raw() == list_class_.raw();
}
void EmitSourceLine(Instruction* instr);
intptr_t GetOptimizationThreshold() const;
StackMapTableBuilder* stackmap_table_builder() {
if (stackmap_table_builder_ == NULL) {
stackmap_table_builder_ = new StackMapTableBuilder();
}
return stackmap_table_builder_;
}
// TODO(vegorov) re-enable frame state tracking on DBC. It is
// currently disabled because it relies on LocationSummaries and
// we don't use them during unoptimized compilation on DBC.
#if defined(DEBUG) && !defined(TARGET_ARCH_DBC)
void FrameStateUpdateWith(Instruction* instr);
void FrameStatePush(Definition* defn);
void FrameStatePop(intptr_t count);
bool FrameStateIsSafeToCall();
void FrameStateClear();
#endif
// This struct contains either function or code, the other one being NULL.
class StaticCallsStruct : public ZoneAllocated {
public:
const intptr_t offset;
const Function* function; // Can be NULL.
const Code* code; // Can be NULL.
StaticCallsStruct(intptr_t offset_arg,
const Function* function_arg,
const Code* code_arg)
: offset(offset_arg), function(function_arg), code(code_arg) {
ASSERT((function == NULL) || function->IsZoneHandle());
ASSERT((code == NULL) || code->IsZoneHandle());
}
private:
DISALLOW_COPY_AND_ASSIGN(StaticCallsStruct);
};
Thread* thread_;
Zone* zone_;
Assembler* assembler_;
const ParsedFunction& parsed_function_;
const FlowGraph& flow_graph_;
const GrowableArray<BlockEntryInstr*>& block_order_;
#if defined(DEBUG)
GrowableArray<Representation> frame_state_;
#endif
// Compiler specific per-block state. Indexed by postorder block number
// for convenience. This is not the block's index in the block order,
// which is reverse postorder.
BlockEntryInstr* current_block_;
ExceptionHandlerList* exception_handlers_list_;
DescriptorList* pc_descriptors_list_;
StackMapTableBuilder* stackmap_table_builder_;
CodeSourceMapBuilder* code_source_map_builder_;
CatchEntryStateMapBuilder* catch_entry_state_maps_builder_;
GrowableArray<BlockInfo*> block_info_;
GrowableArray<CompilerDeoptInfo*> deopt_infos_;
GrowableArray<SlowPathCode*> slow_path_code_;
// Stores static call targets as well as stub targets.
// TODO(srdjan): Evaluate if we should store allocation stub targets into a
// separate table?
GrowableArray<StaticCallsStruct*> static_calls_target_table_;
const bool is_optimizing_;
// Set to true if optimized code has IC calls.
bool may_reoptimize_;
// True while emitting intrinsic code.
bool intrinsic_mode_;
Label intrinsic_slow_path_label_;
const Class& double_class_;
const Class& mint_class_;
const Class& float32x4_class_;
const Class& float64x2_class_;
const Class& int32x4_class_;
const Class& list_class_;
ParallelMoveResolver parallel_move_resolver_;
// Currently instructions generate deopt stubs internally by
// calling AddDeoptStub. To communicate deoptimization environment
// that should be used when deoptimizing we store it in this variable.
// In future AddDeoptStub should be moved out of the instruction template.
Environment* pending_deoptimization_env_;
ZoneGrowableArray<const ICData*>* deopt_id_to_ic_data_;
Array& edge_counters_array_;
DISALLOW_COPY_AND_ASSIGN(FlowGraphCompiler);
};
} // namespace dart
#endif // RUNTIME_VM_FLOW_GRAPH_COMPILER_H_