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dart / sdk.git / c361f7db1a7754c24724e445e2138ecb80342d48 / . / runtime / vm / flow_graph_compiler_x64.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 VM_FLOW_GRAPH_COMPILER_X64_H_
#define VM_FLOW_GRAPH_COMPILER_X64_H_
#ifndef VM_FLOW_GRAPH_COMPILER_H_
#error Include flow_graph_compiler.h instead of flow_graph_compiler_x64.h.
#endif
namespace dart {
class Code;
class FlowGraph;
template <typename T> class GrowableArray;
class ParsedFunction;
class FlowGraphCompiler : public ValueObject {
private:
struct BlockInfo : public ZoneAllocated {
public:
BlockInfo() : label() { }
Label label;
};
public:
FlowGraphCompiler(Assembler* assembler,
const FlowGraph& flow_graph,
bool is_optimizing);
~FlowGraphCompiler();
static bool SupportsUnboxedMints();
// Accessors.
Assembler* assembler() const { return assembler_; }
const ParsedFunction& parsed_function() const { return parsed_function_; }
const GrowableArray<BlockEntryInstr*>& block_order() const {
return block_order_;
}
DescriptorList* pc_descriptors_list() const {
return pc_descriptors_list_;
}
BlockEntryInstr* current_block() const { return current_block_; }
void set_current_block(BlockEntryInstr* value) {
current_block_ = value;
}
static bool CanOptimize();
bool is_optimizing() const { return is_optimizing_; }
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);
void LoadDoubleOrSmiToXmm(XmmRegister result,
Register reg,
Register temp,
Label* not_double_or_smi);
// Returns 'true' if code generation for this function is complete, i.e.,
// no fall-through to regular code is needed.
bool TryIntrinsify();
void GenerateCallRuntime(intptr_t token_pos,
const RuntimeEntry& entry,
LocationSummary* locs);
void GenerateCall(intptr_t token_pos,
const ExternalLabel* label,
PcDescriptors::Kind kind,
LocationSummary* locs);
void GenerateDartCall(intptr_t deopt_id,
intptr_t token_pos,
const ExternalLabel* label,
PcDescriptors::Kind kind,
LocationSummary* locs);
void GenerateAssertAssignable(intptr_t token_pos,
const AbstractType& dst_type,
const String& dst_name,
LocationSummary* locs);
void GenerateInstanceOf(intptr_t token_pos,
const AbstractType& type,
bool negate_result,
LocationSummary* locs);
void GenerateInstanceCall(intptr_t deopt_id,
intptr_t token_pos,
intptr_t argument_count,
const Array& argument_names,
LocationSummary* locs,
const ICData& ic_data);
void GenerateStaticCall(intptr_t deopt_id,
intptr_t token_pos,
const Function& function,
intptr_t argument_count,
const Array& argument_names,
LocationSummary* locs);
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 EmitComment(Instruction* instr);
void EmitOptimizedInstanceCall(ExternalLabel* target_label,
const ICData& ic_data,
const Array& arguments_descriptor,
intptr_t argument_count,
intptr_t deopt_id,
intptr_t token_pos,
LocationSummary* locs);
void EmitInstanceCall(ExternalLabel* target_label,
const ICData& ic_data,
const Array& arguments_descriptor,
intptr_t argument_count,
intptr_t deopt_id,
intptr_t token_pos,
LocationSummary* locs);
void EmitTestAndCall(const ICData& ic_data,
Register class_id_reg,
intptr_t arg_count,
const Array& arg_names,
Label* deopt,
intptr_t deopt_id,
intptr_t token_index,
LocationSummary* locs);
void EmitDoubleCompareBranch(Condition true_condition,
XmmRegister left,
XmmRegister right,
BranchInstr* branch);
void EmitDoubleCompareBool(Condition true_condition,
XmmRegister left,
XmmRegister right,
Register result);
void EmitEqualityRegConstCompare(Register reg, const Object& obj);
// Implement equality: if any of the arguments is null do identity check.
// Fallthrough calls super equality.
void EmitSuperEqualityCallPrologue(Register result, Label* skip_call);
intptr_t StackSize() const;
// Returns assembler label associated with the given block entry.
Label* GetBlockLabel(BlockEntryInstr* block_entry) 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 IsNextBlock(BlockEntryInstr* block_entry) const;
void AddExceptionHandler(intptr_t try_index, intptr_t pc_offset);
void AddCurrentDescriptor(PcDescriptors::Kind kind,
intptr_t deopt_id,
intptr_t token_pos);
void RecordSafepoint(LocationSummary* locs);
Label* AddDeoptStub(intptr_t deopt_id, DeoptReasonId reason);
void AddDeoptIndexAtCall(intptr_t deopt_id, intptr_t token_pos);
void AddSlowPathCode(SlowPathCode* slow_path);
void FinalizeExceptionHandlers(const Code& code);
void FinalizePcDescriptors(const Code& code);
void FinalizeDeoptInfo(const Code& code);
void FinalizeStackmaps(const Code& code);
void FinalizeVarDescriptors(const Code& code);
void FinalizeComments(const Code& code);
void FinalizeStaticCallTargetsTable(const Code& code);
const Bool& bool_true() const { return bool_true_; }
const Bool& bool_false() const { return bool_false_; }
const Class& double_class() const { return double_class_; }
// Returns true if the compiled function has a finally clause.
bool HasFinally() const;
static const int kLocalsOffsetFromFP = (-1 * kWordSize);
void SaveLiveRegisters(LocationSummary* locs);
void RestoreLiveRegisters(LocationSummary* locs);
intptr_t CurrentTryIndex() const {
if (current_block_ == NULL) {
return CatchClauseNode::kInvalidTryIndex;
}
return current_block_->try_index();
}
bool may_reoptimize() const { return may_reoptimize_; }
static Condition FlipCondition(Condition condition);
static bool EvaluateCondition(Condition condition, intptr_t l, intptr_t r);
// Array/list element address computations.
static FieldAddress ElementAddressForIntIndex(intptr_t cid,
Register array,
intptr_t offset);
static FieldAddress ElementAddressForRegIndex(intptr_t cid,
Register array,
Register index);
private:
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 EmitStaticCall(const Function& function,
const Array& arguments_descriptor,
intptr_t argument_count,
intptr_t deopt_id,
intptr_t token_pos,
LocationSummary* locs);
// 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(intptr_t token_pos,
const AbstractType& type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
RawSubtypeTestCache* GenerateInstantiatedTypeWithArgumentsTest(
intptr_t token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
bool GenerateInstantiatedTypeNoArgumentsTest(intptr_t token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
RawSubtypeTestCache* GenerateUninstantiatedTypeTest(
intptr_t token_pos,
const AbstractType& dst_type,
Label* is_instance_lbl,
Label* is_not_instance_label);
RawSubtypeTestCache* GenerateSubtype1TestCacheLookup(
intptr_t token_pos,
const Class& type_class,
Label* is_instance_lbl,
Label* is_not_instance_lbl);
enum TypeTestStubKind {
kTestTypeOneArg,
kTestTypeTwoArgs,
kTestTypeThreeArgs,
};
RawSubtypeTestCache* GenerateCallSubtypeTestStub(TypeTestStubKind test_kind,
Register instance_reg,
Register 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();
void GenerateInlinedGetter(intptr_t offset);
void GenerateInlinedSetter(intptr_t offset);
// 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;
}
// Perform a greedy local register allocation. Consider all registers free.
void AllocateRegistersLocally(Instruction* instr);
class Assembler* assembler_;
const ParsedFunction& parsed_function_;
const GrowableArray<BlockEntryInstr*>& block_order_;
// 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_;
GrowableArray<BlockInfo*> block_info_;
GrowableArray<CompilerDeoptInfo*> deopt_infos_;
GrowableArray<SlowPathCode*> slow_path_code_;
// Stores: [code offset, function, null(code)].
const GrowableObjectArray& static_calls_target_table_;
const bool is_optimizing_;
// Set to true if optimized code has IC calls.
bool may_reoptimize_;
const Bool& bool_true_;
const Bool& bool_false_;
const Class& double_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_;
DISALLOW_COPY_AND_ASSIGN(FlowGraphCompiler);
};
} // namespace dart
#endif // VM_FLOW_GRAPH_COMPILER_X64_H_