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1 // Copyright 2014 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4 
5 #ifndef V8_COMPILER_INSTRUCTION_H_
6 #define V8_COMPILER_INSTRUCTION_H_
7 
8 #include <deque>
9 #include <iosfwd>
10 #include <map>
11 #include <set>
12 
13 #include "src/compiler/common-operator.h"
14 #include "src/compiler/frame.h"
15 #include "src/compiler/instruction-codes.h"
16 #include "src/compiler/opcodes.h"
17 #include "src/compiler/source-position.h"
18 #include "src/macro-assembler.h"
19 #include "src/register-configuration.h"
20 #include "src/zone-allocator.h"
21 
22 namespace v8 {
23 namespace internal {
24 namespace compiler {
25 
26 // Forward declarations.
27 class Schedule;
28 
29 
30 class InstructionOperand {
31  public:
32   static const int kInvalidVirtualRegister = -1;
33 
34   // TODO(dcarney): recover bit. INVALID can be represented as UNALLOCATED with
35   // kInvalidVirtualRegister and some DCHECKS.
36   enum Kind { INVALID, UNALLOCATED, CONSTANT, IMMEDIATE, EXPLICIT, ALLOCATED };
37 
InstructionOperand()38   InstructionOperand() : InstructionOperand(INVALID) {}
39 
kind()40   Kind kind() const { return KindField::decode(value_); }
41 
42 #define INSTRUCTION_OPERAND_PREDICATE(name, type) \
43   bool Is##name() const { return kind() == type; }
44   INSTRUCTION_OPERAND_PREDICATE(Invalid, INVALID)
45   // UnallocatedOperands are place-holder operands created before register
46   // allocation. They later are assigned registers and become AllocatedOperands.
47   INSTRUCTION_OPERAND_PREDICATE(Unallocated, UNALLOCATED)
48   // Constant operands participate in register allocation. They are allocated to
49   // registers but have a special "spilling" behavior. When a ConstantOperand
50   // value must be rematerialized, it is loaded from an immediate constant
51   // rather from an unspilled slot.
52   INSTRUCTION_OPERAND_PREDICATE(Constant, CONSTANT)
53   // ImmediateOperands do not participate in register allocation and are only
54   // embedded directly in instructions, e.g. small integers and on some
55   // platforms Objects.
56   INSTRUCTION_OPERAND_PREDICATE(Immediate, IMMEDIATE)
57   // ExplicitOperands do not participate in register allocation. They are
58   // created by the instruction selector for direct access to registers and
59   // stack slots, completely bypassing the register allocator. They are never
60   // associated with a virtual register
61   INSTRUCTION_OPERAND_PREDICATE(Explicit, EXPLICIT)
62   // AllocatedOperands are registers or stack slots that are assigned by the
63   // register allocator and are always associated with a virtual register.
64   INSTRUCTION_OPERAND_PREDICATE(Allocated, ALLOCATED)
65 #undef INSTRUCTION_OPERAND_PREDICATE
66 
67   inline bool IsAnyRegister() const;
68   inline bool IsRegister() const;
69   inline bool IsDoubleRegister() const;
70   inline bool IsStackSlot() const;
71   inline bool IsDoubleStackSlot() const;
72 
73   template <typename SubKindOperand>
New(Zone * zone,const SubKindOperand & op)74   static SubKindOperand* New(Zone* zone, const SubKindOperand& op) {
75     void* buffer = zone->New(sizeof(op));
76     return new (buffer) SubKindOperand(op);
77   }
78 
ReplaceWith(InstructionOperand * dest,const InstructionOperand * src)79   static void ReplaceWith(InstructionOperand* dest,
80                           const InstructionOperand* src) {
81     *dest = *src;
82   }
83 
Equals(const InstructionOperand & that)84   bool Equals(const InstructionOperand& that) const {
85     return this->value_ == that.value_;
86   }
87 
Compare(const InstructionOperand & that)88   bool Compare(const InstructionOperand& that) const {
89     return this->value_ < that.value_;
90   }
91 
EqualsCanonicalized(const InstructionOperand & that)92   bool EqualsCanonicalized(const InstructionOperand& that) const {
93     return this->GetCanonicalizedValue() == that.GetCanonicalizedValue();
94   }
95 
CompareCanonicalized(const InstructionOperand & that)96   bool CompareCanonicalized(const InstructionOperand& that) const {
97     return this->GetCanonicalizedValue() < that.GetCanonicalizedValue();
98   }
99 
100   void Print(const RegisterConfiguration* config) const;
101   void Print() const;
102 
103  protected:
InstructionOperand(Kind kind)104   explicit InstructionOperand(Kind kind) : value_(KindField::encode(kind)) {}
105 
106   inline uint64_t GetCanonicalizedValue() const;
107 
108   class KindField : public BitField64<Kind, 0, 3> {};
109 
110   uint64_t value_;
111 };
112 
113 
114 typedef ZoneVector<InstructionOperand> InstructionOperandVector;
115 
116 
117 struct PrintableInstructionOperand {
118   const RegisterConfiguration* register_configuration_;
119   InstructionOperand op_;
120 };
121 
122 
123 std::ostream& operator<<(std::ostream& os,
124                          const PrintableInstructionOperand& op);
125 
126 
127 #define INSTRUCTION_OPERAND_CASTS(OperandType, OperandKind)      \
128                                                                  \
129   static OperandType* cast(InstructionOperand* op) {             \
130     DCHECK_EQ(OperandKind, op->kind());                          \
131     return static_cast<OperandType*>(op);                        \
132   }                                                              \
133                                                                  \
134   static const OperandType* cast(const InstructionOperand* op) { \
135     DCHECK_EQ(OperandKind, op->kind());                          \
136     return static_cast<const OperandType*>(op);                  \
137   }                                                              \
138                                                                  \
139   static OperandType cast(const InstructionOperand& op) {        \
140     DCHECK_EQ(OperandKind, op.kind());                           \
141     return *static_cast<const OperandType*>(&op);                \
142   }
143 
144 class UnallocatedOperand : public InstructionOperand {
145  public:
146   enum BasicPolicy { FIXED_SLOT, EXTENDED_POLICY };
147 
148   enum ExtendedPolicy {
149     NONE,
150     ANY,
151     FIXED_REGISTER,
152     FIXED_DOUBLE_REGISTER,
153     MUST_HAVE_REGISTER,
154     MUST_HAVE_SLOT,
155     SAME_AS_FIRST_INPUT
156   };
157 
158   // Lifetime of operand inside the instruction.
159   enum Lifetime {
160     // USED_AT_START operand is guaranteed to be live only at
161     // instruction start. Register allocator is free to assign the same register
162     // to some other operand used inside instruction (i.e. temporary or
163     // output).
164     USED_AT_START,
165 
166     // USED_AT_END operand is treated as live until the end of
167     // instruction. This means that register allocator will not reuse it's
168     // register for any other operand inside instruction.
169     USED_AT_END
170   };
171 
UnallocatedOperand(ExtendedPolicy policy,int virtual_register)172   UnallocatedOperand(ExtendedPolicy policy, int virtual_register)
173       : UnallocatedOperand(virtual_register) {
174     value_ |= BasicPolicyField::encode(EXTENDED_POLICY);
175     value_ |= ExtendedPolicyField::encode(policy);
176     value_ |= LifetimeField::encode(USED_AT_END);
177   }
178 
UnallocatedOperand(BasicPolicy policy,int index,int virtual_register)179   UnallocatedOperand(BasicPolicy policy, int index, int virtual_register)
180       : UnallocatedOperand(virtual_register) {
181     DCHECK(policy == FIXED_SLOT);
182     value_ |= BasicPolicyField::encode(policy);
183     value_ |= static_cast<int64_t>(index) << FixedSlotIndexField::kShift;
184     DCHECK(this->fixed_slot_index() == index);
185   }
186 
UnallocatedOperand(ExtendedPolicy policy,int index,int virtual_register)187   UnallocatedOperand(ExtendedPolicy policy, int index, int virtual_register)
188       : UnallocatedOperand(virtual_register) {
189     DCHECK(policy == FIXED_REGISTER || policy == FIXED_DOUBLE_REGISTER);
190     value_ |= BasicPolicyField::encode(EXTENDED_POLICY);
191     value_ |= ExtendedPolicyField::encode(policy);
192     value_ |= LifetimeField::encode(USED_AT_END);
193     value_ |= FixedRegisterField::encode(index);
194   }
195 
UnallocatedOperand(ExtendedPolicy policy,Lifetime lifetime,int virtual_register)196   UnallocatedOperand(ExtendedPolicy policy, Lifetime lifetime,
197                      int virtual_register)
198       : UnallocatedOperand(virtual_register) {
199     value_ |= BasicPolicyField::encode(EXTENDED_POLICY);
200     value_ |= ExtendedPolicyField::encode(policy);
201     value_ |= LifetimeField::encode(lifetime);
202   }
203 
UnallocatedOperand(int reg_id,int slot_id,int virtual_register)204   UnallocatedOperand(int reg_id, int slot_id, int virtual_register)
205       : UnallocatedOperand(FIXED_REGISTER, reg_id, virtual_register) {
206     value_ |= HasSecondaryStorageField::encode(true);
207     value_ |= SecondaryStorageField::encode(slot_id);
208   }
209 
210   // Predicates for the operand policy.
HasAnyPolicy()211   bool HasAnyPolicy() const {
212     return basic_policy() == EXTENDED_POLICY && extended_policy() == ANY;
213   }
HasFixedPolicy()214   bool HasFixedPolicy() const {
215     return basic_policy() == FIXED_SLOT ||
216            extended_policy() == FIXED_REGISTER ||
217            extended_policy() == FIXED_DOUBLE_REGISTER;
218   }
HasRegisterPolicy()219   bool HasRegisterPolicy() const {
220     return basic_policy() == EXTENDED_POLICY &&
221            extended_policy() == MUST_HAVE_REGISTER;
222   }
HasSlotPolicy()223   bool HasSlotPolicy() const {
224     return basic_policy() == EXTENDED_POLICY &&
225            extended_policy() == MUST_HAVE_SLOT;
226   }
HasSameAsInputPolicy()227   bool HasSameAsInputPolicy() const {
228     return basic_policy() == EXTENDED_POLICY &&
229            extended_policy() == SAME_AS_FIRST_INPUT;
230   }
HasFixedSlotPolicy()231   bool HasFixedSlotPolicy() const { return basic_policy() == FIXED_SLOT; }
HasFixedRegisterPolicy()232   bool HasFixedRegisterPolicy() const {
233     return basic_policy() == EXTENDED_POLICY &&
234            extended_policy() == FIXED_REGISTER;
235   }
HasFixedDoubleRegisterPolicy()236   bool HasFixedDoubleRegisterPolicy() const {
237     return basic_policy() == EXTENDED_POLICY &&
238            extended_policy() == FIXED_DOUBLE_REGISTER;
239   }
HasSecondaryStorage()240   bool HasSecondaryStorage() const {
241     return basic_policy() == EXTENDED_POLICY &&
242            extended_policy() == FIXED_REGISTER &&
243            HasSecondaryStorageField::decode(value_);
244   }
GetSecondaryStorage()245   int GetSecondaryStorage() const {
246     DCHECK(HasSecondaryStorage());
247     return SecondaryStorageField::decode(value_);
248   }
249 
250   // [basic_policy]: Distinguish between FIXED_SLOT and all other policies.
basic_policy()251   BasicPolicy basic_policy() const {
252     DCHECK_EQ(UNALLOCATED, kind());
253     return BasicPolicyField::decode(value_);
254   }
255 
256   // [extended_policy]: Only for non-FIXED_SLOT. The finer-grained policy.
extended_policy()257   ExtendedPolicy extended_policy() const {
258     DCHECK(basic_policy() == EXTENDED_POLICY);
259     return ExtendedPolicyField::decode(value_);
260   }
261 
262   // [fixed_slot_index]: Only for FIXED_SLOT.
fixed_slot_index()263   int fixed_slot_index() const {
264     DCHECK(HasFixedSlotPolicy());
265     return static_cast<int>(static_cast<int64_t>(value_) >>
266                             FixedSlotIndexField::kShift);
267   }
268 
269   // [fixed_register_index]: Only for FIXED_REGISTER or FIXED_DOUBLE_REGISTER.
fixed_register_index()270   int fixed_register_index() const {
271     DCHECK(HasFixedRegisterPolicy() || HasFixedDoubleRegisterPolicy());
272     return FixedRegisterField::decode(value_);
273   }
274 
275   // [virtual_register]: The virtual register ID for this operand.
virtual_register()276   int32_t virtual_register() const {
277     DCHECK_EQ(UNALLOCATED, kind());
278     return static_cast<int32_t>(VirtualRegisterField::decode(value_));
279   }
280 
281   // TODO(dcarney): remove this.
set_virtual_register(int32_t id)282   void set_virtual_register(int32_t id) {
283     DCHECK_EQ(UNALLOCATED, kind());
284     value_ = VirtualRegisterField::update(value_, static_cast<uint32_t>(id));
285   }
286 
287   // [lifetime]: Only for non-FIXED_SLOT.
IsUsedAtStart()288   bool IsUsedAtStart() const {
289     DCHECK(basic_policy() == EXTENDED_POLICY);
290     return LifetimeField::decode(value_) == USED_AT_START;
291   }
292 
293   INSTRUCTION_OPERAND_CASTS(UnallocatedOperand, UNALLOCATED);
294 
295   // The encoding used for UnallocatedOperand operands depends on the policy
296   // that is
297   // stored within the operand. The FIXED_SLOT policy uses a compact encoding
298   // because it accommodates a larger pay-load.
299   //
300   // For FIXED_SLOT policy:
301   //     +------------------------------------------------+
302   //     |      slot_index   | 0 | virtual_register | 001 |
303   //     +------------------------------------------------+
304   //
305   // For all other (extended) policies:
306   //     +-----------------------------------------------------+
307   //     |  reg_index  | L | PPP |  1 | virtual_register | 001 |
308   //     +-----------------------------------------------------+
309   //     L ... Lifetime
310   //     P ... Policy
311   //
312   // The slot index is a signed value which requires us to decode it manually
313   // instead of using the BitField utility class.
314 
315   STATIC_ASSERT(KindField::kSize == 3);
316 
317   class VirtualRegisterField : public BitField64<uint32_t, 3, 32> {};
318 
319   // BitFields for all unallocated operands.
320   class BasicPolicyField : public BitField64<BasicPolicy, 35, 1> {};
321 
322   // BitFields specific to BasicPolicy::FIXED_SLOT.
323   class FixedSlotIndexField : public BitField64<int, 36, 28> {};
324 
325   // BitFields specific to BasicPolicy::EXTENDED_POLICY.
326   class ExtendedPolicyField : public BitField64<ExtendedPolicy, 36, 3> {};
327   class LifetimeField : public BitField64<Lifetime, 39, 1> {};
328   class HasSecondaryStorageField : public BitField64<bool, 40, 1> {};
329   class FixedRegisterField : public BitField64<int, 41, 6> {};
330   class SecondaryStorageField : public BitField64<int, 47, 3> {};
331 
332  private:
UnallocatedOperand(int virtual_register)333   explicit UnallocatedOperand(int virtual_register)
334       : InstructionOperand(UNALLOCATED) {
335     value_ |=
336         VirtualRegisterField::encode(static_cast<uint32_t>(virtual_register));
337   }
338 };
339 
340 
341 class ConstantOperand : public InstructionOperand {
342  public:
ConstantOperand(int virtual_register)343   explicit ConstantOperand(int virtual_register)
344       : InstructionOperand(CONSTANT) {
345     value_ |=
346         VirtualRegisterField::encode(static_cast<uint32_t>(virtual_register));
347   }
348 
virtual_register()349   int32_t virtual_register() const {
350     return static_cast<int32_t>(VirtualRegisterField::decode(value_));
351   }
352 
New(Zone * zone,int virtual_register)353   static ConstantOperand* New(Zone* zone, int virtual_register) {
354     return InstructionOperand::New(zone, ConstantOperand(virtual_register));
355   }
356 
357   INSTRUCTION_OPERAND_CASTS(ConstantOperand, CONSTANT);
358 
359   STATIC_ASSERT(KindField::kSize == 3);
360   class VirtualRegisterField : public BitField64<uint32_t, 3, 32> {};
361 };
362 
363 
364 class ImmediateOperand : public InstructionOperand {
365  public:
366   enum ImmediateType { INLINE, INDEXED };
367 
ImmediateOperand(ImmediateType type,int32_t value)368   explicit ImmediateOperand(ImmediateType type, int32_t value)
369       : InstructionOperand(IMMEDIATE) {
370     value_ |= TypeField::encode(type);
371     value_ |= static_cast<int64_t>(value) << ValueField::kShift;
372   }
373 
type()374   ImmediateType type() const { return TypeField::decode(value_); }
375 
inline_value()376   int32_t inline_value() const {
377     DCHECK_EQ(INLINE, type());
378     return static_cast<int64_t>(value_) >> ValueField::kShift;
379   }
380 
indexed_value()381   int32_t indexed_value() const {
382     DCHECK_EQ(INDEXED, type());
383     return static_cast<int64_t>(value_) >> ValueField::kShift;
384   }
385 
New(Zone * zone,ImmediateType type,int32_t value)386   static ImmediateOperand* New(Zone* zone, ImmediateType type, int32_t value) {
387     return InstructionOperand::New(zone, ImmediateOperand(type, value));
388   }
389 
390   INSTRUCTION_OPERAND_CASTS(ImmediateOperand, IMMEDIATE);
391 
392   STATIC_ASSERT(KindField::kSize == 3);
393   class TypeField : public BitField64<ImmediateType, 3, 1> {};
394   class ValueField : public BitField64<int32_t, 32, 32> {};
395 };
396 
397 
398 class LocationOperand : public InstructionOperand {
399  public:
400   enum LocationKind { REGISTER, STACK_SLOT };
401 
LocationOperand(InstructionOperand::Kind operand_kind,LocationOperand::LocationKind location_kind,MachineRepresentation rep,int index)402   LocationOperand(InstructionOperand::Kind operand_kind,
403                   LocationOperand::LocationKind location_kind,
404                   MachineRepresentation rep, int index)
405       : InstructionOperand(operand_kind) {
406     DCHECK_IMPLIES(location_kind == REGISTER, index >= 0);
407     DCHECK(IsSupportedRepresentation(rep));
408     value_ |= LocationKindField::encode(location_kind);
409     value_ |= RepresentationField::encode(rep);
410     value_ |= static_cast<int64_t>(index) << IndexField::kShift;
411   }
412 
index()413   int index() const {
414     DCHECK(IsStackSlot() || IsDoubleStackSlot());
415     return static_cast<int64_t>(value_) >> IndexField::kShift;
416   }
417 
GetRegister()418   Register GetRegister() const {
419     DCHECK(IsRegister());
420     return Register::from_code(static_cast<int64_t>(value_) >>
421                                IndexField::kShift);
422   }
423 
GetDoubleRegister()424   DoubleRegister GetDoubleRegister() const {
425     DCHECK(IsDoubleRegister());
426     return DoubleRegister::from_code(static_cast<int64_t>(value_) >>
427                                      IndexField::kShift);
428   }
429 
location_kind()430   LocationKind location_kind() const {
431     return LocationKindField::decode(value_);
432   }
433 
representation()434   MachineRepresentation representation() const {
435     return RepresentationField::decode(value_);
436   }
437 
IsSupportedRepresentation(MachineRepresentation rep)438   static bool IsSupportedRepresentation(MachineRepresentation rep) {
439     switch (rep) {
440       case MachineRepresentation::kWord32:
441       case MachineRepresentation::kWord64:
442       case MachineRepresentation::kFloat32:
443       case MachineRepresentation::kFloat64:
444       case MachineRepresentation::kTagged:
445         return true;
446       case MachineRepresentation::kBit:
447       case MachineRepresentation::kWord8:
448       case MachineRepresentation::kWord16:
449       case MachineRepresentation::kNone:
450         return false;
451     }
452     UNREACHABLE();
453     return false;
454   }
455 
cast(InstructionOperand * op)456   static LocationOperand* cast(InstructionOperand* op) {
457     DCHECK(ALLOCATED == op->kind() || EXPLICIT == op->kind());
458     return static_cast<LocationOperand*>(op);
459   }
460 
cast(const InstructionOperand * op)461   static const LocationOperand* cast(const InstructionOperand* op) {
462     DCHECK(ALLOCATED == op->kind() || EXPLICIT == op->kind());
463     return static_cast<const LocationOperand*>(op);
464   }
465 
cast(const InstructionOperand & op)466   static LocationOperand cast(const InstructionOperand& op) {
467     DCHECK(ALLOCATED == op.kind() || EXPLICIT == op.kind());
468     return *static_cast<const LocationOperand*>(&op);
469   }
470 
471   STATIC_ASSERT(KindField::kSize == 3);
472   class LocationKindField : public BitField64<LocationKind, 3, 2> {};
473   class RepresentationField : public BitField64<MachineRepresentation, 5, 8> {};
474   class IndexField : public BitField64<int32_t, 35, 29> {};
475 };
476 
477 
478 class ExplicitOperand : public LocationOperand {
479  public:
480   ExplicitOperand(LocationKind kind, MachineRepresentation rep, int index);
481 
New(Zone * zone,LocationKind kind,MachineRepresentation rep,int index)482   static ExplicitOperand* New(Zone* zone, LocationKind kind,
483                               MachineRepresentation rep, int index) {
484     return InstructionOperand::New(zone, ExplicitOperand(kind, rep, index));
485   }
486 
487   INSTRUCTION_OPERAND_CASTS(ExplicitOperand, EXPLICIT);
488 };
489 
490 
491 class AllocatedOperand : public LocationOperand {
492  public:
AllocatedOperand(LocationKind kind,MachineRepresentation rep,int index)493   AllocatedOperand(LocationKind kind, MachineRepresentation rep, int index)
494       : LocationOperand(ALLOCATED, kind, rep, index) {}
495 
New(Zone * zone,LocationKind kind,MachineRepresentation rep,int index)496   static AllocatedOperand* New(Zone* zone, LocationKind kind,
497                                MachineRepresentation rep, int index) {
498     return InstructionOperand::New(zone, AllocatedOperand(kind, rep, index));
499   }
500 
501   INSTRUCTION_OPERAND_CASTS(AllocatedOperand, ALLOCATED);
502 };
503 
504 
505 #undef INSTRUCTION_OPERAND_CASTS
506 
507 
IsAnyRegister()508 bool InstructionOperand::IsAnyRegister() const {
509   return (IsAllocated() || IsExplicit()) &&
510          LocationOperand::cast(this)->location_kind() ==
511              LocationOperand::REGISTER;
512 }
513 
514 
IsRegister()515 bool InstructionOperand::IsRegister() const {
516   return IsAnyRegister() &&
517          !IsFloatingPoint(LocationOperand::cast(this)->representation());
518 }
519 
IsDoubleRegister()520 bool InstructionOperand::IsDoubleRegister() const {
521   return IsAnyRegister() &&
522          IsFloatingPoint(LocationOperand::cast(this)->representation());
523 }
524 
IsStackSlot()525 bool InstructionOperand::IsStackSlot() const {
526   return (IsAllocated() || IsExplicit()) &&
527          LocationOperand::cast(this)->location_kind() ==
528              LocationOperand::STACK_SLOT &&
529          !IsFloatingPoint(LocationOperand::cast(this)->representation());
530 }
531 
IsDoubleStackSlot()532 bool InstructionOperand::IsDoubleStackSlot() const {
533   return (IsAllocated() || IsExplicit()) &&
534          LocationOperand::cast(this)->location_kind() ==
535              LocationOperand::STACK_SLOT &&
536          IsFloatingPoint(LocationOperand::cast(this)->representation());
537 }
538 
GetCanonicalizedValue()539 uint64_t InstructionOperand::GetCanonicalizedValue() const {
540   if (IsAllocated() || IsExplicit()) {
541     // TODO(dcarney): put machine type last and mask.
542     MachineRepresentation canonicalized_representation =
543         IsFloatingPoint(LocationOperand::cast(this)->representation())
544             ? MachineRepresentation::kFloat64
545             : MachineRepresentation::kNone;
546     return InstructionOperand::KindField::update(
547         LocationOperand::RepresentationField::update(
548             this->value_, canonicalized_representation),
549         LocationOperand::EXPLICIT);
550   }
551   return this->value_;
552 }
553 
554 
555 // Required for maps that don't care about machine type.
556 struct CompareOperandModuloType {
operatorCompareOperandModuloType557   bool operator()(const InstructionOperand& a,
558                   const InstructionOperand& b) const {
559     return a.CompareCanonicalized(b);
560   }
561 };
562 
563 
564 class MoveOperands final : public ZoneObject {
565  public:
MoveOperands(const InstructionOperand & source,const InstructionOperand & destination)566   MoveOperands(const InstructionOperand& source,
567                const InstructionOperand& destination)
568       : source_(source), destination_(destination) {
569     DCHECK(!source.IsInvalid() && !destination.IsInvalid());
570   }
571 
source()572   const InstructionOperand& source() const { return source_; }
source()573   InstructionOperand& source() { return source_; }
set_source(const InstructionOperand & operand)574   void set_source(const InstructionOperand& operand) { source_ = operand; }
575 
destination()576   const InstructionOperand& destination() const { return destination_; }
destination()577   InstructionOperand& destination() { return destination_; }
set_destination(const InstructionOperand & operand)578   void set_destination(const InstructionOperand& operand) {
579     destination_ = operand;
580   }
581 
582   // The gap resolver marks moves as "in-progress" by clearing the
583   // destination (but not the source).
IsPending()584   bool IsPending() const {
585     return destination_.IsInvalid() && !source_.IsInvalid();
586   }
SetPending()587   void SetPending() { destination_ = InstructionOperand(); }
588 
589   // True if this move a move into the given destination operand.
Blocks(const InstructionOperand & operand)590   bool Blocks(const InstructionOperand& operand) const {
591     return !IsEliminated() && source().EqualsCanonicalized(operand);
592   }
593 
594   // A move is redundant if it's been eliminated or if its source and
595   // destination are the same.
IsRedundant()596   bool IsRedundant() const {
597     DCHECK_IMPLIES(!destination_.IsInvalid(), !destination_.IsConstant());
598     return IsEliminated() || source_.EqualsCanonicalized(destination_);
599   }
600 
601   // We clear both operands to indicate move that's been eliminated.
Eliminate()602   void Eliminate() { source_ = destination_ = InstructionOperand(); }
IsEliminated()603   bool IsEliminated() const {
604     DCHECK_IMPLIES(source_.IsInvalid(), destination_.IsInvalid());
605     return source_.IsInvalid();
606   }
607 
608   void Print(const RegisterConfiguration* config) const;
609   void Print() const;
610 
611  private:
612   InstructionOperand source_;
613   InstructionOperand destination_;
614 
615   DISALLOW_COPY_AND_ASSIGN(MoveOperands);
616 };
617 
618 
619 struct PrintableMoveOperands {
620   const RegisterConfiguration* register_configuration_;
621   const MoveOperands* move_operands_;
622 };
623 
624 
625 std::ostream& operator<<(std::ostream& os, const PrintableMoveOperands& mo);
626 
627 
628 class ParallelMove final : public ZoneVector<MoveOperands*>, public ZoneObject {
629  public:
ParallelMove(Zone * zone)630   explicit ParallelMove(Zone* zone) : ZoneVector<MoveOperands*>(zone) {
631     reserve(4);
632   }
633 
AddMove(const InstructionOperand & from,const InstructionOperand & to)634   MoveOperands* AddMove(const InstructionOperand& from,
635                         const InstructionOperand& to) {
636     auto zone = get_allocator().zone();
637     auto move = new (zone) MoveOperands(from, to);
638     push_back(move);
639     return move;
640   }
641 
642   bool IsRedundant() const;
643 
644   // Prepare this ParallelMove to insert move as if it happened in a subsequent
645   // ParallelMove.  move->source() may be changed.  The MoveOperand returned
646   // must be Eliminated.
647   MoveOperands* PrepareInsertAfter(MoveOperands* move) const;
648 
649  private:
650   DISALLOW_COPY_AND_ASSIGN(ParallelMove);
651 };
652 
653 
654 struct PrintableParallelMove {
655   const RegisterConfiguration* register_configuration_;
656   const ParallelMove* parallel_move_;
657 };
658 
659 
660 std::ostream& operator<<(std::ostream& os, const PrintableParallelMove& pm);
661 
662 
663 class ReferenceMap final : public ZoneObject {
664  public:
ReferenceMap(Zone * zone)665   explicit ReferenceMap(Zone* zone)
666       : reference_operands_(8, zone), instruction_position_(-1) {}
667 
reference_operands()668   const ZoneVector<InstructionOperand>& reference_operands() const {
669     return reference_operands_;
670   }
instruction_position()671   int instruction_position() const { return instruction_position_; }
672 
set_instruction_position(int pos)673   void set_instruction_position(int pos) {
674     DCHECK(instruction_position_ == -1);
675     instruction_position_ = pos;
676   }
677 
678   void RecordReference(const AllocatedOperand& op);
679 
680  private:
681   friend std::ostream& operator<<(std::ostream& os, const ReferenceMap& pm);
682 
683   ZoneVector<InstructionOperand> reference_operands_;
684   int instruction_position_;
685 };
686 
687 std::ostream& operator<<(std::ostream& os, const ReferenceMap& pm);
688 
689 class Instruction final {
690  public:
OutputCount()691   size_t OutputCount() const { return OutputCountField::decode(bit_field_); }
OutputAt(size_t i)692   const InstructionOperand* OutputAt(size_t i) const {
693     DCHECK(i < OutputCount());
694     return &operands_[i];
695   }
OutputAt(size_t i)696   InstructionOperand* OutputAt(size_t i) {
697     DCHECK(i < OutputCount());
698     return &operands_[i];
699   }
700 
HasOutput()701   bool HasOutput() const { return OutputCount() == 1; }
Output()702   const InstructionOperand* Output() const { return OutputAt(0); }
Output()703   InstructionOperand* Output() { return OutputAt(0); }
704 
InputCount()705   size_t InputCount() const { return InputCountField::decode(bit_field_); }
InputAt(size_t i)706   const InstructionOperand* InputAt(size_t i) const {
707     DCHECK(i < InputCount());
708     return &operands_[OutputCount() + i];
709   }
InputAt(size_t i)710   InstructionOperand* InputAt(size_t i) {
711     DCHECK(i < InputCount());
712     return &operands_[OutputCount() + i];
713   }
714 
TempCount()715   size_t TempCount() const { return TempCountField::decode(bit_field_); }
TempAt(size_t i)716   const InstructionOperand* TempAt(size_t i) const {
717     DCHECK(i < TempCount());
718     return &operands_[OutputCount() + InputCount() + i];
719   }
TempAt(size_t i)720   InstructionOperand* TempAt(size_t i) {
721     DCHECK(i < TempCount());
722     return &operands_[OutputCount() + InputCount() + i];
723   }
724 
opcode()725   InstructionCode opcode() const { return opcode_; }
arch_opcode()726   ArchOpcode arch_opcode() const { return ArchOpcodeField::decode(opcode()); }
addressing_mode()727   AddressingMode addressing_mode() const {
728     return AddressingModeField::decode(opcode());
729   }
flags_mode()730   FlagsMode flags_mode() const { return FlagsModeField::decode(opcode()); }
flags_condition()731   FlagsCondition flags_condition() const {
732     return FlagsConditionField::decode(opcode());
733   }
734 
735   // TODO(titzer): make call into a flags.
New(Zone * zone,InstructionCode opcode)736   static Instruction* New(Zone* zone, InstructionCode opcode) {
737     return New(zone, opcode, 0, nullptr, 0, nullptr, 0, nullptr);
738   }
739 
New(Zone * zone,InstructionCode opcode,size_t output_count,InstructionOperand * outputs,size_t input_count,InstructionOperand * inputs,size_t temp_count,InstructionOperand * temps)740   static Instruction* New(Zone* zone, InstructionCode opcode,
741                           size_t output_count, InstructionOperand* outputs,
742                           size_t input_count, InstructionOperand* inputs,
743                           size_t temp_count, InstructionOperand* temps) {
744     DCHECK(opcode >= 0);
745     DCHECK(output_count == 0 || outputs != nullptr);
746     DCHECK(input_count == 0 || inputs != nullptr);
747     DCHECK(temp_count == 0 || temps != nullptr);
748     size_t total_extra_ops = output_count + input_count + temp_count;
749     if (total_extra_ops != 0) total_extra_ops--;
750     int size = static_cast<int>(
751         RoundUp(sizeof(Instruction), sizeof(InstructionOperand)) +
752         total_extra_ops * sizeof(InstructionOperand));
753     return new (zone->New(size)) Instruction(
754         opcode, output_count, outputs, input_count, inputs, temp_count, temps);
755   }
756 
MarkAsCall()757   Instruction* MarkAsCall() {
758     bit_field_ = IsCallField::update(bit_field_, true);
759     return this;
760   }
IsCall()761   bool IsCall() const { return IsCallField::decode(bit_field_); }
NeedsReferenceMap()762   bool NeedsReferenceMap() const { return IsCall(); }
HasReferenceMap()763   bool HasReferenceMap() const { return reference_map_ != nullptr; }
764 
ClobbersRegisters()765   bool ClobbersRegisters() const { return IsCall(); }
ClobbersTemps()766   bool ClobbersTemps() const { return IsCall(); }
ClobbersDoubleRegisters()767   bool ClobbersDoubleRegisters() const { return IsCall(); }
reference_map()768   ReferenceMap* reference_map() const { return reference_map_; }
769 
set_reference_map(ReferenceMap * map)770   void set_reference_map(ReferenceMap* map) {
771     DCHECK(NeedsReferenceMap());
772     DCHECK(!reference_map_);
773     reference_map_ = map;
774   }
775 
OverwriteWithNop()776   void OverwriteWithNop() {
777     opcode_ = ArchOpcodeField::encode(kArchNop);
778     bit_field_ = 0;
779     reference_map_ = nullptr;
780   }
781 
IsNop()782   bool IsNop() const {
783     return arch_opcode() == kArchNop && InputCount() == 0 &&
784            OutputCount() == 0 && TempCount() == 0;
785   }
786 
787   enum GapPosition {
788     START,
789     END,
790     FIRST_GAP_POSITION = START,
791     LAST_GAP_POSITION = END
792   };
793 
GetOrCreateParallelMove(GapPosition pos,Zone * zone)794   ParallelMove* GetOrCreateParallelMove(GapPosition pos, Zone* zone) {
795     if (parallel_moves_[pos] == nullptr) {
796       parallel_moves_[pos] = new (zone) ParallelMove(zone);
797     }
798     return parallel_moves_[pos];
799   }
800 
GetParallelMove(GapPosition pos)801   ParallelMove* GetParallelMove(GapPosition pos) {
802     return parallel_moves_[pos];
803   }
804 
GetParallelMove(GapPosition pos)805   const ParallelMove* GetParallelMove(GapPosition pos) const {
806     return parallel_moves_[pos];
807   }
808 
809   bool AreMovesRedundant() const;
810 
parallel_moves()811   ParallelMove* const* parallel_moves() const { return &parallel_moves_[0]; }
parallel_moves()812   ParallelMove** parallel_moves() { return &parallel_moves_[0]; }
813 
814   void Print(const RegisterConfiguration* config) const;
815   void Print() const;
816 
817  private:
818   explicit Instruction(InstructionCode opcode);
819 
820   Instruction(InstructionCode opcode, size_t output_count,
821               InstructionOperand* outputs, size_t input_count,
822               InstructionOperand* inputs, size_t temp_count,
823               InstructionOperand* temps);
824 
825   typedef BitField<size_t, 0, 8> OutputCountField;
826   typedef BitField<size_t, 8, 16> InputCountField;
827   typedef BitField<size_t, 24, 6> TempCountField;
828   typedef BitField<bool, 30, 1> IsCallField;
829 
830   InstructionCode opcode_;
831   uint32_t bit_field_;
832   ParallelMove* parallel_moves_[2];
833   ReferenceMap* reference_map_;
834   InstructionOperand operands_[1];
835 
836   DISALLOW_COPY_AND_ASSIGN(Instruction);
837 };
838 
839 
840 struct PrintableInstruction {
841   const RegisterConfiguration* register_configuration_;
842   const Instruction* instr_;
843 };
844 std::ostream& operator<<(std::ostream& os, const PrintableInstruction& instr);
845 
846 
847 class RpoNumber final {
848  public:
849   static const int kInvalidRpoNumber = -1;
ToInt()850   int ToInt() const {
851     DCHECK(IsValid());
852     return index_;
853   }
ToSize()854   size_t ToSize() const {
855     DCHECK(IsValid());
856     return static_cast<size_t>(index_);
857   }
IsValid()858   bool IsValid() const { return index_ >= 0; }
FromInt(int index)859   static RpoNumber FromInt(int index) { return RpoNumber(index); }
Invalid()860   static RpoNumber Invalid() { return RpoNumber(kInvalidRpoNumber); }
861 
IsNext(const RpoNumber other)862   bool IsNext(const RpoNumber other) const {
863     DCHECK(IsValid());
864     return other.index_ == this->index_ + 1;
865   }
866 
867   // Comparison operators.
868   bool operator==(RpoNumber other) const { return index_ == other.index_; }
869   bool operator!=(RpoNumber other) const { return index_ != other.index_; }
870   bool operator>(RpoNumber other) const { return index_ > other.index_; }
871   bool operator<(RpoNumber other) const { return index_ < other.index_; }
872   bool operator<=(RpoNumber other) const { return index_ <= other.index_; }
873   bool operator>=(RpoNumber other) const { return index_ >= other.index_; }
874 
875  private:
RpoNumber(int32_t index)876   explicit RpoNumber(int32_t index) : index_(index) {}
877   int32_t index_;
878 };
879 
880 
881 std::ostream& operator<<(std::ostream&, const RpoNumber&);
882 
883 
884 class Constant final {
885  public:
886   enum Type {
887     kInt32,
888     kInt64,
889     kFloat32,
890     kFloat64,
891     kExternalReference,
892     kHeapObject,
893     kRpoNumber
894   };
895 
896   explicit Constant(int32_t v);
Constant(int64_t v)897   explicit Constant(int64_t v) : type_(kInt64), value_(v) {}
Constant(float v)898   explicit Constant(float v) : type_(kFloat32), value_(bit_cast<int32_t>(v)) {}
Constant(double v)899   explicit Constant(double v) : type_(kFloat64), value_(bit_cast<int64_t>(v)) {}
Constant(ExternalReference ref)900   explicit Constant(ExternalReference ref)
901       : type_(kExternalReference), value_(bit_cast<intptr_t>(ref)) {}
Constant(Handle<HeapObject> obj)902   explicit Constant(Handle<HeapObject> obj)
903       : type_(kHeapObject), value_(bit_cast<intptr_t>(obj)) {}
Constant(RpoNumber rpo)904   explicit Constant(RpoNumber rpo) : type_(kRpoNumber), value_(rpo.ToInt()) {}
905 
type()906   Type type() const { return type_; }
907 
ToInt32()908   int32_t ToInt32() const {
909     DCHECK(type() == kInt32 || type() == kInt64);
910     const int32_t value = static_cast<int32_t>(value_);
911     DCHECK_EQ(value_, static_cast<int64_t>(value));
912     return value;
913   }
914 
ToInt64()915   int64_t ToInt64() const {
916     if (type() == kInt32) return ToInt32();
917     DCHECK_EQ(kInt64, type());
918     return value_;
919   }
920 
ToFloat32()921   float ToFloat32() const {
922     DCHECK_EQ(kFloat32, type());
923     return bit_cast<float>(static_cast<int32_t>(value_));
924   }
925 
ToFloat64()926   double ToFloat64() const {
927     if (type() == kInt32) return ToInt32();
928     DCHECK_EQ(kFloat64, type());
929     return bit_cast<double>(value_);
930   }
931 
ToExternalReference()932   ExternalReference ToExternalReference() const {
933     DCHECK_EQ(kExternalReference, type());
934     return bit_cast<ExternalReference>(static_cast<intptr_t>(value_));
935   }
936 
ToRpoNumber()937   RpoNumber ToRpoNumber() const {
938     DCHECK_EQ(kRpoNumber, type());
939     return RpoNumber::FromInt(static_cast<int>(value_));
940   }
941 
ToHeapObject()942   Handle<HeapObject> ToHeapObject() const {
943     DCHECK_EQ(kHeapObject, type());
944     return bit_cast<Handle<HeapObject> >(static_cast<intptr_t>(value_));
945   }
946 
947  private:
948   Type type_;
949   int64_t value_;
950 };
951 
952 
953 std::ostream& operator<<(std::ostream& os, const Constant& constant);
954 
955 
956 // Forward declarations.
957 class FrameStateDescriptor;
958 
959 
960 enum class StateValueKind { kPlain, kNested, kDuplicate };
961 
962 
963 class StateValueDescriptor {
964  public:
StateValueDescriptor(Zone * zone)965   explicit StateValueDescriptor(Zone* zone)
966       : kind_(StateValueKind::kPlain),
967         type_(MachineType::AnyTagged()),
968         id_(0),
969         fields_(zone) {}
970 
Plain(Zone * zone,MachineType type)971   static StateValueDescriptor Plain(Zone* zone, MachineType type) {
972     return StateValueDescriptor(StateValueKind::kPlain, zone, type, 0);
973   }
Recursive(Zone * zone,size_t id)974   static StateValueDescriptor Recursive(Zone* zone, size_t id) {
975     return StateValueDescriptor(StateValueKind::kNested, zone,
976                                 MachineType::AnyTagged(), id);
977   }
Duplicate(Zone * zone,size_t id)978   static StateValueDescriptor Duplicate(Zone* zone, size_t id) {
979     return StateValueDescriptor(StateValueKind::kDuplicate, zone,
980                                 MachineType::AnyTagged(), id);
981   }
982 
size()983   size_t size() { return fields_.size(); }
fields()984   ZoneVector<StateValueDescriptor>& fields() { return fields_; }
IsPlain()985   int IsPlain() { return kind_ == StateValueKind::kPlain; }
IsNested()986   int IsNested() { return kind_ == StateValueKind::kNested; }
IsDuplicate()987   int IsDuplicate() { return kind_ == StateValueKind::kDuplicate; }
type()988   MachineType type() const { return type_; }
GetOperandType(size_t index)989   MachineType GetOperandType(size_t index) const {
990     return fields_[index].type_;
991   }
id()992   size_t id() const { return id_; }
993 
994  private:
StateValueDescriptor(StateValueKind kind,Zone * zone,MachineType type,size_t id)995   StateValueDescriptor(StateValueKind kind, Zone* zone, MachineType type,
996                        size_t id)
997       : kind_(kind), type_(type), id_(id), fields_(zone) {}
998 
999   StateValueKind kind_;
1000   MachineType type_;
1001   size_t id_;
1002   ZoneVector<StateValueDescriptor> fields_;
1003 };
1004 
1005 
1006 class FrameStateDescriptor : public ZoneObject {
1007  public:
1008   FrameStateDescriptor(Zone* zone, FrameStateType type, BailoutId bailout_id,
1009                        OutputFrameStateCombine state_combine,
1010                        size_t parameters_count, size_t locals_count,
1011                        size_t stack_count,
1012                        MaybeHandle<SharedFunctionInfo> shared_info,
1013                        FrameStateDescriptor* outer_state = nullptr);
1014 
type()1015   FrameStateType type() const { return type_; }
bailout_id()1016   BailoutId bailout_id() const { return bailout_id_; }
state_combine()1017   OutputFrameStateCombine state_combine() const { return frame_state_combine_; }
parameters_count()1018   size_t parameters_count() const { return parameters_count_; }
locals_count()1019   size_t locals_count() const { return locals_count_; }
stack_count()1020   size_t stack_count() const { return stack_count_; }
shared_info()1021   MaybeHandle<SharedFunctionInfo> shared_info() const { return shared_info_; }
outer_state()1022   FrameStateDescriptor* outer_state() const { return outer_state_; }
HasContext()1023   bool HasContext() const {
1024     return FrameStateFunctionInfo::IsJSFunctionType(type_);
1025   }
1026 
1027   size_t GetSize(OutputFrameStateCombine combine =
1028                      OutputFrameStateCombine::Ignore()) const;
1029   size_t GetTotalSize() const;
1030   size_t GetFrameCount() const;
1031   size_t GetJSFrameCount() const;
1032 
GetType(size_t index)1033   MachineType GetType(size_t index) const {
1034     return values_.GetOperandType(index);
1035   }
GetStateValueDescriptor()1036   StateValueDescriptor* GetStateValueDescriptor() { return &values_; }
1037 
1038  private:
1039   FrameStateType type_;
1040   BailoutId bailout_id_;
1041   OutputFrameStateCombine frame_state_combine_;
1042   size_t parameters_count_;
1043   size_t locals_count_;
1044   size_t stack_count_;
1045   StateValueDescriptor values_;
1046   MaybeHandle<SharedFunctionInfo> const shared_info_;
1047   FrameStateDescriptor* outer_state_;
1048 };
1049 
1050 
1051 typedef ZoneVector<FrameStateDescriptor*> DeoptimizationVector;
1052 
1053 
1054 class PhiInstruction final : public ZoneObject {
1055  public:
1056   typedef ZoneVector<InstructionOperand> Inputs;
1057 
1058   PhiInstruction(Zone* zone, int virtual_register, size_t input_count);
1059 
1060   void SetInput(size_t offset, int virtual_register);
1061 
virtual_register()1062   int virtual_register() const { return virtual_register_; }
operands()1063   const IntVector& operands() const { return operands_; }
1064 
1065   // TODO(dcarney): this has no real business being here, since it's internal to
1066   // the register allocator, but putting it here was convenient.
output()1067   const InstructionOperand& output() const { return output_; }
output()1068   InstructionOperand& output() { return output_; }
1069 
1070  private:
1071   const int virtual_register_;
1072   InstructionOperand output_;
1073   IntVector operands_;
1074 };
1075 
1076 
1077 // Analogue of BasicBlock for Instructions instead of Nodes.
1078 class InstructionBlock final : public ZoneObject {
1079  public:
1080   InstructionBlock(Zone* zone, RpoNumber rpo_number, RpoNumber loop_header,
1081                    RpoNumber loop_end, bool deferred, bool handler);
1082 
1083   // Instruction indexes (used by the register allocator).
first_instruction_index()1084   int first_instruction_index() const {
1085     DCHECK(code_start_ >= 0);
1086     DCHECK(code_end_ > 0);
1087     DCHECK(code_end_ >= code_start_);
1088     return code_start_;
1089   }
last_instruction_index()1090   int last_instruction_index() const {
1091     DCHECK(code_start_ >= 0);
1092     DCHECK(code_end_ > 0);
1093     DCHECK(code_end_ >= code_start_);
1094     return code_end_ - 1;
1095   }
1096 
code_start()1097   int32_t code_start() const { return code_start_; }
set_code_start(int32_t start)1098   void set_code_start(int32_t start) { code_start_ = start; }
1099 
code_end()1100   int32_t code_end() const { return code_end_; }
set_code_end(int32_t end)1101   void set_code_end(int32_t end) { code_end_ = end; }
1102 
IsDeferred()1103   bool IsDeferred() const { return deferred_; }
IsHandler()1104   bool IsHandler() const { return handler_; }
1105 
ao_number()1106   RpoNumber ao_number() const { return ao_number_; }
rpo_number()1107   RpoNumber rpo_number() const { return rpo_number_; }
loop_header()1108   RpoNumber loop_header() const { return loop_header_; }
loop_end()1109   RpoNumber loop_end() const {
1110     DCHECK(IsLoopHeader());
1111     return loop_end_;
1112   }
IsLoopHeader()1113   inline bool IsLoopHeader() const { return loop_end_.IsValid(); }
1114 
1115   typedef ZoneVector<RpoNumber> Predecessors;
predecessors()1116   Predecessors& predecessors() { return predecessors_; }
predecessors()1117   const Predecessors& predecessors() const { return predecessors_; }
PredecessorCount()1118   size_t PredecessorCount() const { return predecessors_.size(); }
1119   size_t PredecessorIndexOf(RpoNumber rpo_number) const;
1120 
1121   typedef ZoneVector<RpoNumber> Successors;
successors()1122   Successors& successors() { return successors_; }
successors()1123   const Successors& successors() const { return successors_; }
SuccessorCount()1124   size_t SuccessorCount() const { return successors_.size(); }
1125 
1126   typedef ZoneVector<PhiInstruction*> PhiInstructions;
phis()1127   const PhiInstructions& phis() const { return phis_; }
AddPhi(PhiInstruction * phi)1128   void AddPhi(PhiInstruction* phi) { phis_.push_back(phi); }
1129 
set_ao_number(RpoNumber ao_number)1130   void set_ao_number(RpoNumber ao_number) { ao_number_ = ao_number; }
1131 
needs_frame()1132   bool needs_frame() const { return needs_frame_; }
mark_needs_frame()1133   void mark_needs_frame() { needs_frame_ = true; }
1134 
must_construct_frame()1135   bool must_construct_frame() const { return must_construct_frame_; }
mark_must_construct_frame()1136   void mark_must_construct_frame() { must_construct_frame_ = true; }
1137 
must_deconstruct_frame()1138   bool must_deconstruct_frame() const { return must_deconstruct_frame_; }
mark_must_deconstruct_frame()1139   void mark_must_deconstruct_frame() { must_deconstruct_frame_ = true; }
1140 
set_last_deferred(RpoNumber last)1141   void set_last_deferred(RpoNumber last) { last_deferred_ = last; }
last_deferred()1142   RpoNumber last_deferred() const { return last_deferred_; }
1143 
1144  private:
1145   Successors successors_;
1146   Predecessors predecessors_;
1147   PhiInstructions phis_;
1148   RpoNumber ao_number_;  // Assembly order number.
1149   const RpoNumber rpo_number_;
1150   const RpoNumber loop_header_;
1151   const RpoNumber loop_end_;
1152   int32_t code_start_;   // start index of arch-specific code.
1153   int32_t code_end_;     // end index of arch-specific code.
1154   const bool deferred_;  // Block contains deferred code.
1155   const bool handler_;   // Block is a handler entry point.
1156   bool needs_frame_;
1157   bool must_construct_frame_;
1158   bool must_deconstruct_frame_;
1159   RpoNumber last_deferred_;
1160 };
1161 
1162 typedef ZoneDeque<Constant> ConstantDeque;
1163 typedef std::map<int, Constant, std::less<int>,
1164                  zone_allocator<std::pair<const int, Constant> > > ConstantMap;
1165 
1166 typedef ZoneDeque<Instruction*> InstructionDeque;
1167 typedef ZoneDeque<ReferenceMap*> ReferenceMapDeque;
1168 typedef ZoneVector<InstructionBlock*> InstructionBlocks;
1169 
1170 
1171 // Forward declarations.
1172 struct PrintableInstructionSequence;
1173 
1174 
1175 // Represents architecture-specific generated code before, during, and after
1176 // register allocation.
1177 class InstructionSequence final : public ZoneObject {
1178  public:
1179   static InstructionBlocks* InstructionBlocksFor(Zone* zone,
1180                                                  const Schedule* schedule);
1181   // Puts the deferred blocks last.
1182   static void ComputeAssemblyOrder(InstructionBlocks* blocks);
1183 
1184   InstructionSequence(Isolate* isolate, Zone* zone,
1185                       InstructionBlocks* instruction_blocks);
1186 
1187   int NextVirtualRegister();
VirtualRegisterCount()1188   int VirtualRegisterCount() const { return next_virtual_register_; }
1189 
instruction_blocks()1190   const InstructionBlocks& instruction_blocks() const {
1191     return *instruction_blocks_;
1192   }
1193 
InstructionBlockCount()1194   int InstructionBlockCount() const {
1195     return static_cast<int>(instruction_blocks_->size());
1196   }
1197 
InstructionBlockAt(RpoNumber rpo_number)1198   InstructionBlock* InstructionBlockAt(RpoNumber rpo_number) {
1199     return instruction_blocks_->at(rpo_number.ToSize());
1200   }
1201 
LastLoopInstructionIndex(const InstructionBlock * block)1202   int LastLoopInstructionIndex(const InstructionBlock* block) {
1203     return instruction_blocks_->at(block->loop_end().ToSize() - 1)
1204         ->last_instruction_index();
1205   }
1206 
InstructionBlockAt(RpoNumber rpo_number)1207   const InstructionBlock* InstructionBlockAt(RpoNumber rpo_number) const {
1208     return instruction_blocks_->at(rpo_number.ToSize());
1209   }
1210 
1211   InstructionBlock* GetInstructionBlock(int instruction_index) const;
1212 
DefaultRepresentation()1213   static MachineRepresentation DefaultRepresentation() {
1214     return MachineType::PointerRepresentation();
1215   }
1216   MachineRepresentation GetRepresentation(int virtual_register) const;
1217   void MarkAsRepresentation(MachineRepresentation rep, int virtual_register);
1218 
IsReference(int virtual_register)1219   bool IsReference(int virtual_register) const {
1220     return GetRepresentation(virtual_register) ==
1221            MachineRepresentation::kTagged;
1222   }
IsFloat(int virtual_register)1223   bool IsFloat(int virtual_register) const {
1224     return IsFloatingPoint(GetRepresentation(virtual_register));
1225   }
1226 
1227   Instruction* GetBlockStart(RpoNumber rpo) const;
1228 
1229   typedef InstructionDeque::const_iterator const_iterator;
begin()1230   const_iterator begin() const { return instructions_.begin(); }
end()1231   const_iterator end() const { return instructions_.end(); }
instructions()1232   const InstructionDeque& instructions() const { return instructions_; }
LastInstructionIndex()1233   int LastInstructionIndex() const {
1234     return static_cast<int>(instructions().size()) - 1;
1235   }
1236 
InstructionAt(int index)1237   Instruction* InstructionAt(int index) const {
1238     DCHECK(index >= 0);
1239     DCHECK(index < static_cast<int>(instructions_.size()));
1240     return instructions_[index];
1241   }
1242 
isolate()1243   Isolate* isolate() const { return isolate_; }
reference_maps()1244   const ReferenceMapDeque* reference_maps() const { return &reference_maps_; }
zone()1245   Zone* zone() const { return zone_; }
1246 
1247   // Used by the instruction selector while adding instructions.
1248   int AddInstruction(Instruction* instr);
1249   void StartBlock(RpoNumber rpo);
1250   void EndBlock(RpoNumber rpo);
1251 
AddConstant(int virtual_register,Constant constant)1252   int AddConstant(int virtual_register, Constant constant) {
1253     // TODO(titzer): allow RPO numbers as constants?
1254     DCHECK(constant.type() != Constant::kRpoNumber);
1255     DCHECK(virtual_register >= 0 && virtual_register < next_virtual_register_);
1256     DCHECK(constants_.find(virtual_register) == constants_.end());
1257     constants_.insert(std::make_pair(virtual_register, constant));
1258     return virtual_register;
1259   }
GetConstant(int virtual_register)1260   Constant GetConstant(int virtual_register) const {
1261     ConstantMap::const_iterator it = constants_.find(virtual_register);
1262     DCHECK(it != constants_.end());
1263     DCHECK_EQ(virtual_register, it->first);
1264     return it->second;
1265   }
1266 
1267   typedef ZoneVector<Constant> Immediates;
immediates()1268   Immediates& immediates() { return immediates_; }
1269 
AddImmediate(const Constant & constant)1270   ImmediateOperand AddImmediate(const Constant& constant) {
1271     if (constant.type() == Constant::kInt32) {
1272       return ImmediateOperand(ImmediateOperand::INLINE, constant.ToInt32());
1273     }
1274     int index = static_cast<int>(immediates_.size());
1275     immediates_.push_back(constant);
1276     return ImmediateOperand(ImmediateOperand::INDEXED, index);
1277   }
1278 
GetImmediate(const ImmediateOperand * op)1279   Constant GetImmediate(const ImmediateOperand* op) const {
1280     switch (op->type()) {
1281       case ImmediateOperand::INLINE:
1282         return Constant(op->inline_value());
1283       case ImmediateOperand::INDEXED: {
1284         int index = op->indexed_value();
1285         DCHECK(index >= 0);
1286         DCHECK(index < static_cast<int>(immediates_.size()));
1287         return immediates_[index];
1288       }
1289     }
1290     UNREACHABLE();
1291     return Constant(static_cast<int32_t>(0));
1292   }
1293 
1294   class StateId {
1295    public:
FromInt(int id)1296     static StateId FromInt(int id) { return StateId(id); }
ToInt()1297     int ToInt() const { return id_; }
1298 
1299    private:
StateId(int id)1300     explicit StateId(int id) : id_(id) {}
1301     int id_;
1302   };
1303 
1304   StateId AddFrameStateDescriptor(FrameStateDescriptor* descriptor);
1305   FrameStateDescriptor* GetFrameStateDescriptor(StateId deoptimization_id);
1306   int GetFrameStateDescriptorCount();
frame_state_descriptors()1307   DeoptimizationVector const& frame_state_descriptors() const {
1308     return deoptimization_entries_;
1309   }
1310 
1311   RpoNumber InputRpo(Instruction* instr, size_t index);
1312 
1313   bool GetSourcePosition(const Instruction* instr,
1314                          SourcePosition* result) const;
1315   void SetSourcePosition(const Instruction* instr, SourcePosition value);
1316 
ContainsCall()1317   bool ContainsCall() const {
1318     for (Instruction* instr : instructions_) {
1319       if (instr->IsCall()) return true;
1320     }
1321     return false;
1322   }
1323   void Print(const RegisterConfiguration* config) const;
1324   void Print() const;
1325 
1326  private:
1327   friend std::ostream& operator<<(std::ostream& os,
1328                                   const PrintableInstructionSequence& code);
1329 
1330   typedef ZoneMap<const Instruction*, SourcePosition> SourcePositionMap;
1331 
1332   Isolate* isolate_;
1333   Zone* const zone_;
1334   InstructionBlocks* const instruction_blocks_;
1335   SourcePositionMap source_positions_;
1336   IntVector block_starts_;
1337   ConstantMap constants_;
1338   Immediates immediates_;
1339   InstructionDeque instructions_;
1340   int next_virtual_register_;
1341   ReferenceMapDeque reference_maps_;
1342   ZoneVector<MachineRepresentation> representations_;
1343   DeoptimizationVector deoptimization_entries_;
1344 
1345   DISALLOW_COPY_AND_ASSIGN(InstructionSequence);
1346 };
1347 
1348 
1349 struct PrintableInstructionSequence {
1350   const RegisterConfiguration* register_configuration_;
1351   const InstructionSequence* sequence_;
1352 };
1353 
1354 
1355 std::ostream& operator<<(std::ostream& os,
1356                          const PrintableInstructionSequence& code);
1357 
1358 }  // namespace compiler
1359 }  // namespace internal
1360 }  // namespace v8
1361 
1362 #endif  // V8_COMPILER_INSTRUCTION_H_
1363