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1 //=== Target/TargetRegisterInfo.h - Target Register Information -*- C++ -*-===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------------===//
9 //
10 // This file describes an abstract interface used to get information about a
11 // target machines register file.  This information is used for a variety of
12 // purposed, especially register allocation.
13 //
14 //===----------------------------------------------------------------------===//
15 
16 #ifndef LLVM_TARGET_TARGETREGISTERINFO_H
17 #define LLVM_TARGET_TARGETREGISTERINFO_H
18 
19 #include "llvm/ADT/ArrayRef.h"
20 #include "llvm/CodeGen/MachineBasicBlock.h"
21 #include "llvm/CodeGen/MachineValueType.h"
22 #include "llvm/IR/CallingConv.h"
23 #include "llvm/MC/MCRegisterInfo.h"
24 #include <cassert>
25 #include <functional>
26 
27 namespace llvm {
28 
29 class BitVector;
30 class MachineFunction;
31 class RegScavenger;
32 template<class T> class SmallVectorImpl;
33 class VirtRegMap;
34 class raw_ostream;
35 
36 class TargetRegisterClass {
37 public:
38   typedef const MCPhysReg* iterator;
39   typedef const MCPhysReg* const_iterator;
40   typedef const MVT::SimpleValueType* vt_iterator;
41   typedef const TargetRegisterClass* const * sc_iterator;
42 
43   // Instance variables filled by tablegen, do not use!
44   const MCRegisterClass *MC;
45   const vt_iterator VTs;
46   const uint32_t *SubClassMask;
47   const uint16_t *SuperRegIndices;
48   const unsigned LaneMask;
49   /// Classes with a higher priority value are assigned first by register
50   /// allocators using a greedy heuristic. The value is in the range [0,63].
51   const uint8_t AllocationPriority;
52   /// Whether the class supports two (or more) disjunct subregister indices.
53   const bool HasDisjunctSubRegs;
54   const sc_iterator SuperClasses;
55   ArrayRef<MCPhysReg> (*OrderFunc)(const MachineFunction&);
56 
57   /// getID() - Return the register class ID number.
58   ///
getID()59   unsigned getID() const { return MC->getID(); }
60 
61   /// begin/end - Return all of the registers in this class.
62   ///
begin()63   iterator       begin() const { return MC->begin(); }
end()64   iterator         end() const { return MC->end(); }
65 
66   /// getNumRegs - Return the number of registers in this class.
67   ///
getNumRegs()68   unsigned getNumRegs() const { return MC->getNumRegs(); }
69 
70   /// getRegister - Return the specified register in the class.
71   ///
getRegister(unsigned i)72   unsigned getRegister(unsigned i) const {
73     return MC->getRegister(i);
74   }
75 
76   /// contains - Return true if the specified register is included in this
77   /// register class.  This does not include virtual registers.
contains(unsigned Reg)78   bool contains(unsigned Reg) const {
79     return MC->contains(Reg);
80   }
81 
82   /// contains - Return true if both registers are in this class.
contains(unsigned Reg1,unsigned Reg2)83   bool contains(unsigned Reg1, unsigned Reg2) const {
84     return MC->contains(Reg1, Reg2);
85   }
86 
87   /// getSize - Return the size of the register in bytes, which is also the size
88   /// of a stack slot allocated to hold a spilled copy of this register.
getSize()89   unsigned getSize() const { return MC->getSize(); }
90 
91   /// getAlignment - Return the minimum required alignment for a register of
92   /// this class.
getAlignment()93   unsigned getAlignment() const { return MC->getAlignment(); }
94 
95   /// getCopyCost - Return the cost of copying a value between two registers in
96   /// this class. A negative number means the register class is very expensive
97   /// to copy e.g. status flag register classes.
getCopyCost()98   int getCopyCost() const { return MC->getCopyCost(); }
99 
100   /// isAllocatable - Return true if this register class may be used to create
101   /// virtual registers.
isAllocatable()102   bool isAllocatable() const { return MC->isAllocatable(); }
103 
104   /// hasType - return true if this TargetRegisterClass has the ValueType vt.
105   ///
hasType(MVT vt)106   bool hasType(MVT vt) const {
107     for(int i = 0; VTs[i] != MVT::Other; ++i)
108       if (MVT(VTs[i]) == vt)
109         return true;
110     return false;
111   }
112 
113   /// vt_begin / vt_end - Loop over all of the value types that can be
114   /// represented by values in this register class.
vt_begin()115   vt_iterator vt_begin() const {
116     return VTs;
117   }
118 
vt_end()119   vt_iterator vt_end() const {
120     vt_iterator I = VTs;
121     while (*I != MVT::Other) ++I;
122     return I;
123   }
124 
125   /// hasSubClass - return true if the specified TargetRegisterClass
126   /// is a proper sub-class of this TargetRegisterClass.
hasSubClass(const TargetRegisterClass * RC)127   bool hasSubClass(const TargetRegisterClass *RC) const {
128     return RC != this && hasSubClassEq(RC);
129   }
130 
131   /// hasSubClassEq - Returns true if RC is a sub-class of or equal to this
132   /// class.
hasSubClassEq(const TargetRegisterClass * RC)133   bool hasSubClassEq(const TargetRegisterClass *RC) const {
134     unsigned ID = RC->getID();
135     return (SubClassMask[ID / 32] >> (ID % 32)) & 1;
136   }
137 
138   /// hasSuperClass - return true if the specified TargetRegisterClass is a
139   /// proper super-class of this TargetRegisterClass.
hasSuperClass(const TargetRegisterClass * RC)140   bool hasSuperClass(const TargetRegisterClass *RC) const {
141     return RC->hasSubClass(this);
142   }
143 
144   /// hasSuperClassEq - Returns true if RC is a super-class of or equal to this
145   /// class.
hasSuperClassEq(const TargetRegisterClass * RC)146   bool hasSuperClassEq(const TargetRegisterClass *RC) const {
147     return RC->hasSubClassEq(this);
148   }
149 
150   /// getSubClassMask - Returns a bit vector of subclasses, including this one.
151   /// The vector is indexed by class IDs, see hasSubClassEq() above for how to
152   /// use it.
getSubClassMask()153   const uint32_t *getSubClassMask() const {
154     return SubClassMask;
155   }
156 
157   /// getSuperRegIndices - Returns a 0-terminated list of sub-register indices
158   /// that project some super-register class into this register class. The list
159   /// has an entry for each Idx such that:
160   ///
161   ///   There exists SuperRC where:
162   ///     For all Reg in SuperRC:
163   ///       this->contains(Reg:Idx)
164   ///
getSuperRegIndices()165   const uint16_t *getSuperRegIndices() const {
166     return SuperRegIndices;
167   }
168 
169   /// getSuperClasses - Returns a NULL terminated list of super-classes.  The
170   /// classes are ordered by ID which is also a topological ordering from large
171   /// to small classes.  The list does NOT include the current class.
getSuperClasses()172   sc_iterator getSuperClasses() const {
173     return SuperClasses;
174   }
175 
176   /// isASubClass - return true if this TargetRegisterClass is a subset
177   /// class of at least one other TargetRegisterClass.
isASubClass()178   bool isASubClass() const {
179     return SuperClasses[0] != nullptr;
180   }
181 
182   /// getRawAllocationOrder - Returns the preferred order for allocating
183   /// registers from this register class in MF. The raw order comes directly
184   /// from the .td file and may include reserved registers that are not
185   /// allocatable. Register allocators should also make sure to allocate
186   /// callee-saved registers only after all the volatiles are used. The
187   /// RegisterClassInfo class provides filtered allocation orders with
188   /// callee-saved registers moved to the end.
189   ///
190   /// The MachineFunction argument can be used to tune the allocatable
191   /// registers based on the characteristics of the function, subtarget, or
192   /// other criteria.
193   ///
194   /// By default, this method returns all registers in the class.
195   ///
getRawAllocationOrder(const MachineFunction & MF)196   ArrayRef<MCPhysReg> getRawAllocationOrder(const MachineFunction &MF) const {
197     return OrderFunc ? OrderFunc(MF) : makeArrayRef(begin(), getNumRegs());
198   }
199 
200   /// Returns the combination of all lane masks of register in this class.
201   /// The lane masks of the registers are the combination of all lane masks
202   /// of their subregisters.
getLaneMask()203   unsigned getLaneMask() const {
204     return LaneMask;
205   }
206 };
207 
208 /// TargetRegisterInfoDesc - Extra information, not in MCRegisterDesc, about
209 /// registers. These are used by codegen, not by MC.
210 struct TargetRegisterInfoDesc {
211   unsigned CostPerUse;          // Extra cost of instructions using register.
212   bool inAllocatableClass;      // Register belongs to an allocatable regclass.
213 };
214 
215 /// Each TargetRegisterClass has a per register weight, and weight
216 /// limit which must be less than the limits of its pressure sets.
217 struct RegClassWeight {
218   unsigned RegWeight;
219   unsigned WeightLimit;
220 };
221 
222 /// TargetRegisterInfo base class - We assume that the target defines a static
223 /// array of TargetRegisterDesc objects that represent all of the machine
224 /// registers that the target has.  As such, we simply have to track a pointer
225 /// to this array so that we can turn register number into a register
226 /// descriptor.
227 ///
228 class TargetRegisterInfo : public MCRegisterInfo {
229 public:
230   typedef const TargetRegisterClass * const * regclass_iterator;
231 private:
232   const TargetRegisterInfoDesc *InfoDesc;     // Extra desc array for codegen
233   const char *const *SubRegIndexNames;        // Names of subreg indexes.
234   // Pointer to array of lane masks, one per sub-reg index.
235   const unsigned *SubRegIndexLaneMasks;
236 
237   regclass_iterator RegClassBegin, RegClassEnd;   // List of regclasses
238   unsigned CoveringLanes;
239 
240 protected:
241   TargetRegisterInfo(const TargetRegisterInfoDesc *ID,
242                      regclass_iterator RegClassBegin,
243                      regclass_iterator RegClassEnd,
244                      const char *const *SRINames,
245                      const unsigned *SRILaneMasks,
246                      unsigned CoveringLanes);
247   virtual ~TargetRegisterInfo();
248 public:
249 
250   // Register numbers can represent physical registers, virtual registers, and
251   // sometimes stack slots. The unsigned values are divided into these ranges:
252   //
253   //   0           Not a register, can be used as a sentinel.
254   //   [1;2^30)    Physical registers assigned by TableGen.
255   //   [2^30;2^31) Stack slots. (Rarely used.)
256   //   [2^31;2^32) Virtual registers assigned by MachineRegisterInfo.
257   //
258   // Further sentinels can be allocated from the small negative integers.
259   // DenseMapInfo<unsigned> uses -1u and -2u.
260 
261   /// isStackSlot - Sometimes it is useful the be able to store a non-negative
262   /// frame index in a variable that normally holds a register. isStackSlot()
263   /// returns true if Reg is in the range used for stack slots.
264   ///
265   /// Note that isVirtualRegister() and isPhysicalRegister() cannot handle stack
266   /// slots, so if a variable may contains a stack slot, always check
267   /// isStackSlot() first.
268   ///
isStackSlot(unsigned Reg)269   static bool isStackSlot(unsigned Reg) {
270     return int(Reg) >= (1 << 30);
271   }
272 
273   /// stackSlot2Index - Compute the frame index from a register value
274   /// representing a stack slot.
stackSlot2Index(unsigned Reg)275   static int stackSlot2Index(unsigned Reg) {
276     assert(isStackSlot(Reg) && "Not a stack slot");
277     return int(Reg - (1u << 30));
278   }
279 
280   /// index2StackSlot - Convert a non-negative frame index to a stack slot
281   /// register value.
index2StackSlot(int FI)282   static unsigned index2StackSlot(int FI) {
283     assert(FI >= 0 && "Cannot hold a negative frame index.");
284     return FI + (1u << 30);
285   }
286 
287   /// isPhysicalRegister - Return true if the specified register number is in
288   /// the physical register namespace.
isPhysicalRegister(unsigned Reg)289   static bool isPhysicalRegister(unsigned Reg) {
290     assert(!isStackSlot(Reg) && "Not a register! Check isStackSlot() first.");
291     return int(Reg) > 0;
292   }
293 
294   /// isVirtualRegister - Return true if the specified register number is in
295   /// the virtual register namespace.
isVirtualRegister(unsigned Reg)296   static bool isVirtualRegister(unsigned Reg) {
297     assert(!isStackSlot(Reg) && "Not a register! Check isStackSlot() first.");
298     return int(Reg) < 0;
299   }
300 
301   /// virtReg2Index - Convert a virtual register number to a 0-based index.
302   /// The first virtual register in a function will get the index 0.
virtReg2Index(unsigned Reg)303   static unsigned virtReg2Index(unsigned Reg) {
304     assert(isVirtualRegister(Reg) && "Not a virtual register");
305     return Reg & ~(1u << 31);
306   }
307 
308   /// index2VirtReg - Convert a 0-based index to a virtual register number.
309   /// This is the inverse operation of VirtReg2IndexFunctor below.
index2VirtReg(unsigned Index)310   static unsigned index2VirtReg(unsigned Index) {
311     return Index | (1u << 31);
312   }
313 
314   /// getMinimalPhysRegClass - Returns the Register Class of a physical
315   /// register of the given type, picking the most sub register class of
316   /// the right type that contains this physreg.
317   const TargetRegisterClass *
318     getMinimalPhysRegClass(unsigned Reg, MVT VT = MVT::Other) const;
319 
320   /// getAllocatableClass - Return the maximal subclass of the given register
321   /// class that is alloctable, or NULL.
322   const TargetRegisterClass *
323     getAllocatableClass(const TargetRegisterClass *RC) const;
324 
325   /// getAllocatableSet - Returns a bitset indexed by register number
326   /// indicating if a register is allocatable or not. If a register class is
327   /// specified, returns the subset for the class.
328   BitVector getAllocatableSet(const MachineFunction &MF,
329                               const TargetRegisterClass *RC = nullptr) const;
330 
331   /// getCostPerUse - Return the additional cost of using this register instead
332   /// of other registers in its class.
getCostPerUse(unsigned RegNo)333   unsigned getCostPerUse(unsigned RegNo) const {
334     return InfoDesc[RegNo].CostPerUse;
335   }
336 
337   /// isInAllocatableClass - Return true if the register is in the allocation
338   /// of any register class.
isInAllocatableClass(unsigned RegNo)339   bool isInAllocatableClass(unsigned RegNo) const {
340     return InfoDesc[RegNo].inAllocatableClass;
341   }
342 
343   /// getSubRegIndexName - Return the human-readable symbolic target-specific
344   /// name for the specified SubRegIndex.
getSubRegIndexName(unsigned SubIdx)345   const char *getSubRegIndexName(unsigned SubIdx) const {
346     assert(SubIdx && SubIdx < getNumSubRegIndices() &&
347            "This is not a subregister index");
348     return SubRegIndexNames[SubIdx-1];
349   }
350 
351   /// getSubRegIndexLaneMask - Return a bitmask representing the parts of a
352   /// register that are covered by SubIdx.
353   ///
354   /// Lane masks for sub-register indices are similar to register units for
355   /// physical registers. The individual bits in a lane mask can't be assigned
356   /// any specific meaning. They can be used to check if two sub-register
357   /// indices overlap.
358   ///
359   /// If the target has a register such that:
360   ///
361   ///   getSubReg(Reg, A) overlaps getSubReg(Reg, B)
362   ///
363   /// then:
364   ///
365   ///   (getSubRegIndexLaneMask(A) & getSubRegIndexLaneMask(B)) != 0
366   ///
367   /// The converse is not necessarily true. If two lane masks have a common
368   /// bit, the corresponding sub-registers may not overlap, but it can be
369   /// assumed that they usually will.
370   /// SubIdx == 0 is allowed, it has the lane mask ~0u.
getSubRegIndexLaneMask(unsigned SubIdx)371   unsigned getSubRegIndexLaneMask(unsigned SubIdx) const {
372     assert(SubIdx < getNumSubRegIndices() && "This is not a subregister index");
373     return SubRegIndexLaneMasks[SubIdx];
374   }
375 
376   /// The lane masks returned by getSubRegIndexLaneMask() above can only be
377   /// used to determine if sub-registers overlap - they can't be used to
378   /// determine if a set of sub-registers completely cover another
379   /// sub-register.
380   ///
381   /// The X86 general purpose registers have two lanes corresponding to the
382   /// sub_8bit and sub_8bit_hi sub-registers. Both sub_32bit and sub_16bit have
383   /// lane masks '3', but the sub_16bit sub-register doesn't fully cover the
384   /// sub_32bit sub-register.
385   ///
386   /// On the other hand, the ARM NEON lanes fully cover their registers: The
387   /// dsub_0 sub-register is completely covered by the ssub_0 and ssub_1 lanes.
388   /// This is related to the CoveredBySubRegs property on register definitions.
389   ///
390   /// This function returns a bit mask of lanes that completely cover their
391   /// sub-registers. More precisely, given:
392   ///
393   ///   Covering = getCoveringLanes();
394   ///   MaskA = getSubRegIndexLaneMask(SubA);
395   ///   MaskB = getSubRegIndexLaneMask(SubB);
396   ///
397   /// If (MaskA & ~(MaskB & Covering)) == 0, then SubA is completely covered by
398   /// SubB.
getCoveringLanes()399   unsigned getCoveringLanes() const { return CoveringLanes; }
400 
401   /// regsOverlap - Returns true if the two registers are equal or alias each
402   /// other. The registers may be virtual register.
regsOverlap(unsigned regA,unsigned regB)403   bool regsOverlap(unsigned regA, unsigned regB) const {
404     if (regA == regB) return true;
405     if (isVirtualRegister(regA) || isVirtualRegister(regB))
406       return false;
407 
408     // Regunits are numerically ordered. Find a common unit.
409     MCRegUnitIterator RUA(regA, this);
410     MCRegUnitIterator RUB(regB, this);
411     do {
412       if (*RUA == *RUB) return true;
413       if (*RUA < *RUB) ++RUA;
414       else             ++RUB;
415     } while (RUA.isValid() && RUB.isValid());
416     return false;
417   }
418 
419   /// hasRegUnit - Returns true if Reg contains RegUnit.
hasRegUnit(unsigned Reg,unsigned RegUnit)420   bool hasRegUnit(unsigned Reg, unsigned RegUnit) const {
421     for (MCRegUnitIterator Units(Reg, this); Units.isValid(); ++Units)
422       if (*Units == RegUnit)
423         return true;
424     return false;
425   }
426 
427   /// getCalleeSavedRegs - Return a null-terminated list of all of the
428   /// callee saved registers on this target. The register should be in the
429   /// order of desired callee-save stack frame offset. The first register is
430   /// closest to the incoming stack pointer if stack grows down, and vice versa.
431   ///
432   virtual const MCPhysReg*
433   getCalleeSavedRegs(const MachineFunction *MF) const = 0;
434 
435   /// getCallPreservedMask - Return a mask of call-preserved registers for the
436   /// given calling convention on the current function.  The mask should
437   /// include all call-preserved aliases.  This is used by the register
438   /// allocator to determine which registers can be live across a call.
439   ///
440   /// The mask is an array containing (TRI::getNumRegs()+31)/32 entries.
441   /// A set bit indicates that all bits of the corresponding register are
442   /// preserved across the function call.  The bit mask is expected to be
443   /// sub-register complete, i.e. if A is preserved, so are all its
444   /// sub-registers.
445   ///
446   /// Bits are numbered from the LSB, so the bit for physical register Reg can
447   /// be found as (Mask[Reg / 32] >> Reg % 32) & 1.
448   ///
449   /// A NULL pointer means that no register mask will be used, and call
450   /// instructions should use implicit-def operands to indicate call clobbered
451   /// registers.
452   ///
getCallPreservedMask(const MachineFunction & MF,CallingConv::ID)453   virtual const uint32_t *getCallPreservedMask(const MachineFunction &MF,
454                                                CallingConv::ID) const {
455     // The default mask clobbers everything.  All targets should override.
456     return nullptr;
457   }
458 
459   /// getReservedRegs - Returns a bitset indexed by physical register number
460   /// indicating if a register is a special register that has particular uses
461   /// and should be considered unavailable at all times, e.g. SP, RA. This is
462   /// used by register scavenger to determine what registers are free.
463   virtual BitVector getReservedRegs(const MachineFunction &MF) const = 0;
464 
465   /// Prior to adding the live-out mask to a stackmap or patchpoint
466   /// instruction, provide the target the opportunity to adjust it (mainly to
467   /// remove pseudo-registers that should be ignored).
adjustStackMapLiveOutMask(uint32_t * Mask)468   virtual void adjustStackMapLiveOutMask(uint32_t *Mask) const { }
469 
470   /// getMatchingSuperReg - Return a super-register of the specified register
471   /// Reg so its sub-register of index SubIdx is Reg.
getMatchingSuperReg(unsigned Reg,unsigned SubIdx,const TargetRegisterClass * RC)472   unsigned getMatchingSuperReg(unsigned Reg, unsigned SubIdx,
473                                const TargetRegisterClass *RC) const {
474     return MCRegisterInfo::getMatchingSuperReg(Reg, SubIdx, RC->MC);
475   }
476 
477   /// getMatchingSuperRegClass - Return a subclass of the specified register
478   /// class A so that each register in it has a sub-register of the
479   /// specified sub-register index which is in the specified register class B.
480   ///
481   /// TableGen will synthesize missing A sub-classes.
482   virtual const TargetRegisterClass *
483   getMatchingSuperRegClass(const TargetRegisterClass *A,
484                            const TargetRegisterClass *B, unsigned Idx) const;
485 
486   /// getSubClassWithSubReg - Returns the largest legal sub-class of RC that
487   /// supports the sub-register index Idx.
488   /// If no such sub-class exists, return NULL.
489   /// If all registers in RC already have an Idx sub-register, return RC.
490   ///
491   /// TableGen generates a version of this function that is good enough in most
492   /// cases.  Targets can override if they have constraints that TableGen
493   /// doesn't understand.  For example, the x86 sub_8bit sub-register index is
494   /// supported by the full GR32 register class in 64-bit mode, but only by the
495   /// GR32_ABCD regiister class in 32-bit mode.
496   ///
497   /// TableGen will synthesize missing RC sub-classes.
498   virtual const TargetRegisterClass *
getSubClassWithSubReg(const TargetRegisterClass * RC,unsigned Idx)499   getSubClassWithSubReg(const TargetRegisterClass *RC, unsigned Idx) const {
500     assert(Idx == 0 && "Target has no sub-registers");
501     return RC;
502   }
503 
504   /// composeSubRegIndices - Return the subregister index you get from composing
505   /// two subregister indices.
506   ///
507   /// The special null sub-register index composes as the identity.
508   ///
509   /// If R:a:b is the same register as R:c, then composeSubRegIndices(a, b)
510   /// returns c. Note that composeSubRegIndices does not tell you about illegal
511   /// compositions. If R does not have a subreg a, or R:a does not have a subreg
512   /// b, composeSubRegIndices doesn't tell you.
513   ///
514   /// The ARM register Q0 has two D subregs dsub_0:D0 and dsub_1:D1. It also has
515   /// ssub_0:S0 - ssub_3:S3 subregs.
516   /// If you compose subreg indices dsub_1, ssub_0 you get ssub_2.
517   ///
composeSubRegIndices(unsigned a,unsigned b)518   unsigned composeSubRegIndices(unsigned a, unsigned b) const {
519     if (!a) return b;
520     if (!b) return a;
521     return composeSubRegIndicesImpl(a, b);
522   }
523 
524   /// Transforms a LaneMask computed for one subregister to the lanemask that
525   /// would have been computed when composing the subsubregisters with IdxA
526   /// first. @sa composeSubRegIndices()
composeSubRegIndexLaneMask(unsigned IdxA,unsigned LaneMask)527   unsigned composeSubRegIndexLaneMask(unsigned IdxA, unsigned LaneMask) const {
528     if (!IdxA)
529       return LaneMask;
530     return composeSubRegIndexLaneMaskImpl(IdxA, LaneMask);
531   }
532 
533   /// Debugging helper: dump register in human readable form to dbgs() stream.
534   static void dumpReg(unsigned Reg, unsigned SubRegIndex = 0,
535                       const TargetRegisterInfo* TRI = nullptr);
536 
537 protected:
538   /// Overridden by TableGen in targets that have sub-registers.
composeSubRegIndicesImpl(unsigned,unsigned)539   virtual unsigned composeSubRegIndicesImpl(unsigned, unsigned) const {
540     llvm_unreachable("Target has no sub-registers");
541   }
542 
543   /// Overridden by TableGen in targets that have sub-registers.
544   virtual unsigned
composeSubRegIndexLaneMaskImpl(unsigned,unsigned)545   composeSubRegIndexLaneMaskImpl(unsigned, unsigned) const {
546     llvm_unreachable("Target has no sub-registers");
547   }
548 
549 public:
550   /// getCommonSuperRegClass - Find a common super-register class if it exists.
551   ///
552   /// Find a register class, SuperRC and two sub-register indices, PreA and
553   /// PreB, such that:
554   ///
555   ///   1. PreA + SubA == PreB + SubB  (using composeSubRegIndices()), and
556   ///
557   ///   2. For all Reg in SuperRC: Reg:PreA in RCA and Reg:PreB in RCB, and
558   ///
559   ///   3. SuperRC->getSize() >= max(RCA->getSize(), RCB->getSize()).
560   ///
561   /// SuperRC will be chosen such that no super-class of SuperRC satisfies the
562   /// requirements, and there is no register class with a smaller spill size
563   /// that satisfies the requirements.
564   ///
565   /// SubA and SubB must not be 0. Use getMatchingSuperRegClass() instead.
566   ///
567   /// Either of the PreA and PreB sub-register indices may be returned as 0. In
568   /// that case, the returned register class will be a sub-class of the
569   /// corresponding argument register class.
570   ///
571   /// The function returns NULL if no register class can be found.
572   ///
573   const TargetRegisterClass*
574   getCommonSuperRegClass(const TargetRegisterClass *RCA, unsigned SubA,
575                          const TargetRegisterClass *RCB, unsigned SubB,
576                          unsigned &PreA, unsigned &PreB) const;
577 
578   //===--------------------------------------------------------------------===//
579   // Register Class Information
580   //
581 
582   /// Register class iterators
583   ///
regclass_begin()584   regclass_iterator regclass_begin() const { return RegClassBegin; }
regclass_end()585   regclass_iterator regclass_end() const { return RegClassEnd; }
586 
getNumRegClasses()587   unsigned getNumRegClasses() const {
588     return (unsigned)(regclass_end()-regclass_begin());
589   }
590 
591   /// getRegClass - Returns the register class associated with the enumeration
592   /// value.  See class MCOperandInfo.
getRegClass(unsigned i)593   const TargetRegisterClass *getRegClass(unsigned i) const {
594     assert(i < getNumRegClasses() && "Register Class ID out of range");
595     return RegClassBegin[i];
596   }
597 
598   /// getRegClassName - Returns the name of the register class.
getRegClassName(const TargetRegisterClass * Class)599   const char *getRegClassName(const TargetRegisterClass *Class) const {
600     return MCRegisterInfo::getRegClassName(Class->MC);
601   }
602 
603   /// getCommonSubClass - find the largest common subclass of A and B. Return
604   /// NULL if there is no common subclass.
605   const TargetRegisterClass *
606   getCommonSubClass(const TargetRegisterClass *A,
607                     const TargetRegisterClass *B) const;
608 
609   /// getPointerRegClass - Returns a TargetRegisterClass used for pointer
610   /// values.  If a target supports multiple different pointer register classes,
611   /// kind specifies which one is indicated.
612   virtual const TargetRegisterClass *
613   getPointerRegClass(const MachineFunction &MF, unsigned Kind=0) const {
614     llvm_unreachable("Target didn't implement getPointerRegClass!");
615   }
616 
617   /// getCrossCopyRegClass - Returns a legal register class to copy a register
618   /// in the specified class to or from. If it is possible to copy the register
619   /// directly without using a cross register class copy, return the specified
620   /// RC. Returns NULL if it is not possible to copy between a two registers of
621   /// the specified class.
622   virtual const TargetRegisterClass *
getCrossCopyRegClass(const TargetRegisterClass * RC)623   getCrossCopyRegClass(const TargetRegisterClass *RC) const {
624     return RC;
625   }
626 
627   /// getLargestLegalSuperClass - Returns the largest super class of RC that is
628   /// legal to use in the current sub-target and has the same spill size.
629   /// The returned register class can be used to create virtual registers which
630   /// means that all its registers can be copied and spilled.
631   virtual const TargetRegisterClass *
getLargestLegalSuperClass(const TargetRegisterClass * RC,const MachineFunction &)632   getLargestLegalSuperClass(const TargetRegisterClass *RC,
633                             const MachineFunction &) const {
634     /// The default implementation is very conservative and doesn't allow the
635     /// register allocator to inflate register classes.
636     return RC;
637   }
638 
639   /// getRegPressureLimit - Return the register pressure "high water mark" for
640   /// the specific register class. The scheduler is in high register pressure
641   /// mode (for the specific register class) if it goes over the limit.
642   ///
643   /// Note: this is the old register pressure model that relies on a manually
644   /// specified representative register class per value type.
getRegPressureLimit(const TargetRegisterClass * RC,MachineFunction & MF)645   virtual unsigned getRegPressureLimit(const TargetRegisterClass *RC,
646                                        MachineFunction &MF) const {
647     return 0;
648   }
649 
650   /// Get the weight in units of pressure for this register class.
651   virtual const RegClassWeight &getRegClassWeight(
652     const TargetRegisterClass *RC) const = 0;
653 
654   /// Get the weight in units of pressure for this register unit.
655   virtual unsigned getRegUnitWeight(unsigned RegUnit) const = 0;
656 
657   /// Get the number of dimensions of register pressure.
658   virtual unsigned getNumRegPressureSets() const = 0;
659 
660   /// Get the name of this register unit pressure set.
661   virtual const char *getRegPressureSetName(unsigned Idx) const = 0;
662 
663   /// Get the register unit pressure limit for this dimension.
664   /// This limit must be adjusted dynamically for reserved registers.
665   virtual unsigned getRegPressureSetLimit(const MachineFunction &MF,
666                                           unsigned Idx) const = 0;
667 
668   /// Get the dimensions of register pressure impacted by this register class.
669   /// Returns a -1 terminated array of pressure set IDs.
670   virtual const int *getRegClassPressureSets(
671     const TargetRegisterClass *RC) const = 0;
672 
673   /// Get the dimensions of register pressure impacted by this register unit.
674   /// Returns a -1 terminated array of pressure set IDs.
675   virtual const int *getRegUnitPressureSets(unsigned RegUnit) const = 0;
676 
677   /// Get a list of 'hint' registers that the register allocator should try
678   /// first when allocating a physical register for the virtual register
679   /// VirtReg. These registers are effectively moved to the front of the
680   /// allocation order.
681   ///
682   /// The Order argument is the allocation order for VirtReg's register class
683   /// as returned from RegisterClassInfo::getOrder(). The hint registers must
684   /// come from Order, and they must not be reserved.
685   ///
686   /// The default implementation of this function can resolve
687   /// target-independent hints provided to MRI::setRegAllocationHint with
688   /// HintType == 0. Targets that override this function should defer to the
689   /// default implementation if they have no reason to change the allocation
690   /// order for VirtReg. There may be target-independent hints.
691   virtual void getRegAllocationHints(unsigned VirtReg,
692                                      ArrayRef<MCPhysReg> Order,
693                                      SmallVectorImpl<MCPhysReg> &Hints,
694                                      const MachineFunction &MF,
695                                      const VirtRegMap *VRM = nullptr) const;
696 
697   /// updateRegAllocHint - A callback to allow target a chance to update
698   /// register allocation hints when a register is "changed" (e.g. coalesced)
699   /// to another register. e.g. On ARM, some virtual registers should target
700   /// register pairs, if one of pair is coalesced to another register, the
701   /// allocation hint of the other half of the pair should be changed to point
702   /// to the new register.
updateRegAllocHint(unsigned Reg,unsigned NewReg,MachineFunction & MF)703   virtual void updateRegAllocHint(unsigned Reg, unsigned NewReg,
704                                   MachineFunction &MF) const {
705     // Do nothing.
706   }
707 
708   /// Allow the target to reverse allocation order of local live ranges. This
709   /// will generally allocate shorter local live ranges first. For targets with
710   /// many registers, this could reduce regalloc compile time by a large
711   /// factor. It is disabled by default for three reasons:
712   /// (1) Top-down allocation is simpler and easier to debug for targets that
713   /// don't benefit from reversing the order.
714   /// (2) Bottom-up allocation could result in poor evicition decisions on some
715   /// targets affecting the performance of compiled code.
716   /// (3) Bottom-up allocation is no longer guaranteed to optimally color.
reverseLocalAssignment()717   virtual bool reverseLocalAssignment() const { return false; }
718 
719   /// Allow the target to override the cost of using a callee-saved register for
720   /// the first time. Default value of 0 means we will use a callee-saved
721   /// register if it is available.
getCSRFirstUseCost()722   virtual unsigned getCSRFirstUseCost() const { return 0; }
723 
724   /// requiresRegisterScavenging - returns true if the target requires (and can
725   /// make use of) the register scavenger.
requiresRegisterScavenging(const MachineFunction & MF)726   virtual bool requiresRegisterScavenging(const MachineFunction &MF) const {
727     return false;
728   }
729 
730   /// useFPForScavengingIndex - returns true if the target wants to use
731   /// frame pointer based accesses to spill to the scavenger emergency spill
732   /// slot.
useFPForScavengingIndex(const MachineFunction & MF)733   virtual bool useFPForScavengingIndex(const MachineFunction &MF) const {
734     return true;
735   }
736 
737   /// requiresFrameIndexScavenging - returns true if the target requires post
738   /// PEI scavenging of registers for materializing frame index constants.
requiresFrameIndexScavenging(const MachineFunction & MF)739   virtual bool requiresFrameIndexScavenging(const MachineFunction &MF) const {
740     return false;
741   }
742 
743   /// requiresVirtualBaseRegisters - Returns true if the target wants the
744   /// LocalStackAllocation pass to be run and virtual base registers
745   /// used for more efficient stack access.
requiresVirtualBaseRegisters(const MachineFunction & MF)746   virtual bool requiresVirtualBaseRegisters(const MachineFunction &MF) const {
747     return false;
748   }
749 
750   /// hasReservedSpillSlot - Return true if target has reserved a spill slot in
751   /// the stack frame of the given function for the specified register. e.g. On
752   /// x86, if the frame register is required, the first fixed stack object is
753   /// reserved as its spill slot. This tells PEI not to create a new stack frame
754   /// object for the given register. It should be called only after
755   /// processFunctionBeforeCalleeSavedScan().
hasReservedSpillSlot(const MachineFunction & MF,unsigned Reg,int & FrameIdx)756   virtual bool hasReservedSpillSlot(const MachineFunction &MF, unsigned Reg,
757                                     int &FrameIdx) const {
758     return false;
759   }
760 
761   /// trackLivenessAfterRegAlloc - returns true if the live-ins should be tracked
762   /// after register allocation.
trackLivenessAfterRegAlloc(const MachineFunction & MF)763   virtual bool trackLivenessAfterRegAlloc(const MachineFunction &MF) const {
764     return false;
765   }
766 
767   /// needsStackRealignment - true if storage within the function requires the
768   /// stack pointer to be aligned more than the normal calling convention calls
769   /// for.
needsStackRealignment(const MachineFunction & MF)770   virtual bool needsStackRealignment(const MachineFunction &MF) const {
771     return false;
772   }
773 
774   /// getFrameIndexInstrOffset - Get the offset from the referenced frame
775   /// index in the instruction, if there is one.
getFrameIndexInstrOffset(const MachineInstr * MI,int Idx)776   virtual int64_t getFrameIndexInstrOffset(const MachineInstr *MI,
777                                            int Idx) const {
778     return 0;
779   }
780 
781   /// needsFrameBaseReg - Returns true if the instruction's frame index
782   /// reference would be better served by a base register other than FP
783   /// or SP. Used by LocalStackFrameAllocation to determine which frame index
784   /// references it should create new base registers for.
needsFrameBaseReg(MachineInstr * MI,int64_t Offset)785   virtual bool needsFrameBaseReg(MachineInstr *MI, int64_t Offset) const {
786     return false;
787   }
788 
789   /// materializeFrameBaseRegister - Insert defining instruction(s) for
790   /// BaseReg to be a pointer to FrameIdx before insertion point I.
materializeFrameBaseRegister(MachineBasicBlock * MBB,unsigned BaseReg,int FrameIdx,int64_t Offset)791   virtual void materializeFrameBaseRegister(MachineBasicBlock *MBB,
792                                             unsigned BaseReg, int FrameIdx,
793                                             int64_t Offset) const {
794     llvm_unreachable("materializeFrameBaseRegister does not exist on this "
795                      "target");
796   }
797 
798   /// resolveFrameIndex - Resolve a frame index operand of an instruction
799   /// to reference the indicated base register plus offset instead.
resolveFrameIndex(MachineInstr & MI,unsigned BaseReg,int64_t Offset)800   virtual void resolveFrameIndex(MachineInstr &MI, unsigned BaseReg,
801                                  int64_t Offset) const {
802     llvm_unreachable("resolveFrameIndex does not exist on this target");
803   }
804 
805   /// isFrameOffsetLegal - Determine whether a given base register plus offset
806   /// immediate is encodable to resolve a frame index.
isFrameOffsetLegal(const MachineInstr * MI,unsigned BaseReg,int64_t Offset)807   virtual bool isFrameOffsetLegal(const MachineInstr *MI, unsigned BaseReg,
808                                   int64_t Offset) const {
809     llvm_unreachable("isFrameOffsetLegal does not exist on this target");
810   }
811 
812 
813   /// saveScavengerRegister - Spill the register so it can be used by the
814   /// register scavenger. Return true if the register was spilled, false
815   /// otherwise. If this function does not spill the register, the scavenger
816   /// will instead spill it to the emergency spill slot.
817   ///
saveScavengerRegister(MachineBasicBlock & MBB,MachineBasicBlock::iterator I,MachineBasicBlock::iterator & UseMI,const TargetRegisterClass * RC,unsigned Reg)818   virtual bool saveScavengerRegister(MachineBasicBlock &MBB,
819                                      MachineBasicBlock::iterator I,
820                                      MachineBasicBlock::iterator &UseMI,
821                                      const TargetRegisterClass *RC,
822                                      unsigned Reg) const {
823     return false;
824   }
825 
826   /// eliminateFrameIndex - This method must be overriden to eliminate abstract
827   /// frame indices from instructions which may use them.  The instruction
828   /// referenced by the iterator contains an MO_FrameIndex operand which must be
829   /// eliminated by this method.  This method may modify or replace the
830   /// specified instruction, as long as it keeps the iterator pointing at the
831   /// finished product.  SPAdj is the SP adjustment due to call frame setup
832   /// instruction.  FIOperandNum is the FI operand number.
833   virtual void eliminateFrameIndex(MachineBasicBlock::iterator MI,
834                                    int SPAdj, unsigned FIOperandNum,
835                                    RegScavenger *RS = nullptr) const = 0;
836 
837   //===--------------------------------------------------------------------===//
838   /// Subtarget Hooks
839 
840   /// \brief SrcRC and DstRC will be morphed into NewRC if this returns true.
shouldCoalesce(MachineInstr * MI,const TargetRegisterClass * SrcRC,unsigned SubReg,const TargetRegisterClass * DstRC,unsigned DstSubReg,const TargetRegisterClass * NewRC)841   virtual bool shouldCoalesce(MachineInstr *MI,
842                               const TargetRegisterClass *SrcRC,
843                               unsigned SubReg,
844                               const TargetRegisterClass *DstRC,
845                               unsigned DstSubReg,
846                               const TargetRegisterClass *NewRC) const
847   { return true; }
848 
849   //===--------------------------------------------------------------------===//
850   /// Debug information queries.
851 
852   /// getFrameRegister - This method should return the register used as a base
853   /// for values allocated in the current stack frame.
854   virtual unsigned getFrameRegister(const MachineFunction &MF) const = 0;
855 };
856 
857 
858 //===----------------------------------------------------------------------===//
859 //                           SuperRegClassIterator
860 //===----------------------------------------------------------------------===//
861 //
862 // Iterate over the possible super-registers for a given register class. The
863 // iterator will visit a list of pairs (Idx, Mask) corresponding to the
864 // possible classes of super-registers.
865 //
866 // Each bit mask will have at least one set bit, and each set bit in Mask
867 // corresponds to a SuperRC such that:
868 //
869 //   For all Reg in SuperRC: Reg:Idx is in RC.
870 //
871 // The iterator can include (O, RC->getSubClassMask()) as the first entry which
872 // also satisfies the above requirement, assuming Reg:0 == Reg.
873 //
874 class SuperRegClassIterator {
875   const unsigned RCMaskWords;
876   unsigned SubReg;
877   const uint16_t *Idx;
878   const uint32_t *Mask;
879 
880 public:
881   /// Create a SuperRegClassIterator that visits all the super-register classes
882   /// of RC. When IncludeSelf is set, also include the (0, sub-classes) entry.
883   SuperRegClassIterator(const TargetRegisterClass *RC,
884                         const TargetRegisterInfo *TRI,
885                         bool IncludeSelf = false)
886     : RCMaskWords((TRI->getNumRegClasses() + 31) / 32),
887       SubReg(0),
888       Idx(RC->getSuperRegIndices()),
889       Mask(RC->getSubClassMask()) {
890     if (!IncludeSelf)
891       ++*this;
892   }
893 
894   /// Returns true if this iterator is still pointing at a valid entry.
isValid()895   bool isValid() const { return Idx; }
896 
897   /// Returns the current sub-register index.
getSubReg()898   unsigned getSubReg() const { return SubReg; }
899 
900   /// Returns the bit mask if register classes that getSubReg() projects into
901   /// RC.
getMask()902   const uint32_t *getMask() const { return Mask; }
903 
904   /// Advance iterator to the next entry.
905   void operator++() {
906     assert(isValid() && "Cannot move iterator past end.");
907     Mask += RCMaskWords;
908     SubReg = *Idx++;
909     if (!SubReg)
910       Idx = nullptr;
911   }
912 };
913 
914 // This is useful when building IndexedMaps keyed on virtual registers
915 struct VirtReg2IndexFunctor : public std::unary_function<unsigned, unsigned> {
operatorVirtReg2IndexFunctor916   unsigned operator()(unsigned Reg) const {
917     return TargetRegisterInfo::virtReg2Index(Reg);
918   }
919 };
920 
921 /// PrintReg - Helper class for printing registers on a raw_ostream.
922 /// Prints virtual and physical registers with or without a TRI instance.
923 ///
924 /// The format is:
925 ///   %noreg          - NoRegister
926 ///   %vreg5          - a virtual register.
927 ///   %vreg5:sub_8bit - a virtual register with sub-register index (with TRI).
928 ///   %EAX            - a physical register
929 ///   %physreg17      - a physical register when no TRI instance given.
930 ///
931 /// Usage: OS << PrintReg(Reg, TRI) << '\n';
932 ///
933 class PrintReg {
934   const TargetRegisterInfo *TRI;
935   unsigned Reg;
936   unsigned SubIdx;
937 public:
938   explicit PrintReg(unsigned reg, const TargetRegisterInfo *tri = nullptr,
939                     unsigned subidx = 0)
TRI(tri)940     : TRI(tri), Reg(reg), SubIdx(subidx) {}
941   void print(raw_ostream&) const;
942 };
943 
944 static inline raw_ostream &operator<<(raw_ostream &OS, const PrintReg &PR) {
945   PR.print(OS);
946   return OS;
947 }
948 
949 /// PrintRegUnit - Helper class for printing register units on a raw_ostream.
950 ///
951 /// Register units are named after their root registers:
952 ///
953 ///   AL      - Single root.
954 ///   FP0~ST7 - Dual roots.
955 ///
956 /// Usage: OS << PrintRegUnit(Unit, TRI) << '\n';
957 ///
958 class PrintRegUnit {
959 protected:
960   const TargetRegisterInfo *TRI;
961   unsigned Unit;
962 public:
PrintRegUnit(unsigned unit,const TargetRegisterInfo * tri)963   PrintRegUnit(unsigned unit, const TargetRegisterInfo *tri)
964     : TRI(tri), Unit(unit) {}
965   void print(raw_ostream&) const;
966 };
967 
968 static inline raw_ostream &operator<<(raw_ostream &OS, const PrintRegUnit &PR) {
969   PR.print(OS);
970   return OS;
971 }
972 
973 /// PrintVRegOrUnit - It is often convenient to track virtual registers and
974 /// physical register units in the same list.
975 class PrintVRegOrUnit : protected PrintRegUnit {
976 public:
PrintVRegOrUnit(unsigned VRegOrUnit,const TargetRegisterInfo * tri)977   PrintVRegOrUnit(unsigned VRegOrUnit, const TargetRegisterInfo *tri)
978     : PrintRegUnit(VRegOrUnit, tri) {}
979   void print(raw_ostream&) const;
980 };
981 
982 static inline raw_ostream &operator<<(raw_ostream &OS,
983                                       const PrintVRegOrUnit &PR) {
984   PR.print(OS);
985   return OS;
986 }
987 
988 } // End llvm namespace
989 
990 #endif
991