1 //===--- TargetInfo.h - Expose information about the target -----*- 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 /// \file
11 /// \brief Defines the clang::TargetInfo interface.
12 ///
13 //===----------------------------------------------------------------------===//
14 
15 #ifndef LLVM_CLANG_BASIC_TARGETINFO_H
16 #define LLVM_CLANG_BASIC_TARGETINFO_H
17 
18 #include "clang/Basic/AddressSpaces.h"
19 #include "clang/Basic/LLVM.h"
20 #include "clang/Basic/Specifiers.h"
21 #include "clang/Basic/TargetCXXABI.h"
22 #include "clang/Basic/TargetOptions.h"
23 #include "clang/Basic/VersionTuple.h"
24 #include "llvm/ADT/IntrusiveRefCntPtr.h"
25 #include "llvm/ADT/APInt.h"
26 #include "llvm/ADT/SmallSet.h"
27 #include "llvm/ADT/StringMap.h"
28 #include "llvm/ADT/StringRef.h"
29 #include "llvm/ADT/StringSwitch.h"
30 #include "llvm/ADT/Triple.h"
31 #include "llvm/Support/DataTypes.h"
32 #include <cassert>
33 #include <string>
34 #include <vector>
35 
36 namespace llvm {
37 struct fltSemantics;
38 }
39 
40 namespace clang {
41 class DiagnosticsEngine;
42 class LangOptions;
43 class MacroBuilder;
44 class SourceLocation;
45 class SourceManager;
46 
47 namespace Builtin { struct Info; }
48 
49 /// \brief Exposes information about the current target.
50 ///
51 class TargetInfo : public RefCountedBase<TargetInfo> {
52   std::shared_ptr<TargetOptions> TargetOpts;
53   llvm::Triple Triple;
54 protected:
55   // Target values set by the ctor of the actual target implementation.  Default
56   // values are specified by the TargetInfo constructor.
57   bool BigEndian;
58   bool TLSSupported;
59   bool NoAsmVariants;  // True if {|} are normal characters.
60   unsigned char PointerWidth, PointerAlign;
61   unsigned char BoolWidth, BoolAlign;
62   unsigned char IntWidth, IntAlign;
63   unsigned char HalfWidth, HalfAlign;
64   unsigned char FloatWidth, FloatAlign;
65   unsigned char DoubleWidth, DoubleAlign;
66   unsigned char LongDoubleWidth, LongDoubleAlign;
67   unsigned char LargeArrayMinWidth, LargeArrayAlign;
68   unsigned char LongWidth, LongAlign;
69   unsigned char LongLongWidth, LongLongAlign;
70   unsigned char SuitableAlign;
71   unsigned char DefaultAlignForAttributeAligned;
72   unsigned char MinGlobalAlign;
73   unsigned char MaxAtomicPromoteWidth, MaxAtomicInlineWidth;
74   unsigned short MaxVectorAlign;
75   unsigned short MaxTLSAlign;
76   unsigned short SimdDefaultAlign;
77   const char *DataLayoutString;
78   const char *UserLabelPrefix;
79   const char *MCountName;
80   const llvm::fltSemantics *HalfFormat, *FloatFormat, *DoubleFormat,
81     *LongDoubleFormat;
82   unsigned char RegParmMax, SSERegParmMax;
83   TargetCXXABI TheCXXABI;
84   const LangAS::Map *AddrSpaceMap;
85 
86   mutable StringRef PlatformName;
87   mutable VersionTuple PlatformMinVersion;
88 
89   unsigned HasAlignMac68kSupport : 1;
90   unsigned RealTypeUsesObjCFPRet : 3;
91   unsigned ComplexLongDoubleUsesFP2Ret : 1;
92 
93   unsigned HasBuiltinMSVaList : 1;
94 
95   // TargetInfo Constructor.  Default initializes all fields.
96   TargetInfo(const llvm::Triple &T);
97 
98 public:
99   /// \brief Construct a target for the given options.
100   ///
101   /// \param Opts - The options to use to initialize the target. The target may
102   /// modify the options to canonicalize the target feature information to match
103   /// what the backend expects.
104   static TargetInfo *
105   CreateTargetInfo(DiagnosticsEngine &Diags,
106                    const std::shared_ptr<TargetOptions> &Opts);
107 
108   virtual ~TargetInfo();
109 
110   /// \brief Retrieve the target options.
getTargetOpts()111   TargetOptions &getTargetOpts() const {
112     assert(TargetOpts && "Missing target options");
113     return *TargetOpts;
114   }
115 
116   ///===---- Target Data Type Query Methods -------------------------------===//
117   enum IntType {
118     NoInt = 0,
119     SignedChar,
120     UnsignedChar,
121     SignedShort,
122     UnsignedShort,
123     SignedInt,
124     UnsignedInt,
125     SignedLong,
126     UnsignedLong,
127     SignedLongLong,
128     UnsignedLongLong
129   };
130 
131   enum RealType {
132     NoFloat = 255,
133     Float = 0,
134     Double,
135     LongDouble
136   };
137 
138   /// \brief The different kinds of __builtin_va_list types defined by
139   /// the target implementation.
140   enum BuiltinVaListKind {
141     /// typedef char* __builtin_va_list;
142     CharPtrBuiltinVaList = 0,
143 
144     /// typedef void* __builtin_va_list;
145     VoidPtrBuiltinVaList,
146 
147     /// __builtin_va_list as defind by the AArch64 ABI
148     /// http://infocenter.arm.com/help/topic/com.arm.doc.ihi0055a/IHI0055A_aapcs64.pdf
149     AArch64ABIBuiltinVaList,
150 
151     /// __builtin_va_list as defined by the PNaCl ABI:
152     /// http://www.chromium.org/nativeclient/pnacl/bitcode-abi#TOC-Machine-Types
153     PNaClABIBuiltinVaList,
154 
155     /// __builtin_va_list as defined by the Power ABI:
156     /// https://www.power.org
157     ///        /resources/downloads/Power-Arch-32-bit-ABI-supp-1.0-Embedded.pdf
158     PowerABIBuiltinVaList,
159 
160     /// __builtin_va_list as defined by the x86-64 ABI:
161     /// http://www.x86-64.org/documentation/abi.pdf
162     X86_64ABIBuiltinVaList,
163 
164     /// __builtin_va_list as defined by ARM AAPCS ABI
165     /// http://infocenter.arm.com
166     //        /help/topic/com.arm.doc.ihi0042d/IHI0042D_aapcs.pdf
167     AAPCSABIBuiltinVaList,
168 
169     // typedef struct __va_list_tag
170     //   {
171     //     long __gpr;
172     //     long __fpr;
173     //     void *__overflow_arg_area;
174     //     void *__reg_save_area;
175     //   } va_list[1];
176     SystemZBuiltinVaList
177   };
178 
179 protected:
180   IntType SizeType, IntMaxType, PtrDiffType, IntPtrType, WCharType,
181           WIntType, Char16Type, Char32Type, Int64Type, SigAtomicType,
182           ProcessIDType;
183 
184   /// \brief Whether Objective-C's built-in boolean type should be signed char.
185   ///
186   /// Otherwise, when this flag is not set, the normal built-in boolean type is
187   /// used.
188   unsigned UseSignedCharForObjCBool : 1;
189 
190   /// Control whether the alignment of bit-field types is respected when laying
191   /// out structures. If true, then the alignment of the bit-field type will be
192   /// used to (a) impact the alignment of the containing structure, and (b)
193   /// ensure that the individual bit-field will not straddle an alignment
194   /// boundary.
195   unsigned UseBitFieldTypeAlignment : 1;
196 
197   /// \brief Whether zero length bitfields (e.g., int : 0;) force alignment of
198   /// the next bitfield.
199   ///
200   /// If the alignment of the zero length bitfield is greater than the member
201   /// that follows it, `bar', `bar' will be aligned as the type of the
202   /// zero-length bitfield.
203   unsigned UseZeroLengthBitfieldAlignment : 1;
204 
205   /// If non-zero, specifies a fixed alignment value for bitfields that follow
206   /// zero length bitfield, regardless of the zero length bitfield type.
207   unsigned ZeroLengthBitfieldBoundary;
208 
209   /// \brief Specify if mangling based on address space map should be used or
210   /// not for language specific address spaces
211   bool UseAddrSpaceMapMangling;
212 
213 public:
getSizeType()214   IntType getSizeType() const { return SizeType; }
getIntMaxType()215   IntType getIntMaxType() const { return IntMaxType; }
getUIntMaxType()216   IntType getUIntMaxType() const {
217     return getCorrespondingUnsignedType(IntMaxType);
218   }
getPtrDiffType(unsigned AddrSpace)219   IntType getPtrDiffType(unsigned AddrSpace) const {
220     return AddrSpace == 0 ? PtrDiffType : getPtrDiffTypeV(AddrSpace);
221   }
getIntPtrType()222   IntType getIntPtrType() const { return IntPtrType; }
getUIntPtrType()223   IntType getUIntPtrType() const {
224     return getCorrespondingUnsignedType(IntPtrType);
225   }
getWCharType()226   IntType getWCharType() const { return WCharType; }
getWIntType()227   IntType getWIntType() const { return WIntType; }
getChar16Type()228   IntType getChar16Type() const { return Char16Type; }
getChar32Type()229   IntType getChar32Type() const { return Char32Type; }
getInt64Type()230   IntType getInt64Type() const { return Int64Type; }
getUInt64Type()231   IntType getUInt64Type() const {
232     return getCorrespondingUnsignedType(Int64Type);
233   }
getSigAtomicType()234   IntType getSigAtomicType() const { return SigAtomicType; }
getProcessIDType()235   IntType getProcessIDType() const { return ProcessIDType; }
236 
getCorrespondingUnsignedType(IntType T)237   static IntType getCorrespondingUnsignedType(IntType T) {
238     switch (T) {
239     case SignedChar:
240       return UnsignedChar;
241     case SignedShort:
242       return UnsignedShort;
243     case SignedInt:
244       return UnsignedInt;
245     case SignedLong:
246       return UnsignedLong;
247     case SignedLongLong:
248       return UnsignedLongLong;
249     default:
250       llvm_unreachable("Unexpected signed integer type");
251     }
252   }
253 
254   /// \brief Return the width (in bits) of the specified integer type enum.
255   ///
256   /// For example, SignedInt -> getIntWidth().
257   unsigned getTypeWidth(IntType T) const;
258 
259   /// \brief Return integer type with specified width.
260   virtual IntType getIntTypeByWidth(unsigned BitWidth, bool IsSigned) const;
261 
262   /// \brief Return the smallest integer type with at least the specified width.
263   virtual IntType getLeastIntTypeByWidth(unsigned BitWidth,
264                                          bool IsSigned) const;
265 
266   /// \brief Return floating point type with specified width.
267   RealType getRealTypeByWidth(unsigned BitWidth) const;
268 
269   /// \brief Return the alignment (in bits) of the specified integer type enum.
270   ///
271   /// For example, SignedInt -> getIntAlign().
272   unsigned getTypeAlign(IntType T) const;
273 
274   /// \brief Returns true if the type is signed; false otherwise.
275   static bool isTypeSigned(IntType T);
276 
277   /// \brief Return the width of pointers on this target, for the
278   /// specified address space.
getPointerWidth(unsigned AddrSpace)279   uint64_t getPointerWidth(unsigned AddrSpace) const {
280     return AddrSpace == 0 ? PointerWidth : getPointerWidthV(AddrSpace);
281   }
getPointerAlign(unsigned AddrSpace)282   uint64_t getPointerAlign(unsigned AddrSpace) const {
283     return AddrSpace == 0 ? PointerAlign : getPointerAlignV(AddrSpace);
284   }
285 
286   /// \brief Return the size of '_Bool' and C++ 'bool' for this target, in bits.
getBoolWidth()287   unsigned getBoolWidth() const { return BoolWidth; }
288 
289   /// \brief Return the alignment of '_Bool' and C++ 'bool' for this target.
getBoolAlign()290   unsigned getBoolAlign() const { return BoolAlign; }
291 
getCharWidth()292   unsigned getCharWidth() const { return 8; } // FIXME
getCharAlign()293   unsigned getCharAlign() const { return 8; } // FIXME
294 
295   /// \brief Return the size of 'signed short' and 'unsigned short' for this
296   /// target, in bits.
getShortWidth()297   unsigned getShortWidth() const { return 16; } // FIXME
298 
299   /// \brief Return the alignment of 'signed short' and 'unsigned short' for
300   /// this target.
getShortAlign()301   unsigned getShortAlign() const { return 16; } // FIXME
302 
303   /// getIntWidth/Align - Return the size of 'signed int' and 'unsigned int' for
304   /// this target, in bits.
getIntWidth()305   unsigned getIntWidth() const { return IntWidth; }
getIntAlign()306   unsigned getIntAlign() const { return IntAlign; }
307 
308   /// getLongWidth/Align - Return the size of 'signed long' and 'unsigned long'
309   /// for this target, in bits.
getLongWidth()310   unsigned getLongWidth() const { return LongWidth; }
getLongAlign()311   unsigned getLongAlign() const { return LongAlign; }
312 
313   /// getLongLongWidth/Align - Return the size of 'signed long long' and
314   /// 'unsigned long long' for this target, in bits.
getLongLongWidth()315   unsigned getLongLongWidth() const { return LongLongWidth; }
getLongLongAlign()316   unsigned getLongLongAlign() const { return LongLongAlign; }
317 
318   /// \brief Determine whether the __int128 type is supported on this target.
hasInt128Type()319   virtual bool hasInt128Type() const {
320     return getPointerWidth(0) >= 64;
321   } // FIXME
322 
323   /// \brief Return the alignment that is suitable for storing any
324   /// object with a fundamental alignment requirement.
getSuitableAlign()325   unsigned getSuitableAlign() const { return SuitableAlign; }
326 
327   /// \brief Return the default alignment for __attribute__((aligned)) on
328   /// this target, to be used if no alignment value is specified.
getDefaultAlignForAttributeAligned()329   unsigned getDefaultAlignForAttributeAligned() const {
330     return DefaultAlignForAttributeAligned;
331   }
332 
333   /// getMinGlobalAlign - Return the minimum alignment of a global variable,
334   /// unless its alignment is explicitly reduced via attributes.
getMinGlobalAlign()335   unsigned getMinGlobalAlign() const { return MinGlobalAlign; }
336 
337   /// getWCharWidth/Align - Return the size of 'wchar_t' for this target, in
338   /// bits.
getWCharWidth()339   unsigned getWCharWidth() const { return getTypeWidth(WCharType); }
getWCharAlign()340   unsigned getWCharAlign() const { return getTypeAlign(WCharType); }
341 
342   /// getChar16Width/Align - Return the size of 'char16_t' for this target, in
343   /// bits.
getChar16Width()344   unsigned getChar16Width() const { return getTypeWidth(Char16Type); }
getChar16Align()345   unsigned getChar16Align() const { return getTypeAlign(Char16Type); }
346 
347   /// getChar32Width/Align - Return the size of 'char32_t' for this target, in
348   /// bits.
getChar32Width()349   unsigned getChar32Width() const { return getTypeWidth(Char32Type); }
getChar32Align()350   unsigned getChar32Align() const { return getTypeAlign(Char32Type); }
351 
352   /// getHalfWidth/Align/Format - Return the size/align/format of 'half'.
getHalfWidth()353   unsigned getHalfWidth() const { return HalfWidth; }
getHalfAlign()354   unsigned getHalfAlign() const { return HalfAlign; }
getHalfFormat()355   const llvm::fltSemantics &getHalfFormat() const { return *HalfFormat; }
356 
357   /// getFloatWidth/Align/Format - Return the size/align/format of 'float'.
getFloatWidth()358   unsigned getFloatWidth() const { return FloatWidth; }
getFloatAlign()359   unsigned getFloatAlign() const { return FloatAlign; }
getFloatFormat()360   const llvm::fltSemantics &getFloatFormat() const { return *FloatFormat; }
361 
362   /// getDoubleWidth/Align/Format - Return the size/align/format of 'double'.
getDoubleWidth()363   unsigned getDoubleWidth() const { return DoubleWidth; }
getDoubleAlign()364   unsigned getDoubleAlign() const { return DoubleAlign; }
getDoubleFormat()365   const llvm::fltSemantics &getDoubleFormat() const { return *DoubleFormat; }
366 
367   /// getLongDoubleWidth/Align/Format - Return the size/align/format of 'long
368   /// double'.
getLongDoubleWidth()369   unsigned getLongDoubleWidth() const { return LongDoubleWidth; }
getLongDoubleAlign()370   unsigned getLongDoubleAlign() const { return LongDoubleAlign; }
getLongDoubleFormat()371   const llvm::fltSemantics &getLongDoubleFormat() const {
372     return *LongDoubleFormat;
373   }
374 
375   /// \brief Return true if the 'long double' type should be mangled like
376   /// __float128.
useFloat128ManglingForLongDouble()377   virtual bool useFloat128ManglingForLongDouble() const { return false; }
378 
379   /// \brief Return the value for the C99 FLT_EVAL_METHOD macro.
getFloatEvalMethod()380   virtual unsigned getFloatEvalMethod() const { return 0; }
381 
382   // getLargeArrayMinWidth/Align - Return the minimum array size that is
383   // 'large' and its alignment.
getLargeArrayMinWidth()384   unsigned getLargeArrayMinWidth() const { return LargeArrayMinWidth; }
getLargeArrayAlign()385   unsigned getLargeArrayAlign() const { return LargeArrayAlign; }
386 
387   /// \brief Return the maximum width lock-free atomic operation which will
388   /// ever be supported for the given target
getMaxAtomicPromoteWidth()389   unsigned getMaxAtomicPromoteWidth() const { return MaxAtomicPromoteWidth; }
390   /// \brief Return the maximum width lock-free atomic operation which can be
391   /// inlined given the supported features of the given target.
getMaxAtomicInlineWidth()392   unsigned getMaxAtomicInlineWidth() const { return MaxAtomicInlineWidth; }
393   /// \brief Returns true if the given target supports lock-free atomic
394   /// operations at the specified width and alignment.
hasBuiltinAtomic(uint64_t AtomicSizeInBits,uint64_t AlignmentInBits)395   virtual bool hasBuiltinAtomic(uint64_t AtomicSizeInBits,
396                                 uint64_t AlignmentInBits) const {
397     return AtomicSizeInBits <= AlignmentInBits &&
398            AtomicSizeInBits <= getMaxAtomicInlineWidth() &&
399            (AtomicSizeInBits <= getCharWidth() ||
400             llvm::isPowerOf2_64(AtomicSizeInBits / getCharWidth()));
401   }
402 
403   /// \brief Return the maximum vector alignment supported for the given target.
getMaxVectorAlign()404   unsigned getMaxVectorAlign() const { return MaxVectorAlign; }
405   /// \brief Return default simd alignment for the given target. Generally, this
406   /// value is type-specific, but this alignment can be used for most of the
407   /// types for the given target.
getSimdDefaultAlign()408   unsigned getSimdDefaultAlign() const { return SimdDefaultAlign; }
409 
410   /// \brief Return the size of intmax_t and uintmax_t for this target, in bits.
getIntMaxTWidth()411   unsigned getIntMaxTWidth() const {
412     return getTypeWidth(IntMaxType);
413   }
414 
415   // Return the size of unwind_word for this target.
getUnwindWordWidth()416   unsigned getUnwindWordWidth() const { return getPointerWidth(0); }
417 
418   /// \brief Return the "preferred" register width on this target.
getRegisterWidth()419   unsigned getRegisterWidth() const {
420     // Currently we assume the register width on the target matches the pointer
421     // width, we can introduce a new variable for this if/when some target wants
422     // it.
423     return PointerWidth;
424   }
425 
426   /// \brief Returns the default value of the __USER_LABEL_PREFIX__ macro,
427   /// which is the prefix given to user symbols by default.
428   ///
429   /// On most platforms this is "_", but it is "" on some, and "." on others.
getUserLabelPrefix()430   const char *getUserLabelPrefix() const {
431     return UserLabelPrefix;
432   }
433 
434   /// \brief Returns the name of the mcount instrumentation function.
getMCountName()435   const char *getMCountName() const {
436     return MCountName;
437   }
438 
439   /// \brief Check if the Objective-C built-in boolean type should be signed
440   /// char.
441   ///
442   /// Otherwise, if this returns false, the normal built-in boolean type
443   /// should also be used for Objective-C.
useSignedCharForObjCBool()444   bool useSignedCharForObjCBool() const {
445     return UseSignedCharForObjCBool;
446   }
noSignedCharForObjCBool()447   void noSignedCharForObjCBool() {
448     UseSignedCharForObjCBool = false;
449   }
450 
451   /// \brief Check whether the alignment of bit-field types is respected
452   /// when laying out structures.
useBitFieldTypeAlignment()453   bool useBitFieldTypeAlignment() const {
454     return UseBitFieldTypeAlignment;
455   }
456 
457   /// \brief Check whether zero length bitfields should force alignment of
458   /// the next member.
useZeroLengthBitfieldAlignment()459   bool useZeroLengthBitfieldAlignment() const {
460     return UseZeroLengthBitfieldAlignment;
461   }
462 
463   /// \brief Get the fixed alignment value in bits for a member that follows
464   /// a zero length bitfield.
getZeroLengthBitfieldBoundary()465   unsigned getZeroLengthBitfieldBoundary() const {
466     return ZeroLengthBitfieldBoundary;
467   }
468 
469   /// \brief Check whether this target support '\#pragma options align=mac68k'.
hasAlignMac68kSupport()470   bool hasAlignMac68kSupport() const {
471     return HasAlignMac68kSupport;
472   }
473 
474   /// \brief Return the user string for the specified integer type enum.
475   ///
476   /// For example, SignedShort -> "short".
477   static const char *getTypeName(IntType T);
478 
479   /// \brief Return the constant suffix for the specified integer type enum.
480   ///
481   /// For example, SignedLong -> "L".
482   const char *getTypeConstantSuffix(IntType T) const;
483 
484   /// \brief Return the printf format modifier for the specified
485   /// integer type enum.
486   ///
487   /// For example, SignedLong -> "l".
488   static const char *getTypeFormatModifier(IntType T);
489 
490   /// \brief Check whether the given real type should use the "fpret" flavor of
491   /// Objective-C message passing on this target.
useObjCFPRetForRealType(RealType T)492   bool useObjCFPRetForRealType(RealType T) const {
493     return RealTypeUsesObjCFPRet & (1 << T);
494   }
495 
496   /// \brief Check whether _Complex long double should use the "fp2ret" flavor
497   /// of Objective-C message passing on this target.
useObjCFP2RetForComplexLongDouble()498   bool useObjCFP2RetForComplexLongDouble() const {
499     return ComplexLongDoubleUsesFP2Ret;
500   }
501 
502   /// \brief Specify if mangling based on address space map should be used or
503   /// not for language specific address spaces
useAddressSpaceMapMangling()504   bool useAddressSpaceMapMangling() const {
505     return UseAddrSpaceMapMangling;
506   }
507 
508   ///===---- Other target property query methods --------------------------===//
509 
510   /// \brief Appends the target-specific \#define values for this
511   /// target set to the specified buffer.
512   virtual void getTargetDefines(const LangOptions &Opts,
513                                 MacroBuilder &Builder) const = 0;
514 
515 
516   /// Return information about target-specific builtins for
517   /// the current primary target, and info about which builtins are non-portable
518   /// across the current set of primary and secondary targets.
519   virtual ArrayRef<Builtin::Info> getTargetBuiltins() const = 0;
520 
521   /// The __builtin_clz* and __builtin_ctz* built-in
522   /// functions are specified to have undefined results for zero inputs, but
523   /// on targets that support these operations in a way that provides
524   /// well-defined results for zero without loss of performance, it is a good
525   /// idea to avoid optimizing based on that undef behavior.
isCLZForZeroUndef()526   virtual bool isCLZForZeroUndef() const { return true; }
527 
528   /// \brief Returns the kind of __builtin_va_list type that should be used
529   /// with this target.
530   virtual BuiltinVaListKind getBuiltinVaListKind() const = 0;
531 
532   /// Returns whether or not type \c __builtin_ms_va_list type is
533   /// available on this target.
hasBuiltinMSVaList()534   bool hasBuiltinMSVaList() const { return HasBuiltinMSVaList; }
535 
536   /// \brief Returns whether the passed in string is a valid clobber in an
537   /// inline asm statement.
538   ///
539   /// This is used by Sema.
540   bool isValidClobber(StringRef Name) const;
541 
542   /// \brief Returns whether the passed in string is a valid register name
543   /// according to GCC.
544   ///
545   /// This is used by Sema for inline asm statements.
546   bool isValidGCCRegisterName(StringRef Name) const;
547 
548   /// \brief Returns the "normalized" GCC register name.
549   ///
550   /// For example, on x86 it will return "ax" when "eax" is passed in.
551   StringRef getNormalizedGCCRegisterName(StringRef Name) const;
552 
553   struct ConstraintInfo {
554     enum {
555       CI_None = 0x00,
556       CI_AllowsMemory = 0x01,
557       CI_AllowsRegister = 0x02,
558       CI_ReadWrite = 0x04,         // "+r" output constraint (read and write).
559       CI_HasMatchingInput = 0x08,  // This output operand has a matching input.
560       CI_ImmediateConstant = 0x10, // This operand must be an immediate constant
561       CI_EarlyClobber = 0x20,      // "&" output constraint (early clobber).
562     };
563     unsigned Flags;
564     int TiedOperand;
565     struct {
566       int Min;
567       int Max;
568     } ImmRange;
569     llvm::SmallSet<int, 4> ImmSet;
570 
571     std::string ConstraintStr;  // constraint: "=rm"
572     std::string Name;           // Operand name: [foo] with no []'s.
573   public:
ConstraintInfoConstraintInfo574     ConstraintInfo(StringRef ConstraintStr, StringRef Name)
575         : Flags(0), TiedOperand(-1), ConstraintStr(ConstraintStr.str()),
576           Name(Name.str()) {
577       ImmRange.Min = ImmRange.Max = 0;
578     }
579 
getConstraintStrConstraintInfo580     const std::string &getConstraintStr() const { return ConstraintStr; }
getNameConstraintInfo581     const std::string &getName() const { return Name; }
isReadWriteConstraintInfo582     bool isReadWrite() const { return (Flags & CI_ReadWrite) != 0; }
earlyClobberConstraintInfo583     bool earlyClobber() { return (Flags & CI_EarlyClobber) != 0; }
allowsRegisterConstraintInfo584     bool allowsRegister() const { return (Flags & CI_AllowsRegister) != 0; }
allowsMemoryConstraintInfo585     bool allowsMemory() const { return (Flags & CI_AllowsMemory) != 0; }
586 
587     /// \brief Return true if this output operand has a matching
588     /// (tied) input operand.
hasMatchingInputConstraintInfo589     bool hasMatchingInput() const { return (Flags & CI_HasMatchingInput) != 0; }
590 
591     /// \brief Return true if this input operand is a matching
592     /// constraint that ties it to an output operand.
593     ///
594     /// If this returns true then getTiedOperand will indicate which output
595     /// operand this is tied to.
hasTiedOperandConstraintInfo596     bool hasTiedOperand() const { return TiedOperand != -1; }
getTiedOperandConstraintInfo597     unsigned getTiedOperand() const {
598       assert(hasTiedOperand() && "Has no tied operand!");
599       return (unsigned)TiedOperand;
600     }
601 
requiresImmediateConstantConstraintInfo602     bool requiresImmediateConstant() const {
603       return (Flags & CI_ImmediateConstant) != 0;
604     }
isValidAsmImmediateConstraintInfo605     bool isValidAsmImmediate(const llvm::APInt &Value) const {
606       return (Value.sge(ImmRange.Min) && Value.sle(ImmRange.Max)) ||
607              ImmSet.count(Value.getZExtValue()) != 0;
608     }
609 
setIsReadWriteConstraintInfo610     void setIsReadWrite() { Flags |= CI_ReadWrite; }
setEarlyClobberConstraintInfo611     void setEarlyClobber() { Flags |= CI_EarlyClobber; }
setAllowsMemoryConstraintInfo612     void setAllowsMemory() { Flags |= CI_AllowsMemory; }
setAllowsRegisterConstraintInfo613     void setAllowsRegister() { Flags |= CI_AllowsRegister; }
setHasMatchingInputConstraintInfo614     void setHasMatchingInput() { Flags |= CI_HasMatchingInput; }
setRequiresImmediateConstraintInfo615     void setRequiresImmediate(int Min, int Max) {
616       Flags |= CI_ImmediateConstant;
617       ImmRange.Min = Min;
618       ImmRange.Max = Max;
619     }
setRequiresImmediateConstraintInfo620     void setRequiresImmediate(llvm::ArrayRef<int> Exacts) {
621       Flags |= CI_ImmediateConstant;
622       for (int Exact : Exacts)
623         ImmSet.insert(Exact);
624     }
setRequiresImmediateConstraintInfo625     void setRequiresImmediate(int Exact) {
626       Flags |= CI_ImmediateConstant;
627       ImmSet.insert(Exact);
628     }
setRequiresImmediateConstraintInfo629     void setRequiresImmediate() {
630       Flags |= CI_ImmediateConstant;
631       ImmRange.Min = INT_MIN;
632       ImmRange.Max = INT_MAX;
633     }
634 
635     /// \brief Indicate that this is an input operand that is tied to
636     /// the specified output operand.
637     ///
638     /// Copy over the various constraint information from the output.
setTiedOperandConstraintInfo639     void setTiedOperand(unsigned N, ConstraintInfo &Output) {
640       Output.setHasMatchingInput();
641       Flags = Output.Flags;
642       TiedOperand = N;
643       // Don't copy Name or constraint string.
644     }
645   };
646 
647   /// \brief Validate register name used for global register variables.
648   ///
649   /// This function returns true if the register passed in RegName can be used
650   /// for global register variables on this target. In addition, it returns
651   /// true in HasSizeMismatch if the size of the register doesn't match the
652   /// variable size passed in RegSize.
validateGlobalRegisterVariable(StringRef RegName,unsigned RegSize,bool & HasSizeMismatch)653   virtual bool validateGlobalRegisterVariable(StringRef RegName,
654                                               unsigned RegSize,
655                                               bool &HasSizeMismatch) const {
656     HasSizeMismatch = false;
657     return true;
658   }
659 
660   // validateOutputConstraint, validateInputConstraint - Checks that
661   // a constraint is valid and provides information about it.
662   // FIXME: These should return a real error instead of just true/false.
663   bool validateOutputConstraint(ConstraintInfo &Info) const;
664   bool validateInputConstraint(MutableArrayRef<ConstraintInfo> OutputConstraints,
665                                ConstraintInfo &info) const;
666 
validateOutputSize(StringRef,unsigned)667   virtual bool validateOutputSize(StringRef /*Constraint*/,
668                                   unsigned /*Size*/) const {
669     return true;
670   }
671 
validateInputSize(StringRef,unsigned)672   virtual bool validateInputSize(StringRef /*Constraint*/,
673                                  unsigned /*Size*/) const {
674     return true;
675   }
676   virtual bool
validateConstraintModifier(StringRef,char,unsigned,std::string &)677   validateConstraintModifier(StringRef /*Constraint*/,
678                              char /*Modifier*/,
679                              unsigned /*Size*/,
680                              std::string &/*SuggestedModifier*/) const {
681     return true;
682   }
683   virtual bool
684   validateAsmConstraint(const char *&Name,
685                         TargetInfo::ConstraintInfo &info) const = 0;
686 
687   bool resolveSymbolicName(const char *&Name,
688                            ArrayRef<ConstraintInfo> OutputConstraints,
689                            unsigned &Index) const;
690 
691   // Constraint parm will be left pointing at the last character of
692   // the constraint.  In practice, it won't be changed unless the
693   // constraint is longer than one character.
convertConstraint(const char * & Constraint)694   virtual std::string convertConstraint(const char *&Constraint) const {
695     // 'p' defaults to 'r', but can be overridden by targets.
696     if (*Constraint == 'p')
697       return std::string("r");
698     return std::string(1, *Constraint);
699   }
700 
701   /// \brief Returns a string of target-specific clobbers, in LLVM format.
702   virtual const char *getClobbers() const = 0;
703 
704   /// \brief Returns true if NaN encoding is IEEE 754-2008.
705   /// Only MIPS allows a different encoding.
isNan2008()706   virtual bool isNan2008() const {
707     return true;
708   }
709 
710   /// \brief Returns the target triple of the primary target.
getTriple()711   const llvm::Triple &getTriple() const {
712     return Triple;
713   }
714 
getDataLayoutString()715   const char *getDataLayoutString() const {
716     assert(DataLayoutString && "Uninitialized DataLayoutString!");
717     return DataLayoutString;
718   }
719 
720   struct GCCRegAlias {
721     const char * const Aliases[5];
722     const char * const Register;
723   };
724 
725   struct AddlRegName {
726     const char * const Names[5];
727     const unsigned RegNum;
728   };
729 
730   /// \brief Does this target support "protected" visibility?
731   ///
732   /// Any target which dynamic libraries will naturally support
733   /// something like "default" (meaning that the symbol is visible
734   /// outside this shared object) and "hidden" (meaning that it isn't)
735   /// visibilities, but "protected" is really an ELF-specific concept
736   /// with weird semantics designed around the convenience of dynamic
737   /// linker implementations.  Which is not to suggest that there's
738   /// consistent target-independent semantics for "default" visibility
739   /// either; the entire thing is pretty badly mangled.
hasProtectedVisibility()740   virtual bool hasProtectedVisibility() const { return true; }
741 
742   /// \brief An optional hook that targets can implement to perform semantic
743   /// checking on attribute((section("foo"))) specifiers.
744   ///
745   /// In this case, "foo" is passed in to be checked.  If the section
746   /// specifier is invalid, the backend should return a non-empty string
747   /// that indicates the problem.
748   ///
749   /// This hook is a simple quality of implementation feature to catch errors
750   /// and give good diagnostics in cases when the assembler or code generator
751   /// would otherwise reject the section specifier.
752   ///
isValidSectionSpecifier(StringRef SR)753   virtual std::string isValidSectionSpecifier(StringRef SR) const {
754     return "";
755   }
756 
757   /// \brief Set forced language options.
758   ///
759   /// Apply changes to the target information with respect to certain
760   /// language options which change the target configuration.
761   virtual void adjust(const LangOptions &Opts);
762 
763   /// \brief Initialize the map with the default set of target features for the
764   /// CPU this should include all legal feature strings on the target.
765   ///
766   /// \return False on error (invalid features).
767   virtual bool initFeatureMap(llvm::StringMap<bool> &Features,
768                               DiagnosticsEngine &Diags, StringRef CPU,
769                               const std::vector<std::string> &FeatureVec) const;
770 
771   /// \brief Get the ABI currently in use.
getABI()772   virtual StringRef getABI() const { return StringRef(); }
773 
774   /// \brief Get the C++ ABI currently in use.
getCXXABI()775   TargetCXXABI getCXXABI() const {
776     return TheCXXABI;
777   }
778 
779   /// \brief Target the specified CPU.
780   ///
781   /// \return  False on error (invalid CPU name).
setCPU(const std::string & Name)782   virtual bool setCPU(const std::string &Name) {
783     return false;
784   }
785 
786   /// \brief Use the specified ABI.
787   ///
788   /// \return False on error (invalid ABI name).
setABI(const std::string & Name)789   virtual bool setABI(const std::string &Name) {
790     return false;
791   }
792 
793   /// \brief Use the specified unit for FP math.
794   ///
795   /// \return False on error (invalid unit name).
setFPMath(StringRef Name)796   virtual bool setFPMath(StringRef Name) {
797     return false;
798   }
799 
800   /// \brief Enable or disable a specific target feature;
801   /// the feature name must be valid.
setFeatureEnabled(llvm::StringMap<bool> & Features,StringRef Name,bool Enabled)802   virtual void setFeatureEnabled(llvm::StringMap<bool> &Features,
803                                  StringRef Name,
804                                  bool Enabled) const {
805     Features[Name] = Enabled;
806   }
807 
808   /// \brief Perform initialization based on the user configured
809   /// set of features (e.g., +sse4).
810   ///
811   /// The list is guaranteed to have at most one entry per feature.
812   ///
813   /// The target may modify the features list, to change which options are
814   /// passed onwards to the backend.
815   /// FIXME: This part should be fixed so that we can change handleTargetFeatures
816   /// to merely a TargetInfo initialization routine.
817   ///
818   /// \return  False on error.
handleTargetFeatures(std::vector<std::string> & Features,DiagnosticsEngine & Diags)819   virtual bool handleTargetFeatures(std::vector<std::string> &Features,
820                                     DiagnosticsEngine &Diags) {
821     return true;
822   }
823 
824   /// \brief Determine whether the given target has the given feature.
hasFeature(StringRef Feature)825   virtual bool hasFeature(StringRef Feature) const {
826     return false;
827   }
828 
829   // \brief Validate the contents of the __builtin_cpu_supports(const char*)
830   // argument.
validateCpuSupports(StringRef Name)831   virtual bool validateCpuSupports(StringRef Name) const { return false; }
832 
833   // \brief Returns maximal number of args passed in registers.
getRegParmMax()834   unsigned getRegParmMax() const {
835     assert(RegParmMax < 7 && "RegParmMax value is larger than AST can handle");
836     return RegParmMax;
837   }
838 
839   /// \brief Whether the target supports thread-local storage.
isTLSSupported()840   bool isTLSSupported() const {
841     return TLSSupported;
842   }
843 
844   /// \brief Return the maximum alignment (in bits) of a TLS variable
845   ///
846   /// Gets the maximum alignment (in bits) of a TLS variable on this target.
847   /// Returns zero if there is no such constraint.
getMaxTLSAlign()848   unsigned short getMaxTLSAlign() const {
849     return MaxTLSAlign;
850   }
851 
852   /// \brief Whether the target supports SEH __try.
isSEHTrySupported()853   bool isSEHTrySupported() const {
854     return getTriple().isOSWindows() &&
855            (getTriple().getArch() == llvm::Triple::x86 ||
856             getTriple().getArch() == llvm::Triple::x86_64);
857   }
858 
859   /// \brief Return true if {|} are normal characters in the asm string.
860   ///
861   /// If this returns false (the default), then {abc|xyz} is syntax
862   /// that says that when compiling for asm variant #0, "abc" should be
863   /// generated, but when compiling for asm variant #1, "xyz" should be
864   /// generated.
hasNoAsmVariants()865   bool hasNoAsmVariants() const {
866     return NoAsmVariants;
867   }
868 
869   /// \brief Return the register number that __builtin_eh_return_regno would
870   /// return with the specified argument.
getEHDataRegisterNumber(unsigned RegNo)871   virtual int getEHDataRegisterNumber(unsigned RegNo) const {
872     return -1;
873   }
874 
875   /// \brief Return the section to use for C++ static initialization functions.
getStaticInitSectionSpecifier()876   virtual const char *getStaticInitSectionSpecifier() const {
877     return nullptr;
878   }
879 
getAddressSpaceMap()880   const LangAS::Map &getAddressSpaceMap() const {
881     return *AddrSpaceMap;
882   }
883 
884   /// \brief Retrieve the name of the platform as it is used in the
885   /// availability attribute.
getPlatformName()886   StringRef getPlatformName() const { return PlatformName; }
887 
888   /// \brief Retrieve the minimum desired version of the platform, to
889   /// which the program should be compiled.
getPlatformMinVersion()890   VersionTuple getPlatformMinVersion() const { return PlatformMinVersion; }
891 
isBigEndian()892   bool isBigEndian() const { return BigEndian; }
893 
894   enum CallingConvMethodType {
895     CCMT_Unknown,
896     CCMT_Member,
897     CCMT_NonMember
898   };
899 
900   /// \brief Gets the default calling convention for the given target and
901   /// declaration context.
getDefaultCallingConv(CallingConvMethodType MT)902   virtual CallingConv getDefaultCallingConv(CallingConvMethodType MT) const {
903     // Not all targets will specify an explicit calling convention that we can
904     // express.  This will always do the right thing, even though it's not
905     // an explicit calling convention.
906     return CC_C;
907   }
908 
909   enum CallingConvCheckResult {
910     CCCR_OK,
911     CCCR_Warning,
912     CCCR_Ignore,
913   };
914 
915   /// \brief Determines whether a given calling convention is valid for the
916   /// target. A calling convention can either be accepted, produce a warning
917   /// and be substituted with the default calling convention, or (someday)
918   /// produce an error (such as using thiscall on a non-instance function).
checkCallingConvention(CallingConv CC)919   virtual CallingConvCheckResult checkCallingConvention(CallingConv CC) const {
920     switch (CC) {
921       default:
922         return CCCR_Warning;
923       case CC_C:
924         return CCCR_OK;
925     }
926   }
927 
928   /// Controls if __builtin_longjmp / __builtin_setjmp can be lowered to
929   /// llvm.eh.sjlj.longjmp / llvm.eh.sjlj.setjmp.
hasSjLjLowering()930   virtual bool hasSjLjLowering() const {
931     return false;
932   }
933 
934 protected:
getPointerWidthV(unsigned AddrSpace)935   virtual uint64_t getPointerWidthV(unsigned AddrSpace) const {
936     return PointerWidth;
937   }
getPointerAlignV(unsigned AddrSpace)938   virtual uint64_t getPointerAlignV(unsigned AddrSpace) const {
939     return PointerAlign;
940   }
getPtrDiffTypeV(unsigned AddrSpace)941   virtual enum IntType getPtrDiffTypeV(unsigned AddrSpace) const {
942     return PtrDiffType;
943   }
944   virtual ArrayRef<const char *> getGCCRegNames() const = 0;
945   virtual ArrayRef<GCCRegAlias> getGCCRegAliases() const = 0;
getGCCAddlRegNames()946   virtual ArrayRef<AddlRegName> getGCCAddlRegNames() const {
947     return None;
948   }
949 };
950 
951 }  // end namespace clang
952 
953 #endif
954