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1 //==-- CGFunctionInfo.h - Representation of function argument/return types -==//
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 // Defines CGFunctionInfo and associated types used in representing the
11 // LLVM source types and ABI-coerced types for function arguments and
12 // return values.
13 //
14 //===----------------------------------------------------------------------===//
15 
16 #ifndef LLVM_CLANG_CODEGEN_CGFUNCTIONINFO_H
17 #define LLVM_CLANG_CODEGEN_CGFUNCTIONINFO_H
18 
19 #include "clang/AST/CanonicalType.h"
20 #include "clang/AST/Type.h"
21 #include "llvm/ADT/FoldingSet.h"
22 #include <cassert>
23 
24 namespace llvm {
25   class Type;
26   class StructType;
27 }
28 
29 namespace clang {
30 class Decl;
31 
32 namespace CodeGen {
33 
34 /// ABIArgInfo - Helper class to encapsulate information about how a
35 /// specific C type should be passed to or returned from a function.
36 class ABIArgInfo {
37 public:
38   enum Kind : uint8_t {
39     /// Direct - Pass the argument directly using the normal converted LLVM
40     /// type, or by coercing to another specified type stored in
41     /// 'CoerceToType').  If an offset is specified (in UIntData), then the
42     /// argument passed is offset by some number of bytes in the memory
43     /// representation. A dummy argument is emitted before the real argument
44     /// if the specified type stored in "PaddingType" is not zero.
45     Direct,
46 
47     /// Extend - Valid only for integer argument types. Same as 'direct'
48     /// but also emit a zero/sign extension attribute.
49     Extend,
50 
51     /// Indirect - Pass the argument indirectly via a hidden pointer
52     /// with the specified alignment (0 indicates default alignment).
53     Indirect,
54 
55     /// Ignore - Ignore the argument (treat as void). Useful for void and
56     /// empty structs.
57     Ignore,
58 
59     /// Expand - Only valid for aggregate argument types. The structure should
60     /// be expanded into consecutive arguments for its constituent fields.
61     /// Currently expand is only allowed on structures whose fields
62     /// are all scalar types or are themselves expandable types.
63     Expand,
64 
65     /// InAlloca - Pass the argument directly using the LLVM inalloca attribute.
66     /// This is similar to indirect with byval, except it only applies to
67     /// arguments stored in memory and forbids any implicit copies.  When
68     /// applied to a return type, it means the value is returned indirectly via
69     /// an implicit sret parameter stored in the argument struct.
70     InAlloca,
71     KindFirst = Direct,
72     KindLast = InAlloca
73   };
74 
75 private:
76   llvm::Type *TypeData; // isDirect() || isExtend()
77   llvm::Type *PaddingType;
78   union {
79     unsigned DirectOffset;     // isDirect() || isExtend()
80     unsigned IndirectAlign;    // isIndirect()
81     unsigned AllocaFieldIndex; // isInAlloca()
82   };
83   Kind TheKind;
84   bool PaddingInReg : 1;
85   bool InAllocaSRet : 1;    // isInAlloca()
86   bool IndirectByVal : 1;   // isIndirect()
87   bool IndirectRealign : 1; // isIndirect()
88   bool SRetAfterThis : 1;   // isIndirect()
89   bool InReg : 1;           // isDirect() || isExtend() || isIndirect()
90   bool CanBeFlattened: 1;   // isDirect()
91 
ABIArgInfo(Kind K)92   ABIArgInfo(Kind K)
93       : PaddingType(nullptr), TheKind(K), PaddingInReg(false), InReg(false) {}
94 
95 public:
ABIArgInfo()96   ABIArgInfo()
97       : TypeData(nullptr), PaddingType(nullptr), DirectOffset(0),
98         TheKind(Direct), PaddingInReg(false), InReg(false) {}
99 
100   static ABIArgInfo getDirect(llvm::Type *T = nullptr, unsigned Offset = 0,
101                               llvm::Type *Padding = nullptr,
102                               bool CanBeFlattened = true) {
103     auto AI = ABIArgInfo(Direct);
104     AI.setCoerceToType(T);
105     AI.setDirectOffset(Offset);
106     AI.setPaddingType(Padding);
107     AI.setCanBeFlattened(CanBeFlattened);
108     return AI;
109   }
110   static ABIArgInfo getDirectInReg(llvm::Type *T = nullptr) {
111     auto AI = getDirect(T);
112     AI.setInReg(true);
113     return AI;
114   }
115   static ABIArgInfo getExtend(llvm::Type *T = nullptr) {
116     auto AI = ABIArgInfo(Extend);
117     AI.setCoerceToType(T);
118     AI.setDirectOffset(0);
119     return AI;
120   }
121   static ABIArgInfo getExtendInReg(llvm::Type *T = nullptr) {
122     auto AI = getExtend(T);
123     AI.setInReg(true);
124     return AI;
125   }
getIgnore()126   static ABIArgInfo getIgnore() {
127     return ABIArgInfo(Ignore);
128   }
129   static ABIArgInfo getIndirect(unsigned Alignment, bool ByVal = true,
130                                 bool Realign = false,
131                                 llvm::Type *Padding = nullptr) {
132     auto AI = ABIArgInfo(Indirect);
133     AI.setIndirectAlign(Alignment);
134     AI.setIndirectByVal(ByVal);
135     AI.setIndirectRealign(Realign);
136     AI.setSRetAfterThis(false);
137     AI.setPaddingType(Padding);
138     return AI;
139   }
140   static ABIArgInfo getIndirectInReg(unsigned Alignment, bool ByVal = true,
141                                      bool Realign = false) {
142     auto AI = getIndirect(Alignment, ByVal, Realign);
143     AI.setInReg(true);
144     return AI;
145   }
getInAlloca(unsigned FieldIndex)146   static ABIArgInfo getInAlloca(unsigned FieldIndex) {
147     auto AI = ABIArgInfo(InAlloca);
148     AI.setInAllocaFieldIndex(FieldIndex);
149     return AI;
150   }
getExpand()151   static ABIArgInfo getExpand() {
152     return ABIArgInfo(Expand);
153   }
getExpandWithPadding(bool PaddingInReg,llvm::Type * Padding)154   static ABIArgInfo getExpandWithPadding(bool PaddingInReg,
155                                          llvm::Type *Padding) {
156     auto AI = getExpand();
157     AI.setPaddingInReg(PaddingInReg);
158     AI.setPaddingType(Padding);
159     return AI;
160   }
161 
getKind()162   Kind getKind() const { return TheKind; }
isDirect()163   bool isDirect() const { return TheKind == Direct; }
isInAlloca()164   bool isInAlloca() const { return TheKind == InAlloca; }
isExtend()165   bool isExtend() const { return TheKind == Extend; }
isIgnore()166   bool isIgnore() const { return TheKind == Ignore; }
isIndirect()167   bool isIndirect() const { return TheKind == Indirect; }
isExpand()168   bool isExpand() const { return TheKind == Expand; }
169 
canHaveCoerceToType()170   bool canHaveCoerceToType() const { return isDirect() || isExtend(); }
171 
172   // Direct/Extend accessors
getDirectOffset()173   unsigned getDirectOffset() const {
174     assert((isDirect() || isExtend()) && "Not a direct or extend kind");
175     return DirectOffset;
176   }
setDirectOffset(unsigned Offset)177   void setDirectOffset(unsigned Offset) {
178     assert((isDirect() || isExtend()) && "Not a direct or extend kind");
179     DirectOffset = Offset;
180   }
181 
getPaddingType()182   llvm::Type *getPaddingType() const { return PaddingType; }
183 
setPaddingType(llvm::Type * T)184   void setPaddingType(llvm::Type *T) { PaddingType = T; }
185 
getPaddingInReg()186   bool getPaddingInReg() const {
187     return PaddingInReg;
188   }
setPaddingInReg(bool PIR)189   void setPaddingInReg(bool PIR) {
190     PaddingInReg = PIR;
191   }
192 
getCoerceToType()193   llvm::Type *getCoerceToType() const {
194     assert(canHaveCoerceToType() && "Invalid kind!");
195     return TypeData;
196   }
197 
setCoerceToType(llvm::Type * T)198   void setCoerceToType(llvm::Type *T) {
199     assert(canHaveCoerceToType() && "Invalid kind!");
200     TypeData = T;
201   }
202 
getInReg()203   bool getInReg() const {
204     assert((isDirect() || isExtend() || isIndirect()) && "Invalid kind!");
205     return InReg;
206   }
207 
setInReg(bool IR)208   void setInReg(bool IR) {
209     assert((isDirect() || isExtend() || isIndirect()) && "Invalid kind!");
210     InReg = IR;
211   }
212 
213   // Indirect accessors
getIndirectAlign()214   unsigned getIndirectAlign() const {
215     assert(isIndirect() && "Invalid kind!");
216     return IndirectAlign;
217   }
setIndirectAlign(unsigned IA)218   void setIndirectAlign(unsigned IA) {
219     assert(isIndirect() && "Invalid kind!");
220     IndirectAlign = IA;
221   }
222 
getIndirectByVal()223   bool getIndirectByVal() const {
224     assert(isIndirect() && "Invalid kind!");
225     return IndirectByVal;
226   }
setIndirectByVal(unsigned IBV)227   void setIndirectByVal(unsigned IBV) {
228     assert(isIndirect() && "Invalid kind!");
229     IndirectByVal = IBV;
230   }
231 
getIndirectRealign()232   bool getIndirectRealign() const {
233     assert(isIndirect() && "Invalid kind!");
234     return IndirectRealign;
235   }
setIndirectRealign(bool IR)236   void setIndirectRealign(bool IR) {
237     assert(isIndirect() && "Invalid kind!");
238     IndirectRealign = IR;
239   }
240 
isSRetAfterThis()241   bool isSRetAfterThis() const {
242     assert(isIndirect() && "Invalid kind!");
243     return SRetAfterThis;
244   }
setSRetAfterThis(bool AfterThis)245   void setSRetAfterThis(bool AfterThis) {
246     assert(isIndirect() && "Invalid kind!");
247     SRetAfterThis = AfterThis;
248   }
249 
getInAllocaFieldIndex()250   unsigned getInAllocaFieldIndex() const {
251     assert(isInAlloca() && "Invalid kind!");
252     return AllocaFieldIndex;
253   }
setInAllocaFieldIndex(unsigned FieldIndex)254   void setInAllocaFieldIndex(unsigned FieldIndex) {
255     assert(isInAlloca() && "Invalid kind!");
256     AllocaFieldIndex = FieldIndex;
257   }
258 
259   /// \brief Return true if this field of an inalloca struct should be returned
260   /// to implement a struct return calling convention.
getInAllocaSRet()261   bool getInAllocaSRet() const {
262     assert(isInAlloca() && "Invalid kind!");
263     return InAllocaSRet;
264   }
265 
setInAllocaSRet(bool SRet)266   void setInAllocaSRet(bool SRet) {
267     assert(isInAlloca() && "Invalid kind!");
268     InAllocaSRet = SRet;
269   }
270 
getCanBeFlattened()271   bool getCanBeFlattened() const {
272     assert(isDirect() && "Invalid kind!");
273     return CanBeFlattened;
274   }
275 
setCanBeFlattened(bool Flatten)276   void setCanBeFlattened(bool Flatten) {
277     assert(isDirect() && "Invalid kind!");
278     CanBeFlattened = Flatten;
279   }
280 
281   void dump() const;
282 };
283 
284 /// A class for recording the number of arguments that a function
285 /// signature requires.
286 class RequiredArgs {
287   /// The number of required arguments, or ~0 if the signature does
288   /// not permit optional arguments.
289   unsigned NumRequired;
290 public:
291   enum All_t { All };
292 
RequiredArgs(All_t _)293   RequiredArgs(All_t _) : NumRequired(~0U) {}
RequiredArgs(unsigned n)294   explicit RequiredArgs(unsigned n) : NumRequired(n) {
295     assert(n != ~0U);
296   }
297 
298   /// Compute the arguments required by the given formal prototype,
299   /// given that there may be some additional, non-formal arguments
300   /// in play.
forPrototypePlus(const FunctionProtoType * prototype,unsigned additional)301   static RequiredArgs forPrototypePlus(const FunctionProtoType *prototype,
302                                        unsigned additional) {
303     if (!prototype->isVariadic()) return All;
304     return RequiredArgs(prototype->getNumParams() + additional);
305   }
306 
forPrototype(const FunctionProtoType * prototype)307   static RequiredArgs forPrototype(const FunctionProtoType *prototype) {
308     return forPrototypePlus(prototype, 0);
309   }
310 
forPrototype(CanQual<FunctionProtoType> prototype)311   static RequiredArgs forPrototype(CanQual<FunctionProtoType> prototype) {
312     return forPrototype(prototype.getTypePtr());
313   }
314 
forPrototypePlus(CanQual<FunctionProtoType> prototype,unsigned additional)315   static RequiredArgs forPrototypePlus(CanQual<FunctionProtoType> prototype,
316                                        unsigned additional) {
317     return forPrototypePlus(prototype.getTypePtr(), additional);
318   }
319 
allowsOptionalArgs()320   bool allowsOptionalArgs() const { return NumRequired != ~0U; }
getNumRequiredArgs()321   unsigned getNumRequiredArgs() const {
322     assert(allowsOptionalArgs());
323     return NumRequired;
324   }
325 
getOpaqueData()326   unsigned getOpaqueData() const { return NumRequired; }
getFromOpaqueData(unsigned value)327   static RequiredArgs getFromOpaqueData(unsigned value) {
328     if (value == ~0U) return All;
329     return RequiredArgs(value);
330   }
331 };
332 
333 /// CGFunctionInfo - Class to encapsulate the information about a
334 /// function definition.
335 class CGFunctionInfo : public llvm::FoldingSetNode {
336   struct ArgInfo {
337     CanQualType type;
338     ABIArgInfo info;
339   };
340 
341   /// The LLVM::CallingConv to use for this function (as specified by the
342   /// user).
343   unsigned CallingConvention : 8;
344 
345   /// The LLVM::CallingConv to actually use for this function, which may
346   /// depend on the ABI.
347   unsigned EffectiveCallingConvention : 8;
348 
349   /// The clang::CallingConv that this was originally created with.
350   unsigned ASTCallingConvention : 8;
351 
352   /// Whether this is an instance method.
353   unsigned InstanceMethod : 1;
354 
355   /// Whether this is a chain call.
356   unsigned ChainCall : 1;
357 
358   /// Whether this function is noreturn.
359   unsigned NoReturn : 1;
360 
361   /// Whether this function is returns-retained.
362   unsigned ReturnsRetained : 1;
363 
364   /// How many arguments to pass inreg.
365   unsigned HasRegParm : 1;
366   unsigned RegParm : 3;
367 
368   RequiredArgs Required;
369 
370   /// The struct representing all arguments passed in memory.  Only used when
371   /// passing non-trivial types with inalloca.  Not part of the profile.
372   llvm::StructType *ArgStruct;
373 
374   unsigned NumArgs;
getArgsBuffer()375   ArgInfo *getArgsBuffer() {
376     return reinterpret_cast<ArgInfo*>(this+1);
377   }
getArgsBuffer()378   const ArgInfo *getArgsBuffer() const {
379     return reinterpret_cast<const ArgInfo*>(this + 1);
380   }
381 
CGFunctionInfo()382   CGFunctionInfo() : Required(RequiredArgs::All) {}
383 
384 public:
385   static CGFunctionInfo *create(unsigned llvmCC,
386                                 bool instanceMethod,
387                                 bool chainCall,
388                                 const FunctionType::ExtInfo &extInfo,
389                                 CanQualType resultType,
390                                 ArrayRef<CanQualType> argTypes,
391                                 RequiredArgs required);
392 
393   typedef const ArgInfo *const_arg_iterator;
394   typedef ArgInfo *arg_iterator;
395 
396   typedef llvm::iterator_range<arg_iterator> arg_range;
397   typedef llvm::iterator_range<const_arg_iterator> arg_const_range;
398 
arguments()399   arg_range arguments() { return arg_range(arg_begin(), arg_end()); }
arguments()400   arg_const_range arguments() const {
401     return arg_const_range(arg_begin(), arg_end());
402   }
403 
arg_begin()404   const_arg_iterator arg_begin() const { return getArgsBuffer() + 1; }
arg_end()405   const_arg_iterator arg_end() const { return getArgsBuffer() + 1 + NumArgs; }
arg_begin()406   arg_iterator arg_begin() { return getArgsBuffer() + 1; }
arg_end()407   arg_iterator arg_end() { return getArgsBuffer() + 1 + NumArgs; }
408 
arg_size()409   unsigned  arg_size() const { return NumArgs; }
410 
isVariadic()411   bool isVariadic() const { return Required.allowsOptionalArgs(); }
getRequiredArgs()412   RequiredArgs getRequiredArgs() const { return Required; }
getNumRequiredArgs()413   unsigned getNumRequiredArgs() const {
414     return isVariadic() ? getRequiredArgs().getNumRequiredArgs() : arg_size();
415   }
416 
isInstanceMethod()417   bool isInstanceMethod() const { return InstanceMethod; }
418 
isChainCall()419   bool isChainCall() const { return ChainCall; }
420 
isNoReturn()421   bool isNoReturn() const { return NoReturn; }
422 
423   /// In ARC, whether this function retains its return value.  This
424   /// is not always reliable for call sites.
isReturnsRetained()425   bool isReturnsRetained() const { return ReturnsRetained; }
426 
427   /// getASTCallingConvention() - Return the AST-specified calling
428   /// convention.
getASTCallingConvention()429   CallingConv getASTCallingConvention() const {
430     return CallingConv(ASTCallingConvention);
431   }
432 
433   /// getCallingConvention - Return the user specified calling
434   /// convention, which has been translated into an LLVM CC.
getCallingConvention()435   unsigned getCallingConvention() const { return CallingConvention; }
436 
437   /// getEffectiveCallingConvention - Return the actual calling convention to
438   /// use, which may depend on the ABI.
getEffectiveCallingConvention()439   unsigned getEffectiveCallingConvention() const {
440     return EffectiveCallingConvention;
441   }
setEffectiveCallingConvention(unsigned Value)442   void setEffectiveCallingConvention(unsigned Value) {
443     EffectiveCallingConvention = Value;
444   }
445 
getHasRegParm()446   bool getHasRegParm() const { return HasRegParm; }
getRegParm()447   unsigned getRegParm() const { return RegParm; }
448 
getExtInfo()449   FunctionType::ExtInfo getExtInfo() const {
450     return FunctionType::ExtInfo(isNoReturn(),
451                                  getHasRegParm(), getRegParm(),
452                                  getASTCallingConvention(),
453                                  isReturnsRetained());
454   }
455 
getReturnType()456   CanQualType getReturnType() const { return getArgsBuffer()[0].type; }
457 
getReturnInfo()458   ABIArgInfo &getReturnInfo() { return getArgsBuffer()[0].info; }
getReturnInfo()459   const ABIArgInfo &getReturnInfo() const { return getArgsBuffer()[0].info; }
460 
461   /// \brief Return true if this function uses inalloca arguments.
usesInAlloca()462   bool usesInAlloca() const { return ArgStruct; }
463 
464   /// \brief Get the struct type used to represent all the arguments in memory.
getArgStruct()465   llvm::StructType *getArgStruct() const { return ArgStruct; }
setArgStruct(llvm::StructType * Ty)466   void setArgStruct(llvm::StructType *Ty) { ArgStruct = Ty; }
467 
Profile(llvm::FoldingSetNodeID & ID)468   void Profile(llvm::FoldingSetNodeID &ID) {
469     ID.AddInteger(getASTCallingConvention());
470     ID.AddBoolean(InstanceMethod);
471     ID.AddBoolean(ChainCall);
472     ID.AddBoolean(NoReturn);
473     ID.AddBoolean(ReturnsRetained);
474     ID.AddBoolean(HasRegParm);
475     ID.AddInteger(RegParm);
476     ID.AddInteger(Required.getOpaqueData());
477     getReturnType().Profile(ID);
478     for (const auto &I : arguments())
479       I.type.Profile(ID);
480   }
Profile(llvm::FoldingSetNodeID & ID,bool InstanceMethod,bool ChainCall,const FunctionType::ExtInfo & info,RequiredArgs required,CanQualType resultType,ArrayRef<CanQualType> argTypes)481   static void Profile(llvm::FoldingSetNodeID &ID,
482                       bool InstanceMethod,
483                       bool ChainCall,
484                       const FunctionType::ExtInfo &info,
485                       RequiredArgs required,
486                       CanQualType resultType,
487                       ArrayRef<CanQualType> argTypes) {
488     ID.AddInteger(info.getCC());
489     ID.AddBoolean(InstanceMethod);
490     ID.AddBoolean(ChainCall);
491     ID.AddBoolean(info.getNoReturn());
492     ID.AddBoolean(info.getProducesResult());
493     ID.AddBoolean(info.getHasRegParm());
494     ID.AddInteger(info.getRegParm());
495     ID.AddInteger(required.getOpaqueData());
496     resultType.Profile(ID);
497     for (ArrayRef<CanQualType>::iterator
498            i = argTypes.begin(), e = argTypes.end(); i != e; ++i) {
499       i->Profile(ID);
500     }
501   }
502 };
503 
504 }  // end namespace CodeGen
505 }  // end namespace clang
506 
507 #endif
508