IdentifierResolver.cpp source code [clang/lib/Sema/IdentifierResolver.cpp]

1	//===- IdentifierResolver.cpp - Lexical Scope Name lookup -----------------===//
2	//
3	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4	// See https://llvm.org/LICENSE.txt for license information.
5	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6	//
7	//===----------------------------------------------------------------------===//
8	//
9	// This file implements the IdentifierResolver class, which is used for lexical
10	// scoped lookup, based on declaration names.
11	//
12	//===----------------------------------------------------------------------===//
13
14	#include "clang/Sema/IdentifierResolver.h"
15	#include "clang/AST/Decl.h"
16	#include "clang/AST/DeclBase.h"
17	#include "clang/AST/DeclarationName.h"
18	#include "clang/Basic/IdentifierTable.h"
19	#include "clang/Basic/LangOptions.h"
20	#include "clang/Lex/ExternalPreprocessorSource.h"
21	#include "clang/Lex/Preprocessor.h"
22	#include "clang/Sema/Scope.h"
23	#include "llvm/Support/ErrorHandling.h"
24	#include <cassert>
25	#include <cstdint>
26
27	using namespace clang;
28
29	//===----------------------------------------------------------------------===//
30	// IdDeclInfoMap class
31	//===----------------------------------------------------------------------===//
32
33	/// IdDeclInfoMap - Associates IdDeclInfos with declaration names.
34	/// Allocates 'pools' (vectors of IdDeclInfos) to avoid allocating each
35	/// individual IdDeclInfo to heap.
36	class IdentifierResolver::IdDeclInfoMap {
37	static const unsigned int POOL_SIZE = `512`;
38
39	/// We use our own linked-list implementation because it is sadly
40	/// impossible to add something to a pre-C++0x STL container without
41	/// a completely unnecessary copy.
42	struct IdDeclInfoPool {
43	IdDeclInfoPool *Next;
44	IdDeclInfo Pool[POOL_SIZE];
45
46	IdDeclInfoPool(IdDeclInfoPool *Next) : Next(Next) {}
47	};
48
49	IdDeclInfoPool CurPool = nullptr*;
50	unsigned int CurIndex = POOL_SIZE;
51
52	public:
53	IdDeclInfoMap() = default;
54
55	~IdDeclInfoMap() {
56	IdDeclInfoPool *Cur = CurPool;
57	while (IdDeclInfoPool *P = Cur) {
58	Cur = Cur->Next;
59	delete P;
60	}
61	}
62
63	IdDeclInfoMap(const IdDeclInfoMap &) = delete;
64	IdDeclInfoMap &operator=(const IdDeclInfoMap &) = delete;
65
66	/// Returns the IdDeclInfo associated to the DeclarationName.
67	/// It creates a new IdDeclInfo if one was not created before for this id.
68	IdDeclInfo &operator[](DeclarationName Name);
69	};
70
71	//===----------------------------------------------------------------------===//
72	// IdDeclInfo Implementation
73	//===----------------------------------------------------------------------===//
74
75	/// RemoveDecl - Remove the decl from the scope chain.
76	/// The decl must already be part of the decl chain.
77	void IdentifierResolver::IdDeclInfo::RemoveDecl(NamedDecl *D) {
78	for (DeclsTy::iterator I = Decls.end(); I != Decls.begin(); --I) {
79	if (D == *(I-`1`)) {
80	Decls.erase(CI: I-`1`);
81	return;
82	}
83	}
84
85	llvm_unreachable("Didn't find this decl on its identifier's chain!");
86	}
87
88	//===----------------------------------------------------------------------===//
89	// IdentifierResolver Implementation
90	//===----------------------------------------------------------------------===//
91
92	IdentifierResolver::IdentifierResolver(Preprocessor &PP)
93	: LangOpt(PP.getLangOpts()), PP(PP), IdDeclInfos(new IdDeclInfoMap) {}
94
95	IdentifierResolver::~IdentifierResolver() {
96	delete IdDeclInfos;
97	}
98
99	/// isDeclInScope - If 'Ctx' is a function/method, isDeclInScope returns true
100	/// if 'D' is in Scope 'S', otherwise 'S' is ignored and isDeclInScope returns
101	/// true if 'D' belongs to the given declaration context.
102	bool IdentifierResolver::isDeclInScope(Decl D, DeclContext Ctx, Scope *S,
103	bool AllowInlineNamespace) const {
104	Ctx = Ctx->getRedeclContext();
105	// The names for HLSL cbuffer/tbuffers only used by the CPU-side
106	// reflection API which supports querying bindings. It will not have name
107	// conflict with other Decls.
108	if (LangOpt.HLSL && isa<HLSLBufferDecl>(Val: D))
109	return false;
110	if (Ctx->isFunctionOrMethod() \|\| (S && S->isFunctionPrototypeScope())) {
111	// Ignore the scopes associated within transparent declaration contexts.
112	while (S->getEntity() &&
113	(S->getEntity()->isTransparentContext() \|\|
114	(!LangOpt.CPlusPlus && isa<RecordDecl>(Val: S->getEntity()))))
115	S = S->getParent();
116
117	if (S->isDeclScope(D))
118	return true;
119	if (LangOpt.CPlusPlus) {
120	// C++ 3.3.2p3:
121	// The name declared in a catch exception-declaration is local to the
122	// handler and shall not be redeclared in the outermost block of the
123	// handler.
124	// C++ 3.3.2p4:
125	// Names declared in the for-init-statement, and in the condition of if,
126	// while, for, and switch statements are local to the if, while, for, or
127	// switch statement (including the controlled statement), and shall not be
128	// redeclared in a subsequent condition of that statement nor in the
129	// outermost block (or, for the if statement, any of the outermost blocks)
130	// of the controlled statement.
131	//
132	assert(S->getParent() && "No TUScope?");
133	// If the current decl is in a lambda, we shouldn't consider this is a
134	// redefinition as lambda has its own scope.
135	if (S->getParent()->isControlScope() && !S->isFunctionScope()) {
136	S = S->getParent();
137	if (S->isDeclScope(D))
138	return true;
139	}
140	if (S->isFnTryCatchScope())
141	return S->getParent()->isDeclScope(D);
142	}
143	return false;
144	}
145
146	// FIXME: If D is a local extern declaration, this check doesn't make sense;
147	// we should be checking its lexical context instead in that case, because
148	// that is its scope.
149	DeclContext *DCtx = D->getDeclContext()->getRedeclContext();
150	return AllowInlineNamespace ? Ctx->InEnclosingNamespaceSetOf(NS: DCtx)
151	: Ctx->Equals(DC: DCtx);
152	}
153
154	/// AddDecl - Link the decl to its shadowed decl chain.
155	void IdentifierResolver::AddDecl(NamedDecl *D) {
156	DeclarationName Name = D->getDeclName();
157	if (IdentifierInfo *II = Name.getAsIdentifierInfo())
158	updatingIdentifier(II&: *II);
159
160	void *Ptr = Name.getFETokenInfo();
161
162	if (!Ptr) {
163	Name.setFETokenInfo(D);
164	return;
165	}
166
167	IdDeclInfo *IDI;
168
169	if (isDeclPtr(Ptr)) {
170	Name.setFETokenInfo(nullptr);
171	IDI = &(*IdDeclInfos)[Name];
172	NamedDecl PrevD = static_cast<NamedDecl>(Ptr);
173	IDI->AddDecl(D: PrevD);
174	} else
175	IDI = toIdDeclInfo(Ptr);
176
177	IDI->AddDecl(D);
178	}
179
180	void IdentifierResolver::InsertDeclAfter(iterator Pos, NamedDecl *D) {
181	DeclarationName Name = D->getDeclName();
182	if (IdentifierInfo *II = Name.getAsIdentifierInfo())
183	updatingIdentifier(II&: *II);
184
185	void *Ptr = Name.getFETokenInfo();
186
187	if (!Ptr) {
188	AddDecl(D);
189	return;
190	}
191
192	if (isDeclPtr(Ptr)) {
193	// We only have a single declaration: insert before or after it,
194	// as appropriate.
195	if (Pos == iterator ()) {
196	// Add the new declaration before the existing declaration.
197	NamedDecl PrevD = static_cast<NamedDecl>(Ptr);
198	RemoveDecl(D: PrevD);
199	AddDecl(D);
200	AddDecl(D: PrevD);
201	} else {
202	// Add new declaration after the existing declaration.
203	AddDecl(D);
204	}
205
206	return;
207	}
208
209	// General case: insert the declaration at the appropriate point in the
210	// list, which already has at least two elements.
211	IdDeclInfo *IDI = toIdDeclInfo(Ptr);
212	if (Pos.isIterator()) {
213	IDI->InsertDecl(Pos: Pos.getIterator() + `1`, D);
214	} else
215	IDI->InsertDecl(Pos: IDI->decls_begin(), D);
216	}
217
218	/// RemoveDecl - Unlink the decl from its shadowed decl chain.
219	/// The decl must already be part of the decl chain.
220	void IdentifierResolver::RemoveDecl(NamedDecl *D) {
221	assert(D && "null param passed");
222	DeclarationName Name = D->getDeclName();
223	if (IdentifierInfo *II = Name.getAsIdentifierInfo())
224	updatingIdentifier(II&: *II);
225
226	void *Ptr = Name.getFETokenInfo();
227
228	assert(Ptr && "Didn't find this decl on its identifier's chain!");
229
230	if (isDeclPtr(Ptr)) {
231	assert(D == Ptr && "Didn't find this decl on its identifier's chain!");
232	Name.setFETokenInfo(nullptr);
233	return;
234	}
235
236	return toIdDeclInfo(Ptr)->RemoveDecl(D);
237	}
238
239	llvm::iterator_range<IdentifierResolver::iterator>
240	IdentifierResolver::decls(DeclarationName Name) {
241	return {begin(Name), end()};
242	}
243
244	IdentifierResolver::iterator IdentifierResolver::begin(DeclarationName Name) {
245	if (IdentifierInfo *II = Name.getAsIdentifierInfo())
246	readingIdentifier(II&: *II);
247
248	void *Ptr = Name.getFETokenInfo();
249	if (!Ptr) return end();
250
251	if (isDeclPtr(Ptr))
252	return iterator (static_cast<NamedDecl*>(Ptr));
253
254	IdDeclInfo *IDI = toIdDeclInfo(Ptr);
255
256	IdDeclInfo::DeclsTy::iterator I = IDI->decls_end();
257	if (I != IDI->decls_begin())
258	return iterator (I-`1`);
259	// No decls found.
260	return end();
261	}
262
263	namespace {
264
265	enum DeclMatchKind {
266	DMK_Different,
267	DMK_Replace,
268	DMK_Ignore
269	};
270
271	} // namespace
272
273	/// Compare two declarations to see whether they are different or,
274	/// if they are the same, whether the new declaration should replace the
275	/// existing declaration.
276	static DeclMatchKind compareDeclarations(NamedDecl Existing, NamedDecl New) {
277	// If the declarations are identical, ignore the new one.
278	if (Existing == New)
279	return DMK_Ignore;
280
281	// If the declarations have different kinds, they're obviously different.
282	if (Existing->getKind() != New->getKind())
283	return DMK_Different;
284
285	// If the declarations are redeclarations of each other, keep the newest one.
286	if (Existing->getCanonicalDecl() == New->getCanonicalDecl()) {
287	// If we're adding an imported declaration, don't replace another imported
288	// declaration.
289	if (Existing->isFromASTFile() && New->isFromASTFile())
290	return DMK_Different;
291
292	// If either of these is the most recent declaration, use it.
293	Decl *MostRecent = Existing->getMostRecentDecl();
294	if (Existing == MostRecent)
295	return DMK_Ignore;
296
297	if (New == MostRecent)
298	return DMK_Replace;
299
300	// If the existing declaration is somewhere in the previous declaration
301	// chain of the new declaration, then prefer the new declaration.
302	for (auto *RD : New->redecls()) {
303	if (RD == Existing)
304	return DMK_Replace;
305
306	if (RD->isCanonicalDecl())
307	break;
308	}
309
310	return DMK_Ignore;
311	}
312
313	return DMK_Different;
314	}
315
316	bool IdentifierResolver::tryAddTopLevelDecl(NamedDecl *D, DeclarationName Name){
317	if (IdentifierInfo *II = Name.getAsIdentifierInfo())
318	readingIdentifier(II&: *II);
319
320	void *Ptr = Name.getFETokenInfo();
321
322	if (!Ptr) {
323	Name.setFETokenInfo(D);
324	return true;
325	}
326
327	IdDeclInfo *IDI;
328
329	if (isDeclPtr(Ptr)) {
330	NamedDecl PrevD = static_cast<NamedDecl>(Ptr);
331
332	switch (compareDeclarations(Existing: PrevD, New: D)) {
333	case DMK_Different:
334	break;
335
336	case DMK_Ignore:
337	return false;
338
339	case DMK_Replace:
340	Name.setFETokenInfo(D);
341	return true;
342	}
343
344	Name.setFETokenInfo(nullptr);
345	IDI = &(*IdDeclInfos)[Name];
346
347	// If the existing declaration is not visible in translation unit scope,
348	// then add the new top-level declaration first.
349	if (!PrevD->getDeclContext()->getRedeclContext()->isTranslationUnit()) {
350	IDI->AddDecl(D);
351	IDI->AddDecl(D: PrevD);
352	} else {
353	IDI->AddDecl(D: PrevD);
354	IDI->AddDecl(D);
355	}
356	return true;
357	}
358
359	IDI = toIdDeclInfo(Ptr);
360
361	// See whether this declaration is identical to any existing declarations.
362	// If not, find the right place to insert it.
363	for (IdDeclInfo::DeclsTy::iterator I = IDI->decls_begin(),
364	IEnd = IDI->decls_end();
365	I != IEnd; ++I) {
366
367	switch (compareDeclarations(Existing: *I, New: D)) {
368	case DMK_Different:
369	break;
370
371	case DMK_Ignore:
372	return false;
373
374	case DMK_Replace:
375	*I = D;
376	return true;
377	}
378
379	if (!(*I)->getDeclContext()->getRedeclContext()->isTranslationUnit()) {
380	// We've found a declaration that is not visible from the translation
381	// unit (it's in an inner scope). Insert our declaration here.
382	IDI->InsertDecl(Pos: I, D);
383	return true;
384	}
385	}
386
387	// Add the declaration to the end.
388	IDI->AddDecl(D);
389	return true;
390	}
391
392	void IdentifierResolver::readingIdentifier(IdentifierInfo &II) {
393	if (II.isOutOfDate())
394	PP.getExternalSource()->updateOutOfDateIdentifier(II);
395	}
396
397	void IdentifierResolver::updatingIdentifier(IdentifierInfo &II) {
398	if (II.isOutOfDate())
399	PP.getExternalSource()->updateOutOfDateIdentifier(II);
400
401	if (II.isFromAST())
402	II.setFETokenInfoChangedSinceDeserialization();
403	}
404
405	//===----------------------------------------------------------------------===//
406	// IdDeclInfoMap Implementation
407	//===----------------------------------------------------------------------===//
408
409	/// Returns the IdDeclInfo associated to the DeclarationName.
410	/// It creates a new IdDeclInfo if one was not created before for this id.
411	IdentifierResolver::IdDeclInfo &
412	IdentifierResolver::IdDeclInfoMap::operator[](DeclarationName Name) {
413	void *Ptr = Name.getFETokenInfo();
414
415	if (Ptr) return *toIdDeclInfo(Ptr);
416
417	if (CurIndex == POOL_SIZE) {
418	CurPool = new IdDeclInfoPool (CurPool);
419	CurIndex = `0`;
420	}
421	IdDeclInfo *IDI = &CurPool->Pool[CurIndex];
422	Name.setFETokenInfo(reinterpret_cast<void*>(
423	reinterpret_cast<uintptr_t>(IDI) \| `0x1`)
424	);
425	++CurIndex;
426	return *IDI;
427	}
428
429	void IdentifierResolver::iterator::incrementSlowCase() {
430	NamedDecl D = *this;
431	void *InfoPtr = D->getDeclName().getFETokenInfo();
432	assert(!isDeclPtr(InfoPtr) && "Decl with wrong id ?");
433	IdDeclInfo *Info = toIdDeclInfo(Ptr: InfoPtr);
434
435	BaseIter I = getIterator();
436	if (I != Info->decls_begin())
437	*this = iterator (I-`1`);
438	else // No more decls.
439	*this = iterator ();
440	}
441

source code of clang/lib/Sema/IdentifierResolver.cpp