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office-gobmx/compilerplugins/clang/salcall.cxx
Stephan Bergmann bd10851e9e Adapt compilerplugins to Clang 18 trunk isPure -> isPureVirtual rename 
...<e90e43fb9c>
"[Clang][NFC] Rename CXXMethodDecl::isPure -> is VirtualPure"

Change-Id: I27b7cd40c84c71804bef396d0bff4ee2683cb3af
Reviewed-on: https://gerrit.libreoffice.org/c/core/+/162345
Tested-by: Jenkins
Reviewed-by: Stephan Bergmann <stephan.bergmann@allotropia.de>
2024-01-21 19:41:28 +01:00

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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*/
#include "plugin.hxx"
#include "check.hxx"
#include "compat.hxx"
#include "functionaddress.hxx"
#include <algorithm>
#include <cassert>
#include <set>
#include <utility>
#include <vector>
// The SAL_CALL function annotation is only necessary on our outward
// facing C++ ABI, anywhere else it is just cargo-cult.
//
//TODO: To find inconsistencies like
//
// template<typename> struct S { void f(); }; // #1
// template<typename T> void S<T>::f() {} // #2
// template void SAL_CALL S<void>::f();
//
// VisitFunctionDecl would need to also visit explicit instantiations, by letting
// shouldVisitTemplateInstantiations return true and returning from VisitFunctionDecl early iff
// decl->getTemplateSpecializationKind() == TSK_ImplicitInstantiation. However, an instantiated
// FunctionDecl is created in TemplateDeclInstantiator::VisitCXXMethodDecl by copying information
// (including source locations) from the declaration at #1, and later modified in
// Sema::InstantiateFunctionDefinition with some source location information from the definition at
// #2. That means that the source scanning in isSalCallFunction below would be thoroughly confused
// and break. (This happens for both explicit and implicit template instantiations, which is the
// reason why calls to isSalCallFunction make sure to not call it with any FunctionDecls
// representing such template instantiations.)
namespace
{
//static bool startswith(const std::string& rStr, const char* pSubStr)
//{
// return rStr.compare(0, strlen(pSubStr), pSubStr) == 0;
//}
CXXMethodDecl const* getTemplateInstantiationPattern(CXXMethodDecl const* decl)
{
auto const p = decl->getTemplateInstantiationPattern();
return p == nullptr ? decl : cast<CXXMethodDecl>(p);
}
class SalCall final : public loplugin::FunctionAddress<loplugin::FilteringRewritePlugin<SalCall>>
{
public:
explicit SalCall(loplugin::InstantiationData const& data)
: FunctionAddress(data)
{
}
virtual void run() override
{
if (TraverseDecl(compiler.getASTContext().getTranslationUnitDecl()))
{
auto const& addressOfSet = getFunctionsWithAddressTaken();
for (auto const decl : m_decls)
{
if (addressOfSet.find(decl->getCanonicalDecl()) == addressOfSet.end())
{
handleFunctionDecl(decl);
}
}
}
}
bool VisitFunctionDecl(FunctionDecl const*);
private:
void handleFunctionDecl(FunctionDecl const* decl);
bool rewrite(SourceLocation);
bool isSalCallFunction(FunctionDecl const* functionDecl, SourceLocation* pLoc = nullptr);
std::set<FunctionDecl const*> m_decls;
};
bool SalCall::VisitFunctionDecl(FunctionDecl const* decl)
{
if (ignoreLocation(decl))
return true;
// ignore template stuff
if (decl->getTemplatedKind() != clang::FunctionDecl::TK_NonTemplate)
return true;
auto recordDecl = dyn_cast<CXXRecordDecl>(decl->getDeclContext());
if (recordDecl
&& (recordDecl->getTemplateSpecializationKind() != TSK_Undeclared
|| recordDecl->isDependentContext()))
{
return true;
}
auto canonicalDecl = decl->getCanonicalDecl();
// ignore UNO implementations
if (isInUnoIncludeFile(
compiler.getSourceManager().getSpellingLoc(canonicalDecl->getLocation())))
return true;
SourceLocation rewriteLoc;
SourceLocation rewriteCanonicalLoc;
bool bDeclIsSalCall = isSalCallFunction(decl, &rewriteLoc);
bool bCanonicalDeclIsSalCall = isSalCallFunction(canonicalDecl, &rewriteCanonicalLoc);
// first, check for consistency, so we don't trip ourselves up on Linux, where we normally run the plugin
if (canonicalDecl != decl)
{
if (bCanonicalDeclIsSalCall)
; // this is fine, the actual definition have or not have SAL_CALL, and MSVC is fine with it
else if (bDeclIsSalCall)
{
// not fine
report(DiagnosticsEngine::Warning, "SAL_CALL inconsistency", decl->getLocation())
<< decl->getSourceRange();
report(DiagnosticsEngine::Note, "SAL_CALL inconsistency", canonicalDecl->getLocation())
<< canonicalDecl->getSourceRange();
return true;
}
}
auto methodDecl = dyn_cast<CXXMethodDecl>(canonicalDecl);
if (methodDecl)
{
for (auto iter = methodDecl->begin_overridden_methods();
iter != methodDecl->end_overridden_methods(); ++iter)
{
const CXXMethodDecl* overriddenMethod
= getTemplateInstantiationPattern(*iter)->getCanonicalDecl();
if (bCanonicalDeclIsSalCall != isSalCallFunction(overriddenMethod))
{
report(DiagnosticsEngine::Warning, "SAL_CALL inconsistency",
methodDecl->getLocation())
<< methodDecl->getSourceRange();
report(DiagnosticsEngine::Note, "SAL_CALL inconsistency",
overriddenMethod->getLocation())
<< overriddenMethod->getSourceRange();
return true;
}
}
}
if (!bCanonicalDeclIsSalCall)
return true;
if (!decl->isThisDeclarationADefinition() && !(methodDecl && compat::isPureVirtual(methodDecl)))
return true;
m_decls.insert(decl);
return true;
}
void SalCall::handleFunctionDecl(FunctionDecl const* decl)
{
// some base classes are overridden by sub-classes which override both the base-class and a UNO class
if (auto recordDecl = dyn_cast<CXXRecordDecl>(decl->getDeclContext()))
{
auto dc = loplugin::DeclCheck(recordDecl);
if (dc.Class("OProxyAggregation").Namespace("comphelper").GlobalNamespace()
|| dc.Class("OComponentProxyAggregationHelper")
.Namespace("comphelper")
.GlobalNamespace()
|| dc.Class("SvxShapeMaster").GlobalNamespace()
|| dc.Class("ListBoxAccessibleBase").Namespace("accessibility").GlobalNamespace()
|| dc.Class("AsyncEventNotifierBase").Namespace("comphelper").GlobalNamespace()
|| dc.Class("ODescriptor")
.Namespace("sdbcx")
.Namespace("connectivity")
.GlobalNamespace()
|| dc.Class("IController").Namespace("dbaui").GlobalNamespace()
|| dc.Class("ORowSetBase").Namespace("dbaccess").GlobalNamespace()
|| dc.Class("OComponentAdapterBase").Namespace("bib").GlobalNamespace()
|| dc.Class("IEventProcessor").Namespace("comphelper").GlobalNamespace()
|| dc.Class("SvxUnoTextBase").GlobalNamespace()
|| dc.Class("OInterfaceContainer").Namespace("frm").GlobalNamespace()
|| dc.Class("AccessibleComponentBase").Namespace("accessibility").GlobalNamespace()
|| dc.Class("ContextHandler2Helper")
.Namespace("core")
.Namespace("oox")
.GlobalNamespace()
|| dc.Class("AccessibleStaticTextBase").Namespace("accessibility").GlobalNamespace()
|| dc.Class("OCommonPicker").Namespace("svt").GlobalNamespace()
|| dc.Class("VbaDocumentBase").GlobalNamespace()
|| dc.Class("VbaPageSetupBase").GlobalNamespace()
|| dc.Class("ScVbaControl").GlobalNamespace()
)
return;
}
auto canonicalDecl = decl->getCanonicalDecl();
// if any of the overridden methods are SAL_CALL, we should be too
if (auto methodDecl = dyn_cast<CXXMethodDecl>(canonicalDecl))
{
for (auto iter = methodDecl->begin_overridden_methods();
iter != methodDecl->end_overridden_methods(); ++iter)
{
const CXXMethodDecl* overriddenMethod
= getTemplateInstantiationPattern(*iter)->getCanonicalDecl();
if (isSalCallFunction(overriddenMethod))
return;
}
}
SourceLocation rewriteLoc;
SourceLocation rewriteCanonicalLoc;
bool bDeclIsSalCall = isSalCallFunction(decl, &rewriteLoc);
isSalCallFunction(canonicalDecl, &rewriteCanonicalLoc);
bool bOK = rewrite(rewriteLoc);
if (bOK && canonicalDecl != decl)
{
bOK = rewrite(rewriteCanonicalLoc);
}
if (bOK)
return;
if (bDeclIsSalCall)
{
report(DiagnosticsEngine::Warning, "SAL_CALL unnecessary here",
rewriteLoc.isValid() ? rewriteLoc : decl->getLocation())
<< decl->getSourceRange();
}
if (canonicalDecl != decl)
{
report(DiagnosticsEngine::Warning, "SAL_CALL unnecessary here", rewriteCanonicalLoc)
<< canonicalDecl->getSourceRange();
if (!bDeclIsSalCall)
{
report(DiagnosticsEngine::Note, "defined here (without SAL_CALL decoration)",
decl->getLocation())
<< decl->getSourceRange();
}
}
}
//TODO: This doesn't handle all possible cases of macro usage (and possibly never will be able to),
// just what is encountered in practice:
bool SalCall::isSalCallFunction(FunctionDecl const* functionDecl, SourceLocation* pLoc)
{
assert(!functionDecl->isTemplateInstantiation());
//TODO: It appears that FunctionDecls representing explicit template specializations have the
// same issue as those representing (implicit or explicit) instantiations, namely that their
// data (including relevant source locations) is an incoherent combination of data from the
// original template declaration and the later specialization definition. For example, for the
// OValueLimitedType<double>::registerProperties specialization at
// forms/source/xforms/datatyperepository.cxx:241, the FunctionDecl (which is even considered
// canonic) representing the base-class function overridden by ODecimalType::registerProperties
// (forms/source/xforms/datatypes.hxx:299) is dumped as
//
// CXXMethodDecl <forms/source/xforms/datatypes.hxx:217:9, col:54>
// forms/source/xforms/datatyperepository.cxx:242:37 registerProperties 'void (void)' virtual
//
// mixing the source range ("datatypes.hxx:217:9, col:54") from the original declaration with
// the name location ("datatyperepository.cxx:242:37") from the explicit specialization. Just
// give up for now and assume no "SAL_CALL" is present:
if (functionDecl->getTemplateSpecializationKind() == TSK_ExplicitSpecialization)
{
return false;
}
SourceManager& SM = compiler.getSourceManager();
std::vector<SourceRange> ranges;
SourceLocation startLoc;
SourceLocation endLoc;
bool noReturnType = isa<CXXConstructorDecl>(functionDecl)
|| isa<CXXDestructorDecl>(functionDecl)
|| isa<CXXConversionDecl>(functionDecl);
bool startAfterReturnType = !noReturnType;
if (startAfterReturnType)
{
// For functions that do have a return type, start searching for "SAL_CALL" after the return
// type (which for SAL_CALL functions on Windows will be an AttributedTypeLoc, which the
// implementation of FunctionDecl::getReturnTypeSourceRange does not take into account, so
// do that here explicitly):
auto const TSI = functionDecl->getTypeSourceInfo();
if (TSI == nullptr)
{
if (isDebugMode())
{
report(DiagnosticsEngine::Fatal, "TODO: unexpected failure #1, needs investigation",
functionDecl->getLocation())
<< functionDecl->getSourceRange();
}
return false;
}
auto TL = TSI->getTypeLoc().IgnoreParens();
if (auto ATL = TL.getAs<AttributedTypeLoc>())
{
TL = ATL.getModifiedLoc();
}
auto const FTL = TL.getAs<FunctionTypeLoc>();
if (!FTL)
{
// Happens when a function declaration uses a typedef for the function type, as in
//
// SAL_JNI_EXPORT javaunohelper::detail::Func_bootstrap
// Java_com_sun_star_comp_helper_Bootstrap_cppuhelper_1bootstrap;
//
// in javaunohelper/source/juhx-export-functions.hxx.
//TODO: check the typedef for mention of "SAL_CALL" (and also check for usage of such
// typedefs in the !startAfterReturnType case below)
return false;
}
startLoc = FTL.getReturnLoc().getEndLoc();
while (SM.isMacroArgExpansion(startLoc, &startLoc))
{
}
// Stop searching for "SAL_CALL" at the start of the function declaration's name (for
// qualified names this will point after the qualifiers, but needlessly including those in
// the search should be harmless---modulo issues with using "SAL_CALL" as the name of a
// function-like macro parameter as discussed below):
endLoc = functionDecl->getNameInfo().getBeginLoc();
while (SM.isMacroArgExpansion(endLoc, &endLoc))
{
}
while (endLoc.isMacroID() && SM.isAtStartOfImmediateMacroExpansion(endLoc, &endLoc))
{
}
endLoc = SM.getSpellingLoc(endLoc);
auto const slEnd = Lexer::getLocForEndOfToken(startLoc, 0, SM, compiler.getLangOpts());
if (slEnd.isValid())
{
// startLoc is either non-macro, or at end of macro; one source range from startLoc to
// endLoc:
startLoc = slEnd;
while (startLoc.isMacroID() && SM.isAtEndOfImmediateMacroExpansion(startLoc, &startLoc))
{
}
startLoc = SM.getSpellingLoc(startLoc);
if (startLoc.isValid() && endLoc.isValid() && startLoc != endLoc
&& !SM.isBeforeInTranslationUnit(startLoc, endLoc))
{
// Happens for uses of trailing return type (in which case starting instead at the
// start of the function declaration should be fine), but also for cases like
//
// void (*f())();
//
// where the function name is within the function type (TODO: in which case starting
// at the start can erroneously pick up the "SAL_CALL" from the returned pointer-to-
// function type in cases like
//
// void SAL_CALL (*f())();
//
// that are hopefully rare):
startAfterReturnType = false;
}
}
else
{
// startLoc is within a macro body; two source ranges, first is the remainder of the
// corresponding macro definition's replacement text, second is from after the macro
// invocation to endLoc, unless endLoc is already in the first range:
//TODO: If the macro is a function-like macro with a parameter named "SAL_CALL", uses of
// that parameter in the remainder of the replacement text will be false positives.
assert(SM.isMacroBodyExpansion(startLoc));
auto const startLoc2 = compat::getImmediateExpansionRange(SM, startLoc).second;
auto name = Lexer::getImmediateMacroName(startLoc, SM, compiler.getLangOpts());
while (compat::starts_with(name, "\\\n"))
{
name = name.drop_front(2);
while (!name.empty()
&& (name.front() == ' ' || name.front() == '\t' || name.front() == '\n'
|| name.front() == '\v' || name.front() == '\f'))
{
name = name.drop_front(1);
}
}
auto const MI = compiler.getPreprocessor()
.getMacroDefinitionAtLoc(&compiler.getASTContext().Idents.get(name),
SM.getSpellingLoc(startLoc))
.getMacroInfo();
assert(MI != nullptr);
auto endLoc1 = MI->getDefinitionEndLoc();
assert(endLoc1.isFileID());
endLoc1 = Lexer::getLocForEndOfToken(endLoc1, 0, SM, compiler.getLangOpts());
startLoc = Lexer::getLocForEndOfToken(SM.getSpellingLoc(startLoc), 0, SM,
compiler.getLangOpts());
if (!SM.isPointWithin(endLoc, startLoc, endLoc1))
{
ranges.emplace_back(startLoc, endLoc1);
startLoc = Lexer::getLocForEndOfToken(SM.getSpellingLoc(startLoc2), 0, SM,
compiler.getLangOpts());
}
}
}
if (!startAfterReturnType)
{
// Stop searching for "SAL_CALL" at the start of the function declaration's name (for
// qualified names this will point after the qualifiers, but needlessly including those in
// the search should be harmless):
endLoc = functionDecl->getNameInfo().getBeginLoc();
while (endLoc.isMacroID() && SM.isAtStartOfImmediateMacroExpansion(endLoc, &endLoc))
{
}
SourceRange macroRange;
if (SM.isMacroBodyExpansion(endLoc))
{
auto name = Lexer::getImmediateMacroName(endLoc, SM, compiler.getLangOpts());
while (compat::starts_with(name, "\\\n"))
{
name = name.drop_front(2);
while (!name.empty()
&& (name.front() == ' ' || name.front() == '\t' || name.front() == '\n'
|| name.front() == '\v' || name.front() == '\f'))
{
name = name.drop_front(1);
}
}
auto const MI = compiler.getPreprocessor()
.getMacroDefinitionAtLoc(&compiler.getASTContext().Idents.get(name),
SM.getSpellingLoc(endLoc))
.getMacroInfo();
assert(MI != nullptr);
macroRange = SourceRange(MI->getDefinitionLoc(), MI->getDefinitionEndLoc());
if (isDebugMode() && macroRange.isInvalid())
{
report(DiagnosticsEngine::Fatal, "TODO: unexpected failure #4, needs investigation",
functionDecl->getLocation())
<< functionDecl->getSourceRange();
}
}
#if defined _WIN32
auto const macroExpansion = SM.getExpansionLoc(endLoc);
#endif
endLoc = SM.getSpellingLoc(endLoc);
// Ctors/dtors/conversion functions don't have a return type, start searching for "SAL_CALL"
// at the start of the function declaration:
startLoc = functionDecl->getSourceRange().getBegin();
while (startLoc.isMacroID()
&& !(macroRange.isValid()
&& SM.isPointWithin(SM.getSpellingLoc(startLoc), macroRange.getBegin(),
macroRange.getEnd()))
&& SM.isAtStartOfImmediateMacroExpansion(startLoc, &startLoc))
{
}
#if !defined _WIN32
auto const macroStartLoc = startLoc;
#endif
startLoc = SM.getSpellingLoc(startLoc);
#if defined _WIN32
if (macroRange.isValid()
&& !SM.isPointWithin(startLoc, macroRange.getBegin(), macroRange.getEnd()))
{
// endLoc is within a macro body but startLoc is not; two source ranges, first is from
// startLoc to the macro invocation, second is the leading part of the corresponding
// macro definition's replacement text:
ranges.emplace_back(startLoc, macroExpansion);
startLoc = macroRange.getBegin();
}
#else
// When the SAL_CALL macro expands to nothing, it may even precede the function
// declaration's source range, so go back one token (unless the declaration is known to
// start with a token that must precede a possible "SAL_CALL", like "virtual" or
// "explicit"):
//TODO: this will produce false positives if the declaration is immediately preceded by a
// macro definition whose replacement text ends in "SAL_CALL"
if (noReturnType
&& !(functionDecl->isVirtualAsWritten()
|| (isa<CXXConstructorDecl>(functionDecl)
&& cast<CXXConstructorDecl>(functionDecl)->getExplicitSpecifier().isExplicit())
|| (isa<CXXConversionDecl>(functionDecl)
&& cast<CXXConversionDecl>(functionDecl)
->getExplicitSpecifier()
.isExplicit())))
{
SourceLocation endLoc1;
if (macroStartLoc.isMacroID()
&& SM.isAtStartOfImmediateMacroExpansion(macroStartLoc, &endLoc1))
{
// startLoc is at the start of a macro body; two source ranges, first one is looking
// backwards one token from the call site of the macro:
auto startLoc1 = endLoc1;
for (;;)
{
startLoc1 = Lexer::GetBeginningOfToken(startLoc1.getLocWithOffset(-1), SM,
compiler.getLangOpts());
auto const s = StringRef(
SM.getCharacterData(startLoc1),
Lexer::MeasureTokenLength(startLoc1, SM, compiler.getLangOpts()));
// When looking backward at least through a function-like macro replacement like
//
// | foo\ |
// | barbaz##X |
//
// starting at "barbaz" in the second line, the next token reported will start at "\"
// in the first line and include the intervening spaces and (part of? looks like an
// error in Clang) "barbaz", so just skip any tokens starting with backslash-newline
// when looking backwards here, without even trying to look at their content:
if (!(s.empty() || compat::starts_with(s, "/*") || compat::starts_with(s, "//")
|| compat::starts_with(s, "\\\n")))
{
break;
}
}
ranges.emplace_back(startLoc1, endLoc1);
}
else
{
for (;;)
{
startLoc = Lexer::GetBeginningOfToken(startLoc.getLocWithOffset(-1), SM,
compiler.getLangOpts());
auto const s = StringRef(
SM.getCharacterData(startLoc),
Lexer::MeasureTokenLength(startLoc, SM, compiler.getLangOpts()));
// When looking backward at least through a function-like macro replacement like
//
// | foo\ |
// | barbaz##X |
//
// starting at "barbaz" in the second line, the next token reported will start at "\"
// in the first line and include the intervening spaces and (part of? looks like an
// error in Clang) "barbaz", so just skip any tokens starting with backslash-newline
// when looking backwards here, without even trying to look at their content:
if (!(s.empty() || compat::starts_with(s, "/*") || compat::starts_with(s, "//")
|| compat::starts_with(s, "\\\n")))
{
break;
}
}
}
}
#endif
}
ranges.emplace_back(startLoc, endLoc);
for (auto const& range : ranges)
{
if (range.isInvalid())
{
if (isDebugMode())
{
report(DiagnosticsEngine::Fatal, "TODO: unexpected failure #2, needs investigation",
functionDecl->getLocation())
<< functionDecl->getSourceRange();
}
return false;
}
if (isDebugMode() && range.getBegin() != range.getEnd()
&& !SM.isBeforeInTranslationUnit(range.getBegin(), range.getEnd()))
{
report(DiagnosticsEngine::Fatal, "TODO: unexpected failure #3, needs investigation",
functionDecl->getLocation())
<< functionDecl->getSourceRange();
}
for (auto loc = range.getBegin(); SM.isBeforeInTranslationUnit(loc, range.getEnd());)
{
unsigned n = Lexer::MeasureTokenLength(loc, SM, compiler.getLangOpts());
auto s = StringRef(compiler.getSourceManager().getCharacterData(loc), n);
while (compat::starts_with(s, "\\\n"))
{
s = s.drop_front(2);
while (!s.empty()
&& (s.front() == ' ' || s.front() == '\t' || s.front() == '\n'
|| s.front() == '\v' || s.front() == '\f'))
{
s = s.drop_front(1);
}
}
if (s == "SAL_CALL")
{
if (pLoc)
*pLoc = loc;
return true;
}
loc = loc.getLocWithOffset(std::max<unsigned>(n, 1));
}
}
return false;
}
bool SalCall::rewrite(SourceLocation locBegin)
{
if (!rewriter)
return false;
if (!locBegin.isValid())
return false;
auto locEnd = locBegin.getLocWithOffset(8);
if (!locEnd.isValid())
return false;
SourceRange range(locBegin, locEnd);
if (!replaceText(locBegin, 9, ""))
return false;
return true;
}
static loplugin::Plugin::Registration<SalCall> reg("salcall", true);
}
/* vim:set shiftwidth=4 softtabstop=4 expandtab cinoptions=b1,g0,N-s cinkeys+=0=break: */
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