CallDescriptionTest.cpp
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//===- unittests/StaticAnalyzer/CallDescriptionTest.cpp -------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "Reusables.h"
#include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h"
#include "clang/Tooling/Tooling.h"
#include "gtest/gtest.h"
namespace clang {
namespace ento {
namespace {
// A wrapper around CallDescriptionMap<bool> that allows verifying that
// all functions have been found. This is needed because CallDescriptionMap
// isn't supposed to support iteration.
class ResultMap {
size_t Found, Total;
CallDescriptionMap<bool> Impl;
public:
ResultMap(std::initializer_list<std::pair<CallDescription, bool>> Data)
: Found(0),
Total(std::count_if(Data.begin(), Data.end(),
[](const std::pair<CallDescription, bool> &Pair) {
return Pair.second == true;
})),
Impl(std::move(Data)) {}
const bool *lookup(const CallEvent &Call) {
const bool *Result = Impl.lookup(Call);
// If it's a function we expected to find, remember that we've found it.
if (Result && *Result)
++Found;
return Result;
}
// Fail the test if we haven't found all the true-calls we were looking for.
~ResultMap() { EXPECT_EQ(Found, Total); }
};
// Scan the code body for call expressions and see if we find all calls that
// we were supposed to find ("true" in the provided ResultMap) and that we
// don't find the ones that we weren't supposed to find
// ("false" in the ResultMap).
class CallDescriptionConsumer : public ExprEngineConsumer {
ResultMap &RM;
void performTest(const Decl *D) {
using namespace ast_matchers;
if (!D->hasBody())
return;
const CallExpr *CE = findNode<CallExpr>(D, callExpr());
const StackFrameContext *SFC =
Eng.getAnalysisDeclContextManager().getStackFrame(D);
ProgramStateRef State = Eng.getInitialState(SFC);
CallEventRef<> Call =
Eng.getStateManager().getCallEventManager().getCall(CE, State, SFC);
const bool *LookupResult = RM.lookup(*Call);
// Check that we've found the function in the map
// with the correct description.
EXPECT_TRUE(LookupResult && *LookupResult);
// ResultMap is responsible for making sure that we've found *all* calls.
}
public:
CallDescriptionConsumer(CompilerInstance &C,
ResultMap &RM)
: ExprEngineConsumer(C), RM(RM) {}
bool HandleTopLevelDecl(DeclGroupRef DG) override {
for (const auto *D : DG)
performTest(D);
return true;
}
};
class CallDescriptionAction : public ASTFrontendAction {
ResultMap RM;
public:
CallDescriptionAction(
std::initializer_list<std::pair<CallDescription, bool>> Data)
: RM(Data) {}
std::unique_ptr<ASTConsumer> CreateASTConsumer(CompilerInstance &Compiler,
StringRef File) override {
return std::make_unique<CallDescriptionConsumer>(Compiler, RM);
}
};
TEST(CallEvent, CallDescription) {
// Test simple name matching.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{"bar"}, false}, // false: there's no call to 'bar' in this code.
{{"foo"}, true}, // true: there's a call to 'foo' in this code.
})), "void foo(); void bar() { foo(); }"));
// Test arguments check.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{"foo", 1}, true},
{{"foo", 2}, false},
})), "void foo(int); void foo(int, int); void bar() { foo(1); }"));
// Test lack of arguments check.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{"foo", None}, true},
{{"foo", 2}, false},
})), "void foo(int); void foo(int, int); void bar() { foo(1); }"));
// Test qualified names.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{{"std", "basic_string", "c_str"}}, true},
})),
"namespace std { inline namespace __1 {"
" template<typename T> class basic_string {"
" public:"
" T *c_str();"
" };"
"}}"
"void foo() {"
" using namespace std;"
" basic_string<char> s;"
" s.c_str();"
"}"));
// A negative test for qualified names.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{{"foo", "bar"}}, false},
{{{"bar", "foo"}}, false},
{{"foo"}, true},
})), "void foo(); struct bar { void foo(); }; void test() { foo(); }"));
// Test CDF_MaybeBuiltin - a flag that allows matching weird builtins.
EXPECT_TRUE(tooling::runToolOnCode(
std::unique_ptr<CallDescriptionAction>(new CallDescriptionAction({
{{"memset", 3}, false},
{{CDF_MaybeBuiltin, "memset", 3}, true}
})),
"void foo() {"
" int x;"
" __builtin___memset_chk(&x, 0, sizeof(x),"
" __builtin_object_size(&x, 0));"
"}"));
}
} // namespace
} // namespace ento
} // namespace clang