cppcheck/test/testvalueflow.cpp

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/*
* Cppcheck - A tool for static C/C++ code analysis
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* Copyright (C) 2007-2021 Cppcheck team.
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
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#include "library.h"
#include "platform.h"
#include "settings.h"
#include "testsuite.h"
#include "token.h"
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#include "tokenize.h"
#include "valueflow.h"
#include <algorithm>
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#include <cmath>
#include <cstdint>
#include <cstring>
#include <functional>
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#include <list>
#include <map>
#include <simplecpp.h>
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#include <string>
#include <utility>
#include <vector>
class TestValueFlow : public TestFixture {
public:
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TestValueFlow() : TestFixture("TestValueFlow") {}
private:
Settings settings;
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void run() OVERRIDE {
// strcpy, abort cfg
const char cfg[] = "<?xml version=\"1.0\"?>\n"
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"<def>\n"
" <function name=\"strcpy\"> <arg nr=\"1\"><not-null/></arg> </function>\n"
" <function name=\"abort\"> <noreturn>true</noreturn> </function>\n" // abort is a noreturn function
"</def>";
settings.library.loadxmldata(cfg, sizeof(cfg));
LOAD_LIB_2(settings.library, "std.cfg");
TEST_CASE(valueFlowNumber);
TEST_CASE(valueFlowString);
TEST_CASE(valueFlowPointerAlias);
TEST_CASE(valueFlowLifetime);
TEST_CASE(valueFlowArrayElement);
TEST_CASE(valueFlowMove);
TEST_CASE(valueFlowBitAnd);
TEST_CASE(valueFlowRightShift);
TEST_CASE(valueFlowCalculations);
TEST_CASE(valueFlowSizeof);
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TEST_CASE(valueFlowErrorPath);
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TEST_CASE(valueFlowBeforeCondition);
TEST_CASE(valueFlowBeforeConditionAndAndOrOrGuard);
TEST_CASE(valueFlowBeforeConditionAssignIncDec);
TEST_CASE(valueFlowBeforeConditionFunctionCall);
TEST_CASE(valueFlowBeforeConditionGlobalVariables);
TEST_CASE(valueFlowBeforeConditionGoto);
TEST_CASE(valueFlowBeforeConditionIfElse);
TEST_CASE(valueFlowBeforeConditionLoop);
TEST_CASE(valueFlowBeforeConditionMacro);
TEST_CASE(valueFlowBeforeConditionSizeof);
TEST_CASE(valueFlowBeforeConditionSwitch);
TEST_CASE(valueFlowBeforeConditionTernaryOp);
TEST_CASE(valueFlowBeforeConditionForward);
TEST_CASE(valueFlowBeforeConditionConstructor);
TEST_CASE(valueFlowAfterAssign);
TEST_CASE(valueFlowAfterSwap);
TEST_CASE(valueFlowAfterCondition);
TEST_CASE(valueFlowAfterConditionExpr);
TEST_CASE(valueFlowAfterConditionSeveralNot);
TEST_CASE(valueFlowForwardCompoundAssign);
TEST_CASE(valueFlowForwardCorrelatedVariables);
TEST_CASE(valueFlowForwardModifiedVariables);
TEST_CASE(valueFlowForwardFunction);
TEST_CASE(valueFlowForwardTernary);
TEST_CASE(valueFlowForwardLambda);
TEST_CASE(valueFlowForwardTryCatch);
TEST_CASE(valueFlowForwardInconclusiveImpossible);
TEST_CASE(valueFlowForwardConst);
TEST_CASE(valueFlowFwdAnalysis);
TEST_CASE(valueFlowSwitchVariable);
TEST_CASE(valueFlowForLoop);
TEST_CASE(valueFlowSubFunction);
TEST_CASE(valueFlowFunctionReturn);
TEST_CASE(valueFlowFunctionDefaultParameter);
TEST_CASE(knownValue);
TEST_CASE(valueFlowSizeofForwardDeclaredEnum);
TEST_CASE(valueFlowGlobalVar);
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TEST_CASE(valueFlowGlobalConstVar);
TEST_CASE(valueFlowGlobalStaticVar);
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TEST_CASE(valueFlowInlineAssembly);
TEST_CASE(valueFlowSameExpression);
TEST_CASE(valueFlowUninit);
TEST_CASE(valueFlowConditionExpressions);
TEST_CASE(valueFlowContainerSize);
TEST_CASE(valueFlowDynamicBufferSize);
TEST_CASE(valueFlowSafeFunctionParameterValues);
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TEST_CASE(valueFlowUnknownFunctionReturn);
TEST_CASE(valueFlowPointerAliasDeref);
Fix crashes in valueflow (#2236) * Fix crashes in valueflow http://cppcheck1.osuosl.org:8000/crash.html For instance in http://cppcheck1.osuosl.org:8000/styx ``` ==19651==ERROR: AddressSanitizer: SEGV on unknown address 0x00000000001c (pc 0x556f21abc3df bp 0x7ffc140d2720 sp 0x7ffc140d2710 T0) ==19651==The signal is caused by a READ memory access. ==19651==Hint: address points to the zero page. #0 0x556f21abc3de in Variable::isGlobal() const ../lib/symboldatabase.h:342 #1 0x556f221f801a in valueFlowForwardVariable ../lib/valueflow.cpp:2471 #2 0x556f22208130 in valueFlowForward ../lib/valueflow.cpp:3204 #3 0x556f221e9e14 in valueFlowReverse ../lib/valueflow.cpp:1892 #4 0x556f221f1a43 in valueFlowBeforeCondition ../lib/valueflow.cpp:2200 #5 0x556f2223dbb5 in ValueFlow::setValues(TokenList*, SymbolDatabase*, ErrorLogger*, Settings const*) ../lib/valueflow.cpp:6521 #6 0x556f220e5991 in Tokenizer::simplifyTokens1(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/tokenize.cpp:2342 #7 0x556f21d8d066 in CppCheck::checkFile(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::istream&) ../lib/cppcheck.cpp:508 #8 0x556f21d84cd3 in CppCheck::check(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/cppcheck.cpp:192 #9 0x556f21a28796 in CppCheckExecutor::check_internal(CppCheck&, int, char const* const*) ../cli/cppcheckexecutor.cpp:884 #10 0x556f21a24be8 in CppCheckExecutor::check(int, char const* const*) ../cli/cppcheckexecutor.cpp:198 #11 0x556f22313063 in main ../cli/main.cpp:95 ``` * Add test case for crash in valueflow
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TEST_CASE(valueFlowCrashIncompleteCode);
TEST_CASE(valueFlowCrash);
TEST_CASE(valueFlowHang);
TEST_CASE(valueFlowCrashConstructorInitialization);
TEST_CASE(valueFlowUnknownMixedOperators);
TEST_CASE(valueFlowIdempotent);
TEST_CASE(valueFlowUnsigned);
TEST_CASE(valueFlowMod);
TEST_CASE(valueFlowNotNull);
TEST_CASE(valueFlowSymbolic);
TEST_CASE(valueFlowSymbolicIdentity);
TEST_CASE(valueFlowSmartPointer);
}
static bool isNotTokValue(const ValueFlow::Value &val) {
return !val.isTokValue();
}
static bool isNotLifetimeValue(const ValueFlow::Value& val) {
return !val.isLifetimeValue();
}
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static bool isNotUninitValue(const ValueFlow::Value& val) {
return !val.isUninitValue();
}
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static bool isNotPossible(const ValueFlow::Value& val) {
return !val.isPossible();
}
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static bool isNotKnown(const ValueFlow::Value& val) {
return !val.isKnown();
}
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static bool isNotInconclusive(const ValueFlow::Value& val) {
return !val.isInconclusive();
}
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static bool isNotImpossible(const ValueFlow::Value& val) {
return !val.isImpossible();
}
#define testValueOfXKnown(...) testValueOfXKnown_(__FILE__, __LINE__, __VA_ARGS__)
bool testValueOfXKnown_(const char* file, int line, const char code[], unsigned int linenr, int value) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& val:tok->values()) {
if (val.isSymbolicValue())
continue;
if (val.isKnown() && val.intvalue == value)
return true;
}
}
}
return false;
}
bool testValueOfXKnown_(const char* file, int line, const char code[], unsigned int linenr, const std::string& expr, int value) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token* tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& val : tok->values()) {
if (!val.isSymbolicValue())
continue;
if (val.isKnown() && val.intvalue == value && val.tokvalue->expressionString() == expr)
return true;
}
}
}
return false;
}
#define testValueOfXImpossible(...) testValueOfXImpossible_(__FILE__, __LINE__, __VA_ARGS__)
bool testValueOfXImpossible_(const char* file, int line, const char code[], unsigned int linenr, int value) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& val:tok->values()) {
if (val.isSymbolicValue())
continue;
if (val.isImpossible() && val.intvalue == value)
return true;
}
}
}
return false;
}
bool testValueOfXImpossible_(const char* file, int line, const char code[], unsigned int linenr, const std::string& expr, int value)
{
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token* tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& val : tok->values()) {
if (!val.isSymbolicValue())
continue;
if (val.isImpossible() && val.intvalue == value && val.tokvalue->expressionString() == expr)
return true;
}
}
}
return false;
}
#define testValueOfXInconclusive(code, linenr, value) testValueOfXInconclusive_(code, linenr, value, __FILE__, __LINE__)
bool testValueOfXInconclusive_(const char code[], unsigned int linenr, int value, const char* file, int line) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& val:tok->values()) {
if (val.isSymbolicValue())
continue;
if (val.isInconclusive() && val.intvalue == value)
return true;
}
}
}
return false;
}
#define testValueOfX(...) testValueOfX_(__FILE__, __LINE__, __VA_ARGS__)
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, int value) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.isIntValue() && !v.isImpossible() && v.intvalue == value)
return true;
}
}
}
return false;
}
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, const std::string& expr, int value)
{
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token* tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value& v : tok->values()) {
if (v.isSymbolicValue() && !v.isImpossible() && v.intvalue == value &&
v.tokvalue->expressionString() == expr)
return true;
}
}
}
return false;
}
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, float value, float diff) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.isFloatValue() && !v.isImpossible() && v.floatValue >= value - diff &&
v.floatValue <= value + diff)
return true;
}
}
}
return false;
}
#define getErrorPathForX(code, linenr) getErrorPathForX_(code, linenr, __FILE__, __LINE__)
std::string getErrorPathForX_(const char code[], unsigned int linenr, const char* file, int line) {
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// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
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for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() != "x" || tok->linenr() != linenr)
continue;
std::ostringstream ostr;
for (const ValueFlow::Value &v : tok->values()) {
for (const ValueFlow::Value::ErrorPathItem &ep : v.errorPath) {
const Token *eptok = ep.first;
const std::string &msg = ep.second;
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ostr << eptok->linenr() << ',' << msg << '\n';
}
}
return ostr.str();
}
return "";
}
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, const char value[], ValueFlow::Value::ValueType type) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.valueType == type && Token::simpleMatch(v.tokvalue, value, strlen(value)))
return true;
}
}
}
return false;
}
#define testLifetimeOfX(...) testLifetimeOfX_(__FILE__, __LINE__, __VA_ARGS__)
bool testLifetimeOfX_(const char* file, int line, const char code[], unsigned int linenr, const char value[], ValueFlow::Value::LifetimeScope lifetimeScope = ValueFlow::Value::LifetimeScope::Local) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.isLifetimeValue() && v.lifetimeScope == lifetimeScope && Token::simpleMatch(v.tokvalue, value, strlen(value)))
return true;
}
}
}
return false;
}
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, int value, ValueFlow::Value::ValueType type) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.valueType == type && v.intvalue == value)
return true;
}
}
}
return false;
}
bool testValueOfX_(const char* file, int line, const char code[], unsigned int linenr, ValueFlow::Value::MoveKind moveKind) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.isMovedValue() && v.moveKind == moveKind)
return true;
}
}
}
return false;
}
#define testConditionalValueOfX(code, linenr, value) testConditionalValueOfX_(code, linenr, value, __FILE__, __LINE__)
bool testConditionalValueOfX_(const char code[], unsigned int linenr, int value, const char* file, int line) {
// Tokenize..
Tokenizer tokenizer(&settings, this);
std::istringstream istr(code);
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
for (const Token *tok = tokenizer.tokens(); tok; tok = tok->next()) {
if (tok->str() == "x" && tok->linenr() == linenr) {
for (const ValueFlow::Value &v : tok->values()) {
if (v.isIntValue() && v.intvalue == value && v.condition)
return true;
}
}
}
return false;
}
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void bailout(const char code[]) {
settings.debugwarnings = true;
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errout.str("");
std::vector<std::string> files(1, "test.cpp");
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std::istringstream istr(code);
const simplecpp::TokenList tokens1(istr, files, files[0]);
simplecpp::TokenList tokens2(files);
std::map<std::string, simplecpp::TokenList*> filedata;
simplecpp::preprocess(tokens2, tokens1, files, filedata, simplecpp::DUI());
// Tokenize..
Tokenizer tokenizer(&settings, this);
tokenizer.createTokens(std::move(tokens2));
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tokenizer.simplifyTokens1("");
settings.debugwarnings = false;
}
#define tokenValues(...) tokenValues_(__FILE__, __LINE__, __VA_ARGS__)
std::list<ValueFlow::Value> tokenValues_(const char* file, int line, const char code[], const char tokstr[], const Settings *s = nullptr) {
Tokenizer tokenizer(s ? s : &settings, this);
std::istringstream istr(code);
errout.str("");
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
const Token *tok = Token::findmatch(tokenizer.tokens(), tokstr);
return tok ? tok->values() : std::list<ValueFlow::Value>();
}
std::list<ValueFlow::Value> tokenValues_(const char* file, int line, const char code[], const char tokstr[], ValueFlow::Value::ValueType vt, const Settings *s = nullptr) {
std::list<ValueFlow::Value> values = tokenValues_(file, line, code, tokstr, s);
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values.remove_if([&](const ValueFlow::Value& v) {
return v.valueType != vt;
});
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return values;
}
#define lifetimeValues(...) lifetimeValues_(__FILE__, __LINE__, __VA_ARGS__)
std::vector<std::string> lifetimeValues_(const char* file, int line, const char code[], const char tokstr[], const Settings *s = nullptr) {
std::vector<std::string> result;
Tokenizer tokenizer(s ? s : &settings, this);
std::istringstream istr(code);
errout.str("");
ASSERT_LOC(tokenizer.tokenize(istr, "test.cpp"), file, line);
const Token *tok = Token::findmatch(tokenizer.tokens(), tokstr);
if (!tok)
return result;
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for (const ValueFlow::Value& value:tok->values()) {
if (!value.isLifetimeValue())
continue;
if (!value.tokvalue)
continue;
result.push_back(value.tokvalue->expressionString());
}
return result;
}
#define valueOfTok(code, tokstr) valueOfTok_(code, tokstr, __FILE__, __LINE__)
ValueFlow::Value valueOfTok_(const char code[], const char tokstr[], const char* file, int line) {
std::list<ValueFlow::Value> values = tokenValues_(file, line, code, tokstr);
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return values.size() == 1U && !values.front().isTokValue() ? values.front() : ValueFlow::Value();
}
std::list<ValueFlow::Value> removeSymbolic(std::list<ValueFlow::Value> values)
{
values.remove_if(std::mem_fn(&ValueFlow::Value::isSymbolicValue));
return values;
}
std::list<ValueFlow::Value> removeImpossible(std::list<ValueFlow::Value> values)
{
values.remove_if(std::mem_fn(&ValueFlow::Value::isImpossible));
return values;
}
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void valueFlowNumber() {
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ASSERT_EQUALS(123, valueOfTok("x=123;", "123").intvalue);
ASSERT_EQUALS_DOUBLE(192.0, valueOfTok("x=0x0.3p10;", "0x0.3p10").floatValue, 1e-5); // 3 * 16^-1 * 2^10 = 192
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ASSERT(std::fabs(valueOfTok("x=0.5;", "0.5").floatValue - 0.5f) < 0.1f);
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ASSERT_EQUALS(10, valueOfTok("enum {A=10,B=15}; x=A+0;", "+").intvalue);
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ASSERT_EQUALS(0, valueOfTok("x=false;", "false").intvalue);
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ASSERT_EQUALS(1, valueOfTok("x=true;", "true").intvalue);
ASSERT_EQUALS(0, valueOfTok("x(NULL);", "NULL").intvalue);
ASSERT_EQUALS((int)('a'), valueOfTok("x='a';", "'a'").intvalue);
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ASSERT_EQUALS((int)('\n'), valueOfTok("x='\\n';", "'\\n'").intvalue);
TODO_ASSERT_EQUALS(
0xFFFFFFFF00000000, -1, valueOfTok("x=0xFFFFFFFF00000000;", "0xFFFFFFFF00000000").intvalue); // #7701
ASSERT_EQUALS_DOUBLE(16, valueOfTok("x=(double)16;", "(").floatValue, 1e-5);
ASSERT_EQUALS_DOUBLE(0.0625, valueOfTok("x=1/(double)16;", "/").floatValue, 1e-5);
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// scope
{
const char code[] = "namespace N { enum E {e0,e1}; }\n"
"void foo() { x = N::e1; }";
ASSERT_EQUALS(1, valueOfTok(code, "::").intvalue);
}
}
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void valueFlowString() {
const char *code;
// valueFlowAfterAssign
code = "const char * f() {\n"
" static const char *x;\n"
" if (a) x = \"123\";\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4, "\"123\"", ValueFlow::Value::ValueType::TOK));
// valueFlowSubFunction
code = "void dostuff(const char *x) {\n"
" f(x);\n"
"}\n"
"\n"
"void test() { dostuff(\"abc\"); }";
ASSERT_EQUALS(true, testValueOfX(code, 2, "\"abc\"", ValueFlow::Value::ValueType::TOK));
}
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void valueFlowPointerAlias() {
const char *code;
std::list<ValueFlow::Value> values;
code = "const char * f() {\n"
" static const char *x;\n"
" static char ret[10];\n"
" if (a) x = &ret[0];\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5, "& ret [ 0 ]", ValueFlow::Value::ValueType::TOK));
// dead pointer
code = "void f() {\n"
" int *x;\n"
" if (cond) { int i; x = &i; }\n"
" *x = 0;\n" // <- x can point at i
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4, "& i", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n"
" struct X *x;\n"
" x = &x[1];\n"
"}";
values = tokenValues(code, "&");
values.remove_if(&isNotTokValue);
ASSERT_EQUALS(true, values.empty());
values = tokenValues(code, "x [");
values.remove_if(&isNotTokValue);
ASSERT_EQUALS(true, values.empty());
}
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void valueFlowLifetime() {
const char *code;
std::vector<std::string> lifetimes;
LOAD_LIB_2(settings.library, "std.cfg");
code = "void f() {\n"
" int a = 1;\n"
" auto x = [&]() { return a + 1; };\n"
" auto b = x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 4, "a + 1"));
code = "void f() {\n"
" int a = 1;\n"
" auto x = [=]() { return a + 1; };\n"
" auto b = x;\n"
"}\n";
ASSERT_EQUALS(false, testLifetimeOfX(code, 4, "a ;"));
code = "void f(int v) {\n"
" int a = v;\n"
" int * p = &a;\n"
" auto x = [=]() { return p + 1; };\n"
" auto b = x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 5, "a ;"));
code = "void f() {\n"
" std::vector<int> v;\n"
" auto x = v.begin();\n"
" auto it = x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 4, "v . begin"));
code = "void f() {\n"
" std::vector<int> v;\n"
" auto x = v.begin() + 1;\n"
" auto it = x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 4, "v . begin"));
code = "int* f() {\n"
" std::vector<int> v;\n"
" int * x = v.data();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 4, "v . data"));
code = "int* f() {\n"
" std::vector<int> v;\n"
" int * x = v.data() + 1;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testLifetimeOfX(code, 4, "v . data"));
code = "int f(int* a) {\n"
" int **p = &a;\n"
" int * x = *p;\n"
" return x; \n"
"}\n";
ASSERT_EQUALS(false, testLifetimeOfX(code, 4, "a"));
code = "void f() {\n"
" int i = 0;\n"
" void* x = (void*)&i;\n"
"}\n";
lifetimes = lifetimeValues(code, "( void * )");
ASSERT_EQUALS(true, lifetimes.size() == 1);
ASSERT_EQUALS(true, lifetimes.front() == "i");
}
void valueFlowArrayElement() {
const char *code;
code = "void f() {\n"
" const int x[] = {43,23,12};\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "{ 43 , 23 , 12 }", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n"
" const char x[] = \"abcd\";\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "\"abcd\"", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n"
" char x[32] = \"abcd\";\n"
" return x;\n"
"}";
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 3U, "\"abcd\"", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n"
" int a[10];\n"
" int *x = a;\n" // <- a value is a
" *x = 0;\n" // .. => x value is a
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4, "a", ValueFlow::Value::ValueType::TOK));
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code = "char f() {\n"
" const char *x = \"abcd\";\n"
" return x[0];\n"
"}";
ASSERT_EQUALS((int)('a'), valueOfTok(code, "[").intvalue);
code = "char f() {\n"
" const char *x = \"\";\n"
" return x[0];\n"
"}";
ASSERT_EQUALS(0, valueOfTok(code, "[").intvalue);
}
void valueFlowMove() {
const char *code;
code = "void f() {\n"
" X x;\n"
" g(std::move(x));\n"
" y=x;\n"
"}";
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ASSERT_EQUALS(true, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f() {\n"
" X x;\n"
" g(std::forward<X>(x));\n"
" y=x;\n"
"}";
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ASSERT_EQUALS(true, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::ForwardedVariable));
code = "void f() {\n"
" X x;\n"
" g(std::move(x).getA());\n" // Only parts of x might be moved out
" y=x;\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f() {\n"
" X x;\n"
" g(std::forward<X>(x).getA());\n" // Only parts of x might be moved out
" y=x;\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::ForwardedVariable));
code = "void f() {\n"
" X x;\n"
" g(std::move(x));\n"
" x.clear();\n"
" y=x;\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 5U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f() {\n"
" X x;\n"
" g(std::move(x));\n"
" y=x->y;\n"
" z=x->z;\n"
"}";
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ASSERT_EQUALS(true, testValueOfX(code, 5U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f(int i) {\n"
" X x;\n"
" z = g(std::move(x));\n"
" y = x;\n"
"}";
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ASSERT_EQUALS(true, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f(int i) {\n"
" X x;\n"
" y = g(std::move(x),\n"
" x.size());\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f(int i) {\n"
" X x;\n"
" x = g(std::move(x));\n"
" y = x;\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "A f(int i) {\n"
" X x;\n"
" if (i)"
" return g(std::move(x));\n"
" return h(std::move(x));\n"
"}";
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ASSERT_EQUALS(false, testValueOfX(code, 5U, ValueFlow::Value::MoveKind::MovedVariable));
code = "struct X {\n"
"};\n"
"struct Data {\n"
" template<typename Fun>\n"
" void foo(Fun f) {}\n"
"};\n"
"Data g(X value) { return Data(); }\n"
"void f() {\n"
" X x;\n"
" g(std::move(x)).foo([=](int value) mutable {;});\n"
" X y=x;\n"
"}";
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ASSERT_EQUALS(true, testValueOfX(code, 11U, ValueFlow::Value::MoveKind::MovedVariable));
code = "void f(int x) {\n"
" g(std::move(x));\n"
" y=x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, ValueFlow::Value::MoveKind::MovedVariable));
}
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void valueFlowCalculations() {
const char *code;
// Different operators
ASSERT_EQUALS(5, valueOfTok("3 + (a ? b : 2);", "+").intvalue);
ASSERT_EQUALS(1, valueOfTok("3 - (a ? b : 2);", "-").intvalue);
ASSERT_EQUALS(6, valueOfTok("3 * (a ? b : 2);", "*").intvalue);
ASSERT_EQUALS(6, valueOfTok("13 / (a ? b : 2);", "/").intvalue);
ASSERT_EQUALS(1, valueOfTok("13 % (a ? b : 2);", "%").intvalue);
ASSERT_EQUALS(0, valueOfTok("3 == (a ? b : 2);", "==").intvalue);
ASSERT_EQUALS(1, valueOfTok("3 != (a ? b : 2);", "!=").intvalue);
ASSERT_EQUALS(1, valueOfTok("3 > (a ? b : 2);", ">").intvalue);
ASSERT_EQUALS(1, valueOfTok("3 >= (a ? b : 2);", ">=").intvalue);
ASSERT_EQUALS(0, valueOfTok("3 < (a ? b : 2);", "<").intvalue);
ASSERT_EQUALS(0, valueOfTok("3 <= (a ? b : 2);", "<=").intvalue);
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ASSERT_EQUALS(1, valueOfTok("(UNKNOWN_TYPE)1;","(").intvalue);
ASSERT(tokenValues("(UNKNOWN_TYPE)1000;","(").empty()); // don't know if there is truncation, sign extension
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ASSERT_EQUALS(255, valueOfTok("(unsigned char)~0;", "(").intvalue);
ASSERT_EQUALS(0, valueOfTok("(int)0;", "(").intvalue);
ASSERT_EQUALS(3, valueOfTok("(int)(1+2);", "(").intvalue);
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ASSERT_EQUALS(0, valueOfTok("(UNKNOWN_TYPE*)0;","(").intvalue);
ASSERT_EQUALS(100, valueOfTok("(int)100.0;", "(").intvalue);
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ASSERT_EQUALS(10, valueOfTok("x = static_cast<int>(10);", "( 10 )").intvalue);
// Don't calculate if there is UB
ASSERT(tokenValues(";-1<<10;","<<").empty());
ASSERT(tokenValues(";10<<-1;","<<").empty());
ASSERT(tokenValues(";10<<64;","<<").empty());
ASSERT(tokenValues(";-1>>10;",">>").empty());
ASSERT(tokenValues(";10>>-1;",">>").empty());
ASSERT(tokenValues(";10>>64;",">>").empty());
code = "float f(const uint16_t& value) {\n"
" const uint16_t uVal = value; \n"
" return static_cast<float>(uVal) / 2;\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "/").empty());
// calculation using 1,2 variables/values
code = "void f(int x) {\n"
" a = x+456;\n"
" if (x==123) {}"
"}";
ASSERT_EQUALS(579, valueOfTok(code, "+").intvalue);
code = "void f(int x, int y) {\n"
" a = x+y;\n"
" if (x==123 || y==456) {}"
"}";
ASSERT_EQUALS(0, valueOfTok(code, "+").intvalue);
code = "void f(int x) {\n"
" a = x+x;\n"
" if (x==123) {}"
"}";
ASSERT_EQUALS(246, valueOfTok(code, "+").intvalue);
code = "void f(int x, int y) {\n"
" a = x*x;\n"
" if (x==2) {}\n"
" if (x==4) {}\n"
"}";
std::list<ValueFlow::Value> values = tokenValues(code,"*");
ASSERT_EQUALS(2U, values.size());
ASSERT_EQUALS(4, values.front().intvalue);
ASSERT_EQUALS(16, values.back().intvalue);
code = "void f(int x) {\n"
" if (x == 3) {}\n"
" a = x * (1 - x - 1);\n"
"}";
ASSERT_EQUALS(-9, valueOfTok(code, "*").intvalue);
// addition of different variables with known values
code = "int f(int x) {\n"
" int a = 1;\n"
" while (x!=3) { x+=a; }\n"
" return x/a;\n"
"}\n";
ASSERT_EQUALS(3, valueOfTok(code, "/").intvalue);
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// ? :
code = "x = y ? 2 : 3;\n";
values = tokenValues(code,"?");
ASSERT_EQUALS(2U, values.size());
ASSERT_EQUALS(2, values.front().intvalue);
ASSERT_EQUALS(3, values.back().intvalue);
code = "void f(int a) { x = a ? 2 : 3; }\n";
values = tokenValues(code,"?");
ASSERT_EQUALS(2U, values.size());
ASSERT_EQUALS(2, values.front().intvalue);
ASSERT_EQUALS(3, values.back().intvalue);
code = "x = (2<5) ? 2 : 3;\n";
values = tokenValues(code, "?");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(2, values.front().intvalue);
code = "x = 123 ? : 456;\n";
values = tokenValues(code, "?");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(123, values.empty() ? 0 : values.front().intvalue);
code = "int f() {\n"
" const int i = 1;\n"
" int x = i < 0 ? 0 : 1;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 1));
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// ~
code = "x = ~0U;";
settings.platform(cppcheck::Platform::Native); // ensure platform is native
values = tokenValues(code,"~");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(~0U, values.back().intvalue);
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// !
code = "void f(int x) {\n"
" a = !x;\n"
" if (x==0) {}\n"
"}";
values = tokenValues(code,"!");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(1, values.back().intvalue);
// unary minus
code = "void f(int x) {\n"
" a = -x;\n"
" if (x==10) {}\n"
"}";
values = tokenValues(code,"-");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(-10, values.back().intvalue);
// Logical and
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code = "void f(bool b) {\n"
" bool x = false && b;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
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code = "void f(bool b) {\n"
" bool x = b && false;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
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code = "void f(bool b) {\n"
" bool x = true && b;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 1));
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code = "void f(bool b) {\n"
" bool x = b && true;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 1));
// Logical or
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code = "void f(bool b) {\n"
" bool x = true || b;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
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code = "void f(bool b) {\n"
" bool x = b || true;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
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code = "void f(bool b) {\n"
" bool x = false || b;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
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code = "void f(bool b) {\n"
" bool x = b || false;\n"
" bool a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
code = "bool f(const uint16_t * const p) {\n"
" const uint8_t x = (uint8_t)(*p & 0x01E0U) >> 5U;\n"
" return x != 0;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
code = "bool f() {\n"
" bool a = (4 == 3);\n"
" bool b = (3 == 3);\n"
" return a || b;\n"
"}\n";
values = tokenValues(code, "%oror%");
ASSERT_EQUALS(1, values.size());
if (!values.empty()) {
ASSERT_EQUALS(true, values.front().isIntValue());
ASSERT_EQUALS(true, values.front().isKnown());
ASSERT_EQUALS(1, values.front().intvalue);
}
// function call => calculation
code = "void f(int x, int y) {\n"
" a = x + y;\n"
"}\n"
"void callf() {\n"
" f(1,1);\n"
" f(10,10);\n"
"}";
values = tokenValues(code, "+");
ASSERT_EQUALS(true, values.empty());
if (!values.empty()) {
/* todo.. */
ASSERT_EQUALS(2U, values.size());
ASSERT_EQUALS(2, values.front().intvalue);
ASSERT_EQUALS(22, values.back().intvalue);
}
// Comparison of string
values = tokenValues("f(\"xyz\" == \"xyz\");", "=="); // implementation defined
ASSERT_EQUALS(0U, values.size()); // <- no value
values = tokenValues("f(\"xyz\" == 0);", "==");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(0, values.front().intvalue);
values = tokenValues("f(0 == \"xyz\");", "==");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(0, values.front().intvalue);
values = tokenValues("f(\"xyz\" != 0);", "!=");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(1, values.front().intvalue);
values = tokenValues("f(0 != \"xyz\");", "!=");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(1, values.front().intvalue);
}
void valueFlowSizeof() {
const char *code;
std::list<ValueFlow::Value> values;
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// array size
code = "void f() {\n"
" char a[10];"
" x = sizeof(*a);\n"
"}";
values = tokenValues(code,"( *");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(1, values.back().intvalue);
code = "void f() {\n"
" char a[10];"
" x = sizeof(a[0]);\n"
"}";
values = tokenValues(code,"( a");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(1, values.back().intvalue);
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code = "enum testEnum : uint32_t { a };\n"
"sizeof(testEnum);";
values = tokenValues(code,"( testEnum");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(4, values.back().intvalue);
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#define CHECK3(A, B, C) \
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do { \
code = "void f() {\n" \
" x = sizeof(" A ");\n" \
"}"; \
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values = tokenValues(code,"( " C " )"); \
ASSERT_EQUALS(1U, values.size()); \
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ASSERT_EQUALS(B, values.back().intvalue); \
} while (false)
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#define CHECK(A, B) CHECK3(A, B, A)
// standard types
CHECK("void *", settings.sizeof_pointer);
CHECK("char", 1U);
CHECK("short", settings.sizeof_short);
CHECK("int", settings.sizeof_int);
CHECK("long", settings.sizeof_long);
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CHECK3("long long", settings.sizeof_long_long, "long");
CHECK("wchar_t", settings.sizeof_wchar_t);
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CHECK("float", settings.sizeof_float);
CHECK("double", settings.sizeof_double);
CHECK3("long double", settings.sizeof_long_double, "double");
// string/char literals
CHECK("\"asdf\"", 5);
CHECK("L\"asdf\"", 5 * settings.sizeof_wchar_t);
CHECK("u8\"asdf\"", 5); // char8_t
CHECK("u\"asdf\"", 5 * 2); // char16_t
CHECK("U\"asdf\"", 5 * 4); // char32_t
CHECK("'a'", 1U);
CHECK("'ab'", settings.sizeof_int);
CHECK("L'a'", settings.sizeof_wchar_t);
CHECK("u8'a'", 1U); // char8_t
CHECK("u'a'", 2U); // char16_t
CHECK("U'a'", 4U); // char32_t
#undef CHECK
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#undef CHECK3
// array size
code = "void f() {\n"
" struct S *a[10];"
" x = sizeof(a) / sizeof(a[0]);\n"
"}";
values = tokenValues(code,"/");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(10, values.back().intvalue);
#define CHECK(A, B, C, D) \
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do { \
code = "enum " A " E " B " { E0, E1 };\n" \
"void f() {\n" \
" x = sizeof(" C ");\n" \
"}"; \
values = tokenValues(code,"( " C " )"); \
ASSERT_EQUALS(1U, values.size()); \
ASSERT_EQUALS(D, values.back().intvalue); \
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} while (false)
// enums
CHECK("", "", "E", settings.sizeof_int);
// typed enums
CHECK("", ": char", "E", 1U);
CHECK("", ": signed char", "E", 1U);
CHECK("", ": unsigned char", "E", 1U);
CHECK("", ": short", "E", settings.sizeof_short);
CHECK("", ": signed short", "E", settings.sizeof_short);
CHECK("", ": unsigned short", "E", settings.sizeof_short);
CHECK("", ": int", "E", settings.sizeof_int);
CHECK("", ": signed int", "E", settings.sizeof_int);
CHECK("", ": unsigned int", "E", settings.sizeof_int);
CHECK("", ": long", "E", settings.sizeof_long);
CHECK("", ": signed long", "E", settings.sizeof_long);
CHECK("", ": unsigned long", "E", settings.sizeof_long);
CHECK("", ": long long", "E", settings.sizeof_long_long);
CHECK("", ": signed long long", "E", settings.sizeof_long_long);
CHECK("", ": unsigned long long", "E", settings.sizeof_long_long);
CHECK("", ": wchar_t", "E", settings.sizeof_wchar_t);
CHECK("", ": size_t", "E", settings.sizeof_size_t);
// enumerators
CHECK("", "", "E0", settings.sizeof_int);
// typed enumerators
CHECK("", ": char", "E0", 1U);
CHECK("", ": signed char", "E0", 1U);
CHECK("", ": unsigned char", "E0", 1U);
CHECK("", ": short", "E0", settings.sizeof_short);
CHECK("", ": signed short", "E0", settings.sizeof_short);
CHECK("", ": unsigned short", "E0", settings.sizeof_short);
CHECK("", ": int", "E0", settings.sizeof_int);
CHECK("", ": signed int", "E0", settings.sizeof_int);
CHECK("", ": unsigned int", "E0", settings.sizeof_int);
CHECK("", ": long", "E0", settings.sizeof_long);
CHECK("", ": signed long", "E0", settings.sizeof_long);
CHECK("", ": unsigned long", "E0", settings.sizeof_long);
CHECK("", ": long long", "E0", settings.sizeof_long_long);
CHECK("", ": signed long long", "E0", settings.sizeof_long_long);
CHECK("", ": unsigned long long", "E0", settings.sizeof_long_long);
CHECK("", ": wchar_t", "E0", settings.sizeof_wchar_t);
CHECK("", ": size_t", "E0", settings.sizeof_size_t);
// class typed enumerators
CHECK("class", ": char", "E :: E0", 1U);
CHECK("class", ": signed char", "E :: E0", 1U);
CHECK("class", ": unsigned char", "E :: E0", 1U);
CHECK("class", ": short", "E :: E0", settings.sizeof_short);
CHECK("class", ": signed short", "E :: E0", settings.sizeof_short);
CHECK("class", ": unsigned short", "E :: E0", settings.sizeof_short);
CHECK("class", ": int", "E :: E0", settings.sizeof_int);
CHECK("class", ": signed int", "E :: E0", settings.sizeof_int);
CHECK("class", ": unsigned int", "E :: E0", settings.sizeof_int);
CHECK("class", ": long", "E :: E0", settings.sizeof_long);
CHECK("class", ": signed long", "E :: E0", settings.sizeof_long);
CHECK("class", ": unsigned long", "E :: E0", settings.sizeof_long);
CHECK("class", ": long long", "E :: E0", settings.sizeof_long_long);
CHECK("class", ": signed long long", "E :: E0", settings.sizeof_long_long);
CHECK("class", ": unsigned long long", "E :: E0", settings.sizeof_long_long);
CHECK("class", ": wchar_t", "E :: E0", settings.sizeof_wchar_t);
CHECK("class", ": size_t", "E :: E0", settings.sizeof_size_t);
#undef CHECK
#define CHECK(A, B) \
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do { \
code = "enum E " A " { E0, E1 };\n" \
"void f() {\n" \
" E arrE[] = { E0, E1 };\n" \
" x = sizeof(arrE);\n" \
"}"; \
values = tokenValues(code,"( arrE )"); \
ASSERT_EQUALS(1U, values.size()); \
2021-08-07 20:51:18 +02:00
ASSERT_EQUALS(B * 2U, values.back().intvalue); \
} while (false)
// enum array
CHECK("", settings.sizeof_int);
// typed enum array
CHECK(": char", 1U);
CHECK(": signed char", 1U);
CHECK(": unsigned char", 1U);
CHECK(": short", settings.sizeof_short);
CHECK(": signed short", settings.sizeof_short);
CHECK(": unsigned short", settings.sizeof_short);
CHECK(": int", settings.sizeof_int);
CHECK(": signed int", settings.sizeof_int);
CHECK(": unsigned int", settings.sizeof_int);
CHECK(": long", settings.sizeof_long);
CHECK(": signed long", settings.sizeof_long);
CHECK(": unsigned long", settings.sizeof_long);
CHECK(": long long", settings.sizeof_long_long);
CHECK(": signed long long", settings.sizeof_long_long);
CHECK(": unsigned long long", settings.sizeof_long_long);
CHECK(": wchar_t", settings.sizeof_wchar_t);
CHECK(": size_t", settings.sizeof_size_t);
#undef CHECK
#define CHECK(A, B) \
2021-08-07 20:51:18 +02:00
do { \
code = "enum class E " A " { E0, E1 };\n" \
"void f() {\n" \
" E arrE[] = { E::E0, E::E1 };\n" \
" x = sizeof(arrE);\n" \
"}"; \
values = tokenValues(code,"( arrE )"); \
ASSERT_EQUALS(1U, values.size()); \
2021-08-07 20:51:18 +02:00
ASSERT_EQUALS(B * 2U, values.back().intvalue); \
} while (false)
// enum array
CHECK("", settings.sizeof_int);
// typed enum array
CHECK(": char", 1U);
CHECK(": signed char", 1U);
CHECK(": unsigned char", 1U);
CHECK(": short", settings.sizeof_short);
CHECK(": signed short", settings.sizeof_short);
CHECK(": unsigned short", settings.sizeof_short);
CHECK(": int", settings.sizeof_int);
CHECK(": signed int", settings.sizeof_int);
CHECK(": unsigned int", settings.sizeof_int);
CHECK(": long", settings.sizeof_long);
CHECK(": signed long", settings.sizeof_long);
CHECK(": unsigned long", settings.sizeof_long);
CHECK(": long long", settings.sizeof_long_long);
CHECK(": signed long long", settings.sizeof_long_long);
CHECK(": unsigned long long", settings.sizeof_long_long);
CHECK(": wchar_t", settings.sizeof_wchar_t);
CHECK(": size_t", settings.sizeof_size_t);
#undef CHECK
code = "uint16_t arr[10];\n"
"x = sizeof(arr);";
values = tokenValues(code,"( arr )");
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(10 * sizeof(std::uint16_t), values.back().intvalue);
}
2017-05-19 14:34:59 +02:00
void valueFlowErrorPath() {
const char *code;
code = "void f() {\n"
" int x = 53;\n"
" a = x;\n"
"}\n";
2017-05-20 08:47:35 +02:00
ASSERT_EQUALS("2,Assignment 'x=53', assigned value is 53\n",
2017-05-19 14:34:59 +02:00
getErrorPathForX(code, 3U));
code = "void f(int y) {\n"
" int x = y;\n"
" a = x;\n"
" y += 12;\n"
" if (y == 32) {}"
"}\n";
ASSERT_EQUALS("2,x is assigned 'y' here.\n"
"5,Assuming that condition 'y==32' is not redundant\n"
2020-11-10 16:00:55 +01:00
"4,Compound assignment '+=', assigned value is 20\n"
"2,x is assigned 'y' here.\n",
2017-05-19 14:34:59 +02:00
getErrorPathForX(code, 3U));
code = "void f1(int x) {\n"
" a = x;\n"
"}\n"
"void f2() {\n"
" int x = 3;\n"
" f1(x+1);\n"
"}\n";
ASSERT_EQUALS("5,Assignment 'x=3', assigned value is 3\n"
"6,Calling function 'f1', 1st argument 'x+1' value is 4\n",
getErrorPathForX(code, 2U));
code = "void f(int a) {\n"
" int x;\n"
" for (x = a; x < 50; x++) {}\n"
" b = x;\n"
"}\n";
ASSERT_EQUALS("3,Assuming that condition 'x<50' is not redundant\n"
"3,Assuming that condition 'x<50' is not redundant\n",
getErrorPathForX(code, 4U));
2017-05-19 14:34:59 +02:00
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeCondition() {
2014-01-08 06:39:15 +01:00
const char *code;
code = "void f(int x) {\n"
" int a = x;\n"
" if (x == 123) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 123));
code = "void f(unsigned int x) {\n"
" int a = x;\n"
" if (x >= 1) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 1));
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "void f(unsigned int x) {\n"
" int a = x;\n"
" if (x > 0) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "void f(unsigned int x) {\n"
" int a = x;\n"
" if (x > 1) {}\n" // not zero => don't consider > condition
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 1));
code = "void f(int x) {\n" // not unsigned => don't consider > condition
" int a = x;\n"
2014-01-20 06:31:28 +01:00
" if (x > 0) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 0));
code = "void f(int *x) {\n"
" *x = 100;\n"
" if (x) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "extern const int x;\n"
"void f() {\n"
" int a = x;\n"
" if (x == 123) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
// after loop
code = "void f(struct X *x) {\n"
" do {\n"
" if (!x)\n"
" break;\n"
" } while (x->a);\n"
" if (x) {}\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionAssignIncDec() { // assignment / increment
const char *code;
code = "void f(int x) {\n"
" x = 2 + x;\n"
" if (x == 65);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 65));
code = "void f(int x) {\n"
" x = y = 2 + x;\n"
" if (x == 65);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 65));
code = "void f(int x) {\n"
" a[x++] = 0;\n"
" if (x == 5);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 5));
code = "void f(int x) {\n"
" a = x;\n"
" x++;\n"
" if (x == 4);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 3));
// compound assignment += , -= , ...
code = "void f(int x) {\n"
" a = x;\n"
" x += 2;\n"
" if (x == 4);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 2));
code = "void f(int x) {\n"
" a = x;\n"
" x -= 2;\n"
" if (x == 4);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 6));
code = "void f(int x) {\n"
" a = x;\n"
" x *= 2;\n"
" if (x == 42);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 21));
code = "void f(int x) {\n"
" a = x;\n"
" x /= 5;\n"
" if (x == 42);\n"
"}";
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS(true, testValueOfX(code, 2U, 210));
// bailout: assignment
bailout("void f(int x) {\n"
" x = y;\n"
" if (x == 123) {}\n"
"}");
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:2]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable y\n",
2020-11-10 16:00:55 +01:00
errout.str());
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionAndAndOrOrGuard() { // guarding by &&
const char *code;
code = "void f(int x) {\n"
" if (!x || \n" // <- x can be 0
" a/x) {}\n" // <- x can't be 0
" if (x==0) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
code = "void f(int *x) {\n"
" ((x=ret())&&\n"
" (*x==0));\n" // <- x is not 0
" if (x==0) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
2015-09-27 13:29:28 +02:00
code = "void f(int *x) {\n"
" int a = (x && *x == '1');\n"
" int b = a ? atoi(x) : 0;\n" // <- x is not 0
" if (x==0) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionFunctionCall() { // function calls
const char *code;
code = "void f(int x) {\n"
" a = x;\n"
" setx(x);\n"
" if (x == 1) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX((std::string("void setx(int x);")+code).c_str(), 2U, 1));
ASSERT_EQUALS(false, testValueOfX((std::string("void setx(int &x);")+code).c_str(), 2U, 1));
ASSERT_EQUALS(true, testValueOfX(code, 2U, 1));
code = "void f(char* x) {\n"
" strcpy(x,\"abc\");\n"
" if (x) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "void addNewFunction(Scope**scope, const Token**tok);\n"
"void f(Scope *x) {\n"
" x->functionList.back();\n"
" addNewFunction(&x,&tok);\n" // address-of, x can be changed by subfunction
" if (x) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionLoop() { // while, for, do-while
const char *code;
code = "void f(int x) {\n" // loop condition, x is not assigned inside loop => use condition
" a = x;\n" // x can be 37
" while (x == 37) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 37));
code = "void f(int x) {\n" // loop condition, x is assigned inside loop => don't use condition
" a = x;\n" // don't assume that x can be 37
" while (x != 37) { x++; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 37));
code = "void f(int x) {\n"
" a = x;\n"
" for (; x!=1; x++) { }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 1));
code = "void f(menu *x) {\n"
" a = x->parent;\n"
" for (i=0;(i<10) && (x!=0); i++) { x = x->next; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 0));
code = "void f(int x) {\n" // condition inside loop, x is NOT assigned inside loop => use condition
" a = x;\n"
" do {\n"
" if (x==76) {}\n"
" } while (1);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 76));
code = "void f(int x) {\n" // conditions inside loop, x is assigned inside do-while => don't use condition
" a = x;\n"
" do {\n"
" if (x!=76) { x=do_something(); }\n"
" } while (1);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 76));
2014-01-18 11:54:00 +01:00
code = "void f(X x) {\n" // conditions inside loop, x is assigned inside do-while => don't use condition
2014-01-18 11:54:00 +01:00
" a = x;\n"
" for (i=1;i<=count;i++) {\n"
" BUGON(x==0)\n"
" x = x.next;\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionTernaryOp() { // bailout: ?:
const char *code;
2014-01-07 19:46:13 +01:00
bailout("void f(int x) {\n"
" y = ((x<0) ? x : ((x==2)?3:4));\n"
"}");
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:2]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable y\n",
2020-11-10 16:00:55 +01:00
errout.str());
2014-01-08 06:39:15 +01:00
bailout("int f(int x) {\n"
" int r = x ? 1 / x : 0;\n"
" if (x == 0) {}\n"
"}");
code = "void f(int x) {\n"
" int a =v x;\n"
2014-01-08 06:39:15 +01:00
" a = b ? x/2 : 20/x;\n"
" if (x == 123) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 123));
2014-01-07 19:46:13 +01:00
code = "void f(const s *x) {\n"
" x->a = 0;\n"
" if (x ? x->a : 0) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "void f(int x, int y) {\n"
" a = x;\n"
" if (y){}\n"
" if (x==123){}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 123));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionSizeof() { // skip sizeof
const char *code;
code = "void f(int *x) {\n"
" sizeof(x[0]);\n"
" if (x==63){}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 63));
code = "void f(int *x) {\n"
" char a[sizeof x.y];\n"
" if (x==0){}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionIfElse() { // bailout: if/else/etc
const char *code;
code = "void f(X * x) {\n"
" a = x;\n"
" if ((x != NULL) &&\n"
" (a(x->name, html)) &&\n"
" (a(x->name, body))) {}\n"
" if (x != NULL) { }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
2014-01-06 11:27:56 +01:00
bailout("void f(int x) {\n"
" if (x != 123) { b = x; }\n"
" if (x == 123) {}\n"
"}");
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:2]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable b\n",
2020-11-10 16:00:55 +01:00
errout.str());
2020-11-10 16:00:55 +01:00
code = "void f(int x, bool abc) {\n"
" a = x;\n"
2020-11-10 16:00:55 +01:00
" if (abc) { x = 1; }\n" // <- condition must be false if x is 7 in next line
" if (x == 7) { }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 7));
2020-11-10 16:00:55 +01:00
code = "void f(int x, bool abc) {\n"
" a = x;\n"
" if (abc) { x = 7; }\n" // <- condition is probably true
" if (x == 7) { }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 7));
}
2014-01-06 11:27:56 +01:00
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionGlobalVariables() {
const char *code;
// handle global variables
code = "int x;\n"
"void f() {\n"
" int a = x;\n"
" if (x == 123) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code,3,123));
// bailout when there is function call
code = "class Fred { int x; void clear(); void f(); };\n"
"void Fred::f() {\n"
" int a = x;\n"
" clear();\n" // <- x might be assigned
" if (x == 234) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code,3,234));
}
2014-01-11 21:21:00 +01:00
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionSwitch() {
2014-01-11 21:21:00 +01:00
// bailout: switch
// TODO : handle switch/goto more intelligently
2014-01-11 21:21:00 +01:00
bailout("void f(int x, int y) {\n"
" switch (y) {\n"
" case 1: a=x; break;\n"
" case 2: if (x==5) {} break;\n"
" };\n"
"}");
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:3]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable a\n",
2020-11-10 16:00:55 +01:00
errout.str());
bailout("void f(int x, int y) {\n"
" switch (y) {\n"
" case 1: a=x; return 1;\n"
" case 2: if (x==5) {} break;\n"
" };\n"
"}");
2020-11-10 16:00:55 +01:00
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:3]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable a\n",
2020-11-10 16:00:55 +01:00
errout.str());
}
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionMacro() {
// bailout: condition is a expanded macro
2017-05-18 21:52:31 +02:00
bailout("#define M if (x==123) {}\n"
"void f(int x) {\n"
" a = x;\n"
2017-05-18 21:52:31 +02:00
" M;\n"
"}");
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:3]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable a\n"
"[test.cpp:4]: (debug) valueflow.cpp:1260:(valueFlow) bailout: variable 'x', condition is defined in macro\n",
errout.str());
bailout("#define FREE(obj) ((obj) ? (free((char *) (obj)), (obj) = 0) : 0)\n" // #8349
"void f(int *x) {\n"
" a = x;\n"
" FREE(x);\n"
"}");
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:3]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable a\n"
"[test.cpp:4]: (debug) valueflow.cpp:1260:(valueFlow) bailout: variable 'x', condition is defined in macro\n",
errout.str());
}
2014-01-13 16:07:25 +01:00
2014-11-20 14:20:09 +01:00
void valueFlowBeforeConditionGoto() {
2014-01-13 16:07:25 +01:00
// bailout: goto label (TODO: handle gotos more intelligently)
bailout("void f(int x) {\n"
" if (x == 123) { goto out; }\n"
" a=x;\n" // <- x is not 123
"out:"
" if (x==123){}\n"
"}");
ASSERT_EQUALS_WITHOUT_LINENUMBERS(
"[test.cpp:3]: (debug) valueflow.cpp::valueFlowConditionExpressions bailout: Skipping function due to incomplete variable a\n"
"[test.cpp:2]: (debug) valueflow.cpp::(valueFlow) bailout: valueFlowAfterCondition: bailing in conditional block\n",
errout.str());
// #5721 - FP
bailout("static void f(int rc) {\n"
" ABC* abc = getabc();\n"
" if (!abc) { goto out };\n"
"\n"
" abc->majortype = 0;\n"
" if (FAILED(rc)) {}\n"
"\n"
"out:\n"
" if (abc) {}\n"
"}");
}
2019-10-05 15:42:47 +02:00
void valueFlowBeforeConditionForward() {
const char* code;
code = "void f(int a) {\n"
" int x = a;\n"
" if (a == 123) {}\n"
" int b = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f(int a) {\n"
" int x = a;\n"
" if (a != 123) {}\n"
" int b = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
}
void valueFlowBeforeConditionConstructor()
{
const char* code;
code = "struct Fred {\n"
" Fred(int *x)\n"
" : i(*x) {\n" // <- dereference x
" if (!x) {}\n" // <- check x
" }\n"
" int i;\n"
"};\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "struct Fred {\n"
" Fred(int *x)\n"
" : i(*x), j(0) {\n" // <- dereference x
" if (!x) {}\n" // <- check x
" }\n"
" int i;\n"
" int j;\n"
"};\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
}
2014-11-20 14:20:09 +01:00
void valueFlowAfterAssign() {
const char *code;
code = "void f() {\n"
" int x = 123;\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
2016-12-19 21:21:18 +01:00
code = "void f() {\n"
" bool x = 32;\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
code = "void f() {\n"
" int x = 123;\n"
" a = sizeof(x);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
code = "void f() {\n"
" int x = 123;\n"
" a = 2 + x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f() {\n"
" const int x(321);\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 321));
code = "void f() {\n"
" int x = 9;\n"
" --x;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 9));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 8));
ASSERT_EQUALS("2,Assignment 'x=9', assigned value is 9\n"
"3,x is decremented', new value is 8\n",
getErrorPathForX(code, 4U));
code = "void x() {\n"
" int x = value ? 6 : 0;\n"
" x =\n"
" 1 + x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 7));
code = "void f() {\n"
" int x = 0;\n"
" y = x += z;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" static int x = 2;\n"
" x++;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 2));
code = "void f() {\n"
" static int x = 2;\n"
" a >> x;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 2));
code = "void f() {\n"
" static int x = 0;\n"
" if (x==0) x = getX();\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
// truncation
code = "int f() {\n"
" int x = 1.5;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
code = "int f() {\n"
" unsigned char x = 0x123;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0x23));
code = "int f() {\n"
" signed char x = 0xfe;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, -2));
// function
code = "void f() {\n"
" char *x = 0;\n"
" int success = getx((char**)&x);\n"
" if (success) x[0] = 0;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" char *x = 0;\n"
" getx(reinterpret_cast<void **>(&x));\n"
" *x = 0;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
// lambda
code = "void f() {\n"
" int x = 0;\n"
" Q q = [&]() {\n"
" if (x > 0) {}\n"
" x++;\n"
" };\n"
" dosomething(q);\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" int x = 0;\n"
" dostuff([&]() {\n"
" if (x > 0) {}\n"
" x++;\n"
" });\n"
" dosomething(q);\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "int f() {\n"
" int x = 1;\n"
" dostuff([&]() {\n"
" x = y;\n"
" });\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 1));
// ?:
code = "void f() {\n"
" int x = 8;\n"
" a = ((x > 10) ?\n"
" x : 0);\n" // <- x is not 8
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 8));
code = "void f() {\n" // #6973
" char *x = \"\";\n"
" a = ((x[0] == 'U') ?\n"
" x[1] : 0);\n" // <- x is not ""
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, "\"\"", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n" // #6973
" char *x = getenv (\"LC_ALL\");\n"
" if (x == NULL)\n"
" x = \"\";\n"
"\n"
" if ( (x[0] == 'U') &&\n" // x can be ""
" (x[1] ?\n" // x can't be ""
" x[3] :\n" // x can't be ""
" x[2] ))\n" // x can't be ""
" {}\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 6U, "\"\"", ValueFlow::Value::ValueType::TOK));
ASSERT_EQUALS(false, testValueOfX(code, 7U, "\"\"", ValueFlow::Value::ValueType::TOK));
ASSERT_EQUALS(false, testValueOfX(code, 8U, "\"\"", ValueFlow::Value::ValueType::TOK));
ASSERT_EQUALS(false, testValueOfX(code, 9U, "\"\"", ValueFlow::Value::ValueType::TOK));
code = "void f() {\n" // #7599
" t *x = 0;\n"
" y = (a ? 1 : x\n" // <- x is 0
" && x->y ? 1 : 2);" // <- x is not 0
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n" // #7599
" t *x = 0;\n"
" y = (a ? 1 : !x\n" // <- x is 0
" || x->y ? 1 : 2);" // <- x is not 0
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
// if/else
code = "void f() {\n"
" int x = 123;\n"
" if (condition) return;\n"
" a = 2 + x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f() {\n"
" int x = 1;\n"
" if (condition) x = 2;\n"
" a = 2 + x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 1));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 2));
code = "void f() {\n"
" int x = 123;\n"
" if (condition1) x = 456;\n"
" if (condition2) x = 789;\n"
" a = 2 + x;\n" // <- either assignment "x=123" is redundant or x can be 123 here.
"}";
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 5U, 123));
code = "void f(int a) {\n"
" int x = 123;\n"
" if (a > 1)\n"
" ++x;\n"
" else\n"
" ++x;\n"
" return 2 + x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f() {\n"
" int x = 1;\n"
" if (condition1) x = 2;\n"
" else return;\n"
" a = 2 + x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 1));
code = "void f(){\n"
" int x = 0;\n"
" if (a>=0) { x = getx(); }\n"
" if (x==0) { return; }\n"
" return 123 / x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
code = "void f() {\n"
" X *x = getx();\n"
" if(0) { x = 0; }\n"
" else { x->y = 1; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n" // #6239
" int x = 4;\n"
" if(1) { x = 0; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 4));
code = "void f() {\n"
" int x = 32;\n"
" if (x>=32) return;\n"
" a[x]=0;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 32));
code = "void f() {\n"
" int x = 32;\n"
" if (x>=32) {\n"
" a[x] = 0;\n" // <- should have possible value 32
" return;\n"
" }\n"
"}";
2014-06-15 17:15:09 +02:00
ASSERT_EQUALS(true, testValueOfX(code, 4U, 32));
code = "void f() {\n"
" int x = 33;\n"
" if (x==33) goto fail;\n"
" a[x]=0;\n"
"fail:\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 33));
code = "void f() {\n"
" int x = 32;\n"
" if (a==1) { z=x+12; }\n"
" if (a==2) { z=x+32; }\n"
" z = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 32));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 32));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 32));
code = "void f() {\n" // #5656 - FP
" int x = 0;\n"
" if (!x) {\n"
" x = getx();\n"
" }\n"
" y = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 0));
code = "void f(int y) {\n" // alias
" int x = y;\n"
" if (y == 54) {}\n"
" else { a = x; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 54));
code = "void f () {\n"
" ST * x = g_pST;\n"
" if (x->y == 0) {\n"
" x = NULL;\n"
" return 1;\n"
" }\n"
" a = x->y;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 0));
code = "void f () {\n"
" ST * x = g_pST;\n"
" if (x->y == 0) {\n"
" x = NULL;\n"
" goto label;\n"
" }\n"
" a = x->y;\n"
"label:\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 0));
code = "void f() {\n" // #5752 - FP
" int *x = 0;\n"
" if (x && *x == 123) {\n"
" getx(*x);\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" int x = 0;\n"
" if (!x) {}\n"
" else { y = x; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n" // #6118 - FP
" int x = 0;\n"
" x = x & 0x1;\n"
" if (x == 0) { x = 2; }\n"
" y = 42 / x;\n" // <- x is 2
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 2));
code = "void f() {\n" // #6118 - FN
" int x = 0;\n"
" x = x & 0x1;\n"
" if (x == 0) { x += 2; }\n"
" y = 42 / x;\n" // <- x is 2
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 2));
code = "void f(int mode) {\n"
" struct ABC *x;\n"
"\n"
" if (mode) { x = &y; }\n"
" else { x = NULL; }\n"
"\n"
" if (!x) exit(1);\n"
"\n"
" a = x->a;\n" // <- x can't be 0
"}";
ASSERT_EQUALS(false, testValueOfX(code, 9U, 0));
code = "void f(int i) {\n"
2018-07-25 23:02:16 +02:00
" bool x = false;\n"
" if (i == 0) { x = true; }\n"
" else if (x && i == 1) {}\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
code = "void f(int i) {\n"
2018-07-25 23:02:16 +02:00
" bool x = false;\n"
" while(i > 0) {\n"
" i++;\n"
" if (i == 0) { x = true; }\n"
" else if (x && i == 1) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 6U, 0));
// multivariables
code = "void f(int a) {\n"
" int x = a;\n"
" if (a!=132) { b = x; }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 132));
code = "void f(int a) {\n"
" int x = a;\n"
" b = x;\n" // <- line 3
" if (a!=132) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 132));
code = "void f() {\n"
" int a;\n"
" if (n) { a = n; }\n"
" else { a = 0; }\n"
" int x = a;\n"
" if (a > 0) { a = b / x; }\n" // <- line 6
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 0)); // x is not 0 at line 6
2014-08-27 17:11:38 +02:00
code = "void f(int x1) {\n" // #6086
" int x = x1;\n"
" if (x1 >= 3) {\n"
" return;\n"
" }\n"
" a = x;\n" // <- x is not 3
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 3));
code = "int f(int *x) {\n" // #5980
" if (!x) {\n"
" switch (i) {\n"
" default:\n"
" throw std::runtime_error(msg);\n"
" };\n"
" }\n"
" return *x;\n" // <- x is not 0
"}";
ASSERT_EQUALS(false, testValueOfX(code, 8U, 0));
code = "void f(int a) {\n" // #6826
" int x = a ? a : 87;\n"
" if (a && x) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 87));
code = "void f() {\n"
" int first=-1, x=0;\n"
" do {\n"
" if (first >= 0) { a = x; }\n" // <- x is not 0
" first++; x=3;\n"
" } while (1);\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 3));
// pointer/reference to x
code = "int f(void) {\n"
" int x = 2;\n"
" int *px = &x;\n"
" for (int i = 0; i < 1; i++) {\n"
" *px = 1;\n"
" }\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 2));
code = "int f(void) {\n"
" int x = 5;\n"
" int &rx = x;\n"
" for (int i = 0; i < 1; i++) {\n"
" rx = 1;\n"
" }\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 5));
// break
code = "void f() {\n"
" for (;;) {\n"
" int x = 1;\n"
" if (!abc()) {\n"
" x = 2;\n"
" break;\n"
" }\n"
" a = x;\n" // <- line 8
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 8U, 2)); // x is not 2 at line 8
code = "void f() {\n"
" int x;\n"
" switch (ab) {\n"
" case A: x = 12; break;\n"
" case B: x = 34; break;\n"
" }\n"
" v = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 7U, 12));
ASSERT_EQUALS(true, testValueOfX(code, 7U, 34));
code = "void f() {\n" // #5981
" int x;\n"
" switch (ab) {\n"
" case A: x = 12; break;\n"
" case B: x = 34; break;\n"
" }\n"
" switch (ab) {\n"
" case A: v = x; break;\n" // <- x is not 34
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 8U, 34));
// while/for
code = "void f() {\n" // #6138
" ENTRY *x = 0;\n"
" while (x = get()) {\n"
" set(x->value);\n" // <- x is not 0
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f(const int *buf) {\n"
" int x = 0;\n"
" for (int i = 0; i < 10; i++) {\n"
" if (buf[i] == 123) {\n"
" x = i;\n"
" break;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can be 0
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 9U, 0)); // x can be 0 at line 9
code = "void f(const int *buf) {\n"
" int x = 111;\n"
" bool found = false;\n"
" for (int i = 0; i < 10; i++) {\n"
" if (buf[i] == 123) {\n"
" x = i;\n"
" found = true;\n"
" break;\n"
" }\n"
" }\n"
" if (found)\n"
" a = x;\n" // <- x can't be 111
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 12U, 111)); // x can not be 111 at line 9
code = "void f(const int *buf) {\n"
" int x = 0;\n"
" for (int i = 0; i < 10; i++) {\n"
" if (buf[i] == 123) {\n"
" x = i;\n"
" ;\n" // <- no break
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 9U, 0)); // x can be 0 at line 9
ASSERT_EQUALS(false, testValueOfXKnown(code, 9U, 0)); // x can't be known at line 9
code = "void f(const int *buf) {\n"
" int x = 0;\n"
" for (int i = 0; i < 10; i++) {\n"
" if (buf[i] == 123) {\n"
" x = i;\n"
" ;\n" // <- no break
" } else {\n"
" x = 1;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 11U, 0)); // x can't be 0 at line 11
code = "void f(const int *buf) {\n"
" int i = 0;\n"
" int x = 0;\n"
" while (++i < 10) {\n"
" if (buf[i] == 123) {\n"
" x = i;\n"
" break;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can be 0
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 10U, 0)); // x can be 0 at line 9
code = "bool maybe();\n"
"void f() {\n"
" int x = 0;\n"
" bool found = false;\n"
" while(!found) {\n"
" if (maybe()) {\n"
" x = i;\n"
" found = true;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 11U, 0));
code = "bool maybe();\n"
"void f() {\n"
" int x = 0;\n"
" bool found = false;\n"
" while(!found) {\n"
" if (maybe()) {\n"
" x = i;\n"
" found = true;\n"
" } else {\n"
" found = false;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 13U, 0));
code = "bool maybe();\n"
"void f() {\n"
" int x = 0;\n"
" bool found = false;\n"
" while(!found) {\n"
" if (maybe()) {\n"
" x = i;\n"
" break;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 11U, 0));
code = "bool maybe();\n"
"void f() {\n"
" int x = 0;\n"
" bool found = false;\n"
" while(!found) {\n"
" if (maybe()) {\n"
" x = i;\n"
" found = true;\n"
" break;\n"
" }\n"
" }\n"
" a = x;\n" // <- x can't be 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 12U, 0));
code = "void f(const int a[]) {\n" // #6616
" const int *x = 0;\n"
" for (int i = 0; i < 10; i = *x) {\n" // <- x is not 0
" x = a[i];\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
// alias
code = "void f() {\n" // #7778
" int x = 0;\n"
" int *p = &x;\n"
" x = 3;\n"
" *p = 2;\n"
" a = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 3));
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 6U, 2));
code = "struct Fred {\n"
" static void Create(std::unique_ptr<Wilma> wilma);\n"
" Fred(std::unique_ptr<Wilma> wilma);\n"
" std::unique_ptr<Wilma> mWilma;\n"
"};\n"
"void Fred::Create(std::unique_ptr<Wilma> wilma) {\n"
" auto fred = std::make_shared<Fred>(std::move(wilma));\n"
" fred->mWilma.reset();\n"
"}\n"
"Fred::Fred(std::unique_ptr<Wilma> wilma)\n"
" : mWilma(std::move(wilma)) {}\n";
ASSERT_EQUALS(0, tokenValues(code, "mWilma (").size());
code = "void g(unknown*);\n"
"int f() {\n"
" int a = 1;\n"
" unknown c[] = {{&a}};\n"
" g(c);\n"
" int x = a;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 7U, 1));
ASSERT_EQUALS(true, testValueOfXInconclusive(code, 7U, 1));
code = "void g(unknown&);\n"
"int f() {\n"
" int a = 1;\n"
" unknown c{&a};\n"
" g(c);\n"
" int x = a;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 7U, 1));
ASSERT_EQUALS(true, testValueOfXInconclusive(code, 7U, 1));
code = "long foo();\n"
"long bar();\n"
"int test() {\n"
" bool b = true;\n"
" long a = foo();\n"
" if (a != 0)\n"
" return 1;\n"
" a = bar();\n"
" if (a != 0)\n"
" b = false;\n"
" int x = b;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 12U, 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 12U, 0));
code = "bool f(unsigned char uc) {\n"
" const bool x = uc;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, 1));
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 1));
code = "struct A {\n"
" int i, j;\n"
" int foo() {\n"
" i = 1;\n"
" j = 2;\n"
" int x = i;\n"
" return x;\n"
" }\n"
"};\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 1));
// global variable
code = "int x;\n"
"int foo(int y) {\n"
" if (y)\n"
" x = 10;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 10));
code = "namespace A { int x; }\n"
"int foo(int y) {\n"
" if (y)\n"
" A::x = 10;\n"
" return A::x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 10));
// member variable
code = "struct Fred {\n"
" int x;\n"
" int foo(int y) {\n"
" if (y)\n"
" x = 10;\n"
" return x;\n"
" }\n"
"};";
ASSERT_EQUALS(true, testValueOfX(code, 6U, 10));
}
void valueFlowAfterSwap()
{
const char* code;
code = "int f() {\n"
" int a = 1;\n"
" int b = 2;\n"
" std::swap(a, b);\n"
" int x = a;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 2));
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 1));
code = "int f() {\n"
" int a = 1;\n"
" int b = 2;\n"
" std::swap(a, b);\n"
" int x = b;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 1));
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 2));
}
2014-11-20 14:20:09 +01:00
void valueFlowAfterCondition() {
const char *code;
// in if
code = "void f(int x) {\n"
" if (x == 123) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x != 123) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x > 123) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 124));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x < 123) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 122));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
// ----
code = "void f(int x) {\n"
" if (123 < x) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 124));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (123 > x) {\n"
" a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 122));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
// in else
code = "void f(int x) {\n"
" if (x == 123) {}\n"
" else a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x != 123) {}\n"
" else a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
// after if
code = "void f(int x) {\n"
" if (x == 10) {\n"
" x++;\n"
" }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 10));
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 5U, 11));
// !
code = "void f(int x) {\n"
" if (!x) { a = x; }\n"
" else a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 0));
code = "void f(int x, int y) {\n"
" if (!(x&&y)) { return; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
code = "void f(int x) {\n"
" if (!x) { { throw new string(); }; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
code = "void f(int x) {\n"
2021-08-07 20:51:18 +02:00
" if (x != 123) { throw " "; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x != 123) { }\n"
2021-08-07 20:51:18 +02:00
" else { throw " "; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
code = "void f(int x) {\n"
" if (x == 123) { }\n"
2021-08-07 20:51:18 +02:00
" else { throw " "; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f(int x) {\n"
" if (x < 123) { }\n"
" else { a = x; }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x < 123) { throw \"\"; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x < 123) { }\n"
" else { throw \"\"; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 122));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
code = "void f(int x) {\n"
" if (x > 123) { }\n"
" else { a = x; }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x > 123) { throw \"\"; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 123));
code = "void f(int x) {\n"
" if (x > 123) { }\n"
" else { throw \"\"; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 124));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
code = "void f(int x) {\n"
" if (x < 123) { return; }\n"
" else { return; }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 124));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
// if (var)
code = "void f(int x) {\n"
" if (x) { a = x; }\n" // <- x is not 0
" else { b = x; }\n" // <- x is 0
" c = x;\n" // <- x might be 0
"}";
ASSERT_EQUALS(false, testValueOfX(code, 2U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
// After while
code = "void f(int x) {\n"
" while (x != 3) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 3));
2014-06-19 17:29:41 +02:00
code = "void f(int x) {\n"
" while (11 != (x = dostuff())) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 11));
code = "void f(int x) {\n"
" while (11 != (x = dostuff()) && y) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 11));
code = "void f(int x) {\n"
" while (x = dostuff()) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "void f(const Token *x) {\n" // #5866
" x = x->next();\n"
" while (x) { x = x->next(); }\n"
" if (x->str()) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
code = "void f(const Token *x) {\n"
" while (0 != (x = x->next)) {}\n"
" x->ab = 0;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "void f(const Token* x) {\n"
" while (0 != (x = x->next)) {}\n"
" if (x->str) {\n" // <- possible value 0
" x = y;\n" // <- this caused some problem
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
// conditional code after if/else/while
code = "void f(int x) {\n"
" if (x == 2) {}\n"
" if (x > 0)\n"
" a = x;\n" // <- TODO, x can be 2
" else\n"
" b = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 2));
ASSERT_EQUALS(false, testValueOfX(code, 6U, 2));
// condition with 2nd variable
code = "void f(int x) {\n"
" int y = 0;\n"
" if (x == 7) { y = 1; }\n"
" if (!y)\n"
" a = x;\n" // <- x can not be 7 here
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 7));
code = "void f(struct X *x) {\n"
" bool b = TRUE;\n"
" if(x) { }\n"
" else\n"
" b = FALSE;\n"
" if (b)\n"
" abc(x->value);\n" // <- x is not 0
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 0));
2014-06-19 17:29:41 +02:00
// In condition, after && and ||
code = "void f(int x) {\n"
" a = (x != 3 ||\n"
" x);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 3));
code = "void f(int x) {\n"
" a = (x == 4 &&\n"
" x);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 4));
// protected usage with &&
code = "void f(const Token* x) {\n"
" if (x) {}\n"
" for (; x &&\n"
" x->str() != y; x = x->next()) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f(const Token* x) {\n"
" if (x) {}\n"
" if (x &&\n"
" x->str() != y) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
// return
code = "void f(int x) {\n" // #6024
" if (x == 5) {\n"
" if (z) return; else return;\n"
" }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 5));
code = "void f(int x) {\n" // #6730
" if (x == 5) {\n"
" if (z) continue; else throw e;\n"
" }\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 5));
// TODO: float
code = "void f(float x) {\n"
" if (x == 0.5) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
// aliased variable
code = "void f() {\n"
" int x = 1;\n"
" int *data = &x;\n"
" if (!x) {\n"
" calc(data);\n"
" a = x;\n" // <- x might be changed by calc
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 0));
code = "int* g();\n"
"int f() {\n"
" int * x;\n"
" x = g();\n"
" if (x) { printf(\"\"); }\n"
" return *x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 6U, 0));
// volatile variable
code = "void foo(const volatile int &x) {\n"
" if (x==1) {\n"
" return x;\n"
" }"
"}";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, 1));
code = "void foo(const std::atomic<int> &x) {\n"
" if (x==2) {\n"
" return x;\n"
" }"
"}";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, 2));
2020-09-11 00:06:49 +02:00
code = "int f(int i, int j) {\n"
" if (i == 0) {\n"
" if (j < 0)\n"
" return 0;\n"
" i = j+1;\n"
" }\n"
" int x = i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 8U, 0));
code = "int f(int i, int j) {\n"
" if (i == 0) {\n"
" if (j < 0)\n"
" return 0;\n"
" if (j < 0)\n"
" i = j+1;\n"
" }\n"
" int x = i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 9U, 0));
code = "void g(long& a);\n"
"void f(long a) {\n"
" if (a == 0)\n"
" return;\n"
" if (a > 1)\n"
" g(a);\n"
" int x = a;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 8U, 0));
code = "int foo(int n) {\n"
" if( n>= 8 ) {\n"
" while(true) {\n"
" n -= 8;\n"
" if( n < 8 )\n"
" break;\n"
" }\n"
" int x = n == 0;\n"
" return x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 9U, 0));
code = "bool c();\n"
"long f() {\n"
" bool stop = false;\n"
" while (!stop) {\n"
" if (c())\n"
" stop = true;\n"
" break;\n"
" }\n"
" int x = !stop;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 10U, 1));
ASSERT_EQUALS(false, testValueOfXKnown(code, 10U, 0));
code = "int f(int a, int b) {\n"
" if (!a && !b)\n"
" return;\n"
" if ((!a && b) || (a && !b))\n"
" return;\n"
" int x = a;\n" // <- a is _not_ 0
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 0));
code = "void f(int x, int y) {\n"
" if (x && y)\n"
" return;\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 4U, 1));
code = "int f(std::vector<int> a, std::vector<int> b) {\n"
" if (a.empty() && b.empty())\n"
" return 0;\n"
" bool x = a.empty() && !b.empty();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 5U, 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 5U, 1));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 5U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 5U, 1));
code = "auto f(int i) {\n"
" if (i == 0) return;\n"
" auto x = !i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, 1));
code = "auto f(int i) {\n"
" if (i == 1) return;\n"
" auto x = !i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 4U, 0));
code = "int g(int x) {\n"
" switch (x) {\n"
" case 1:\n"
" return 1;\n"
" default:\n"
" return 2;\n"
" }\n"
"}\n"
"void f(int x) {\n"
" if (x == 3)\n"
" x = g(0);\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 12U, 3));
code = "long long f(const long long& x, const long long& y) {\n"
" switch (s) {\n"
" case 0:\n"
" if (x >= 64)\n"
" return 0;\n"
" return (long long)y << (long long)x;\n"
" case 1:\n"
" if (x >= 64) {\n"
" }\n"
" }\n"
" return 0; \n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 6U, 63));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 6U, 64));
code = "long long f(const long long& x, const long long& y) {\n"
" switch (s) {\n"
" case 0:\n"
" if (x >= 64)\n"
" return 0;\n"
" return long long(y) << long long(x);\n"
" case 1:\n"
" if (x >= 64) {\n"
" }\n"
" }\n"
" return 0; \n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 6U, 63));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 6U, 64));
code = "long long f(const long long& x, const long long& y) {\n"
" switch (s) {\n"
" case 0:\n"
" if (x >= 64)\n"
" return 0;\n"
" return long long{y} << long long{x};\n"
" case 1:\n"
" if (x >= 64) {\n"
" }\n"
" }\n"
" return 0; \n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 6U, 63));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 6U, 64));
code = "int g(int x) { throw 0; }\n"
"void f(int x) {\n"
" if (x == 3)\n"
" x = g(0);\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 5U, 3));
code = "struct a {\n"
" a *b() const;\n"
" void c();\n"
"};\n"
"void e(a *x) {\n"
" while (x && x->b())\n"
" x = x->b();\n"
" x->c();\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 8U, 0));
code = "struct a {\n"
" a *b();\n"
" void c();\n"
"};\n"
"void e(a *x) {\n"
" while (x && x->b())\n"
" x = x->b();\n"
" x->c();\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 8U, 0));
code = "constexpr int f();\n"
"int g() {\n"
" if (f() == 1) {\n"
" int x = f();\n"
" return x;\n"
" }\n"
" return 0;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
code = "int f(int x) {\n"
" if (x == 1) {\n"
" for(int i=0;i<1;i++) {\n"
" if (x == 1)\n"
" continue;\n"
" }\n"
" }\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 8U, 1));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 8U, 1));
}
2019-09-26 10:32:49 +02:00
void valueFlowAfterConditionExpr() {
const char* code;
code = "void f(int* p) {\n"
" if (p[0] == 123) {\n"
" int x = p[0];\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f(int y) {\n"
" if (y+1 == 123) {\n"
" int x = y+1;\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f(int y) {\n"
" if (y+1 == 123) {\n"
" int x = y+2;\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 124));
code = "void f(int y, int z) {\n"
" if (y+z == 123) {\n"
" int x = y+z;\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123));
code = "void f(int y, int z) {\n"
" if (y+z == 123) {\n"
" y++;\n"
" int x = y+z;\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 123));
code = "void f(int y) {\n"
" if (y++ == 123) {\n"
" int x = y++;\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 124));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 125));
code = "struct A {\n"
" bool g() const;\n"
"};\n"
"void f(A a) {\n"
" if (a.g()) {\n"
" bool x = a.g();\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 7U, 0));
code = "struct A {\n"
" bool g() const;\n"
"};\n"
"void f(A a) {\n"
" if (a.g()) {\n"
" bool x = !a.g();\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 0));
code = "struct A {\n"
" bool g() const;\n"
"};\n"
"void f(A a) {\n"
" if (!a.g()) {\n"
" bool x = a.g();\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 0));
code = "void f(std::vector<int> v) {\n"
" if (v.size() == 3) {\n"
" if (v.size() == 1) {\n"
" int x = 1;\n"
" int a = x;\n"
" }\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
}
void valueFlowAfterConditionSeveralNot() {
const char *code;
code = "int f(int x, int y) {\n"
" if (x!=0) {}\n"
" return y/x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
2019-05-30 14:41:14 +02:00
code = "int f(int x, int y) {\n"
" if (!!(x != 0)) {\n"
" return y/x;\n"
"}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
code = "int f(int x, int y) {\n"
" if (!!!(x != 0)) {\n"
" return y/x;\n"
"}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "int f(int x, int y) {\n"
" if (!!!!(x != 0)) {\n"
" return y/x;\n"
"}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
}
void valueFlowForwardCompoundAssign() {
const char *code;
code = "void f() {\n"
" int x = 123;\n"
" x += 43;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 166));
ASSERT_EQUALS("2,Assignment 'x=123', assigned value is 123\n"
"3,Compound assignment '+=', assigned value is 166\n",
getErrorPathForX(code, 4U));
2017-08-23 17:52:28 +02:00
code = "void f() {\n"
" int x = 123;\n"
" x /= 0;\n" // don't crash when evaluating x/=0
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 123));
code = "void f() {\n"
" float x = 123.45;\n"
" x += 67;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 123.45F + 67, 0.01F));
code = "void f() {\n"
" int x = 123;\n"
" x >>= 1;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 61));
code = "void f() {\n"
" int x = 123;\n"
" x <<= 1;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 246));
}
void valueFlowForwardCorrelatedVariables() {
const char *code;
code = "void f(int x = 0) {\n"
" bool zero(x==0);\n"
" if (zero) a = x;\n" // <- x is 0
" else b = x;\n" // <- x is not 0
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "int g();\n"
"int f(bool i, bool j) {\n"
" if (i && j) {}\n"
" else {\n"
" int x = 0;\n"
" if (i)\n"
" x = g();\n"
" return x;\n"
" }\n"
" return 0;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 8U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 8U, 0));
}
void valueFlowForwardModifiedVariables() {
const char *code;
code = "void f(bool b) {\n"
" int x = 0;\n"
" if (b) x = 1;\n"
" else b = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f(int i) {\n"
" int x = 0;\n"
" if (i == 0)\n"
" x = 1;\n"
" else if (!x && i == 1)\n"
" int b = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 0));
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 0));
}
void valueFlowForwardFunction() {
const char *code;
code = "class C {\n"
"public:\n"
" C(int &i);\n" // non-const argument => might be changed
"};\n"
"int f() {\n"
" int x=1;\n"
" C c(x);\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 8U, 1));
code = "class C {\n"
"public:\n"
" C(const int &i);\n" // const argument => is not changed
"};\n"
"int f() {\n"
" int x=1;\n"
" C c(x);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 8U, 1));
code = "int f(int *);\n"
"int g() {\n"
" const int a = 1;\n"
" int x = 11;\n"
" c = (a && f(&x));\n"
" if (x == 42) {}\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 11));
}
void valueFlowForwardTernary() {
const char *code;
code = "int f() {\n"
" int x=5;\n"
" a = b ? init1(&x) : init2(&x);\n"
" return 1 + x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 5));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 5));
code = "int f(int *p) {\n" // #9008 - gcc ternary ?:
" if (p) return;\n"
" x = *p ? : 1;\n" // <- no explicit expr0
"}";
testValueOfX(code, 1U, 0); // do not crash
code = "void f(int a) {\n" // #8784
" int x = 13;\n"
" if (a == 1) x = 26;\n"
" return a == 1 ? x : 0;\n" // <- x is 26
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 13));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 26));
code = "void f(int* i) {\n"
" if (!i) return;\n"
" int * x = *i == 1 ? i : nullptr;\n"
" int* a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 4U, 0));
}
void valueFlowForwardLambda() {
const char *code;
code = "void f() {\n"
" int x=1;\n"
" auto f = [&](){ a=x; }\n" // x is not 1
" x = 2;\n"
" f();\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 1));
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 3U, 2));
code = "void f() {\n"
" int x=3;\n"
" auto f = [&](){ a=x; }\n" // todo: x is 3
" f();\n"
"}";
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 3U, 3));
code = "void f() {\n"
" int x=3;\n"
" auto f = [&](){ x++; }\n"
" x = 1;\n"
" f();\n"
" int a = x;\n" // x is actually 2
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 1));
ASSERT_EQUALS(false, testValueOfX(code, 6U, 3));
}
void valueFlowForwardTryCatch() {
const char *code;
code = "void g1();\n"
"void g2();\n"
"void f()\n {"
" bool x = false;\n"
" try {\n"
" g1();\n"
" x = true;\n"
" g2();\n"
" }\n"
" catch (...) {\n"
" if (x) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 11U, 1));
ASSERT_EQUALS(false, testValueOfXKnown(code, 11U, 1));
code = "void g1();\n"
"void g2();\n"
"void f()\n {"
" bool x = true;\n"
" try {\n"
" g1();\n"
" g2();\n"
" }\n"
" catch (...) {\n"
" if (x) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 10U, 1));
}
2014-11-20 14:20:09 +01:00
void valueFlowBitAnd() {
const char *code;
code = "int f(int a) {\n"
" int x = a & 0x80;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code,3U,0));
ASSERT_EQUALS(true, testValueOfX(code,3U,0x80));
code = "int f(int a) {\n"
" int x = a & 0x80 ? 1 : 2;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code,3U,0));
ASSERT_EQUALS(false, testValueOfX(code,3U,0x80));
code = "int f() {\n"
" int x = (19 - 3) & 15;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code,3U,0));
ASSERT_EQUALS(false, testValueOfX(code,3U,16));
}
void valueFlowForwardInconclusiveImpossible() {
const char *code;
code = "void foo() {\n"
" bool valid = f1();\n"
" if (!valid) return;\n"
" std::tie(endVal, valid) = f2();\n"
" bool x = !valid;"
" bool b = x;" // <- not always true
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 1));
}
void valueFlowForwardConst()
{
const char* code;
code = "int f() {\n"
" const int i = 2;\n"
" const int x = i+1;\n"
" goto end;\n"
"end:\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 3));
code = "int f() {\n"
" int i = 2;\n"
" const int& x = i;\n"
" i++;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 2));
code = "int f(int a, int b, int c) {\n"
" const int i = 2;\n"
" const int x = i+1;\n"
" if (a == x) { return 0; }\n"
" if (b == x) { return 0; }\n"
" if (c == x) { return 0; }\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 3));
code = "int f(int a, int b, int c) {\n"
" const int i = 2;\n"
" const int y = i+1;\n"
" const int& x = y;\n"
" if (a == x) { return 0; }\n"
" if (b == x) { return 0; }\n"
" if (c == x) { return 0; }\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 8U, 3));
code = "int f(int a, int b, int c, int x) {\n"
" const int i = 2;\n"
" const int y = i+1;\n"
" if (a == y) { return 0; }\n"
" if (b == y) { return 0; }\n"
" if (c == y) { return 0; }\n"
" if (x == y)\n"
" return x;\n"
" return 0;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 8U, 3));
}
void valueFlowRightShift() {
const char *code;
/* Set some temporary fixed values to simplify testing */
const Settings settingsTmp = settings;
settings.int_bit = 32;
settings.long_bit = 64;
settings.long_long_bit = MathLib::bigint_bits * 2;
code = "int f(int a) {\n"
" int x = (a & 0xff) >> 16;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code,3U,0));
code = "int f(unsigned int a) {\n"
" int x = (a % 123) >> 16;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code,3U,0));
code = "int f(int y) {\n"
" int x = (y & 0xFFFFFFF) >> 31;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3u, 0));
code = "int f(int y) {\n"
" int x = (y & 0xFFFFFFF) >> 32;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
code = "int f(short y) {\n"
" int x = (y & 0xFFFFFF) >> 31;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3u, 0));
code = "int f(short y) {\n"
" int x = (y & 0xFFFFFF) >> 32;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
code = "int f(long y) {\n"
" int x = (y & 0xFFFFFF) >> 63;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3u, 0));
code = "int f(long y) {\n"
" int x = (y & 0xFFFFFF) >> 64;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
code = "int f(long long y) {\n"
" int x = (y & 0xFFFFFF) >> 63;\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3u, 0));
code = "int f(long long y) {\n"
" int x = (y & 0xFFFFFF) >> 64;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
code = "int f(long long y) {\n"
" int x = (y & 0xFFFFFF) >> 121;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
code = "int f(long long y) {\n"
" int x = (y & 0xFFFFFF) >> 128;\n"
" return x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 3u, 0));
settings = settingsTmp;
}
void valueFlowFwdAnalysis() {
const char *code;
std::list<ValueFlow::Value> values;
code = "void f() {\n"
" struct Foo foo;\n"
" foo.x = 1;\n"
" x = 0 + foo.x;\n" // <- foo.x is 1
"}";
values = removeSymbolic(tokenValues(code, "+"));
ASSERT_EQUALS(1U, values.size());
ASSERT_EQUALS(true, values.front().isKnown());
ASSERT_EQUALS(true, values.front().isIntValue());
ASSERT_EQUALS(1, values.front().intvalue);
code = "void f() {\n"
" S s;\n"
" s.x = 1;\n"
" int y = 10;\n"
" while (s.x < y)\n" // s.x does not have known value
" s.x++;\n"
"}";
values = tokenValues(code, "<");
ASSERT_EQUALS(1, values.size());
ASSERT(values.front().isPossible());
2021-02-23 08:19:05 +01:00
ASSERT_EQUALS(1, values.front().intvalue);
code = "void f() {\n"
" S s;\n"
" s.x = 37;\n"
" int y = 10;\n"
" while (s.x < y)\n" // s.x has a known value
" y--;\n"
"}";
values = tokenValues(code, ". x <");
ASSERT(values.size() == 1 &&
values.front().isKnown() &&
values.front().isIntValue() &&
values.front().intvalue == 37);
code = "void f() {\n"
" Hints hints;\n"
" hints.x = 1;\n"
" if (foo)\n"
" hints.x = 2;\n"
" x = 0 + foo.x;\n" // <- foo.x is possible 1, possible 2
"}";
values = removeSymbolic(tokenValues(code, "+"));
TODO_ASSERT_EQUALS(2U, 0U, values.size()); // should be 2
// FP: Condition '*b>0' is always true
code = "bool dostuff(const char *x, const char *y);\n"
"void fun(char *s, int *b) {\n"
" for (int i = 0; i < 42; ++i) {\n"
" if (dostuff(s, \"1\")) {\n"
" *b = 1;\n"
" break;\n"
" }\n"
" }\n"
" if (*b > 0) {\n" // *b does not have known value
" }\n"
"}";
values = tokenValues(code, ">");
ASSERT_EQUALS(1, values.size());
ASSERT(values.front().isPossible());
2021-02-23 08:19:05 +01:00
ASSERT_EQUALS(1, values.front().intvalue);
code = "void foo() {\n"
" struct ISO_PVD_s pvd;\n"
" pvd.descr_type = 0xff;\n"
" do {\n"
" if (pvd.descr_type == 0xff) {}\n"
" dostuff(&pvd);\n"
" } while (condition)\n"
"}";
values = tokenValues(code, "==");
ASSERT_EQUALS(1, values.size());
ASSERT(values.front().isPossible());
ASSERT_EQUALS(1, values.front().intvalue);
// for loops
code = "struct S { int x; };\n" // #9036
"void foo(struct S s) {\n"
" for (s.x = 0; s.x < 127; s.x++) {}\n"
"}";
values = tokenValues(code, "<"); // TODO: comparison can be true or false
ASSERT_EQUALS(true, values.empty());
}
void valueFlowSwitchVariable() {
const char *code;
code = "void f(int x) {\n"
" a = x - 1;\n" // <- x can be 14
" switch (x) {\n"
" case 14: a=x+2; break;\n" // <- x is 14
" };\n"
" a = x;\n" // <- x can be 14
"}";
ASSERT_EQUALS(true, testConditionalValueOfX(code, 2U, 14));
TODO_ASSERT_EQUALS(true, false, testConditionalValueOfX(code, 4U, 14));
TODO_ASSERT_EQUALS(true, false, testConditionalValueOfX(code, 6U, 14));
ValueFlow::Value value1 = valueOfTok(code, "-");
ASSERT_EQUALS(13, value1.intvalue);
ASSERT(!value1.isKnown());
ValueFlow::Value value2 = valueOfTok(code, "+");
TODO_ASSERT_EQUALS(16, 0, value2.intvalue);
TODO_ASSERT_EQUALS(true, false, value2.isKnown());
}
2014-11-20 14:20:09 +01:00
void valueFlowForLoop() {
2014-01-10 16:51:58 +01:00
const char *code;
ValueFlow::Value value;
2014-01-10 16:51:58 +01:00
code = "void f() {\n"
" for (int x = 0; x < 10; x++)\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 9));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 10));
code = "void f() {\n"
" int x;\n"
" for (x = 2; x < 1; x++)\n"
" a[x] = 0;\n" // <- not 2
" b = x;\n" // 2
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 2));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 2));
code = "void f() {\n"
" int x;\n"
" for (x = 2; x < 1; ++x)\n"
" a[x] = 0;\n" // <- not 2
" b = x;\n" // 2
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 2));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 2));
code = "enum AB {A,B};\n" // enum => handled by valueForLoop2
"void f() {\n"
" int x;\n"
" for (x = 1; x < B; ++x)\n"
" a[x] = 0;\n" // <- not 1
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 1));
code = "void f(int a) {\n"
" for (int x = a; x < 10; x++)\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 9));
code = "void f() {\n"
" for (int x = 0; x < 5; x += 2)\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 4));
code = "void f() {\n"
" for (int x = 0; x < 10; x = x + 2)\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 8));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 10));
code = "void f() {\n"
" for (int x = 0; x < 10; x = x / 0)\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0)); // don't crash
code = "void f() {\n"
" for (int x = 0; x < 10; x++)\n"
" x<4 ?\n"
" a[x] : 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 9));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 9));
code = "void f() {\n"
" for (int x = 0; x < 10; x++)\n"
" x==0 ?\n"
" 0 : a[x];\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n" // #5223
" for (int x = 0; x < 300 && x < 18; x++)\n"
" x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 17));
ASSERT_EQUALS(false, testValueOfX(code, 3U, 299));
code = "void f() {\n"
" int x;\n"
" for (int i = 0; x = bar[i]; i++)\n"
" x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" const char abc[] = \"abc\";\n"
" int x;\n"
" for (x = 0; abc[x] != '\\0'; x++) {}\n"
" a[x] = 0;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 3));
code = "void f() {\n" // #5939
" int x;\n"
" for (int x = 0; (x = do_something()) != 0;)\n"
" x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" int x;\n"
" for (int x = 0; x < 10 && y = do_something();)\n"
" x;\n"
"}";
TODO_ASSERT_EQUALS(true, false, testValueOfX(code, 4U, 0));
code = "void f() {\n"
" int x,y;\n"
" for (x = 0, y = 0; x < 10, y < 10; x++, y++)\n" // usage of ,
" x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
code = "void foo(double recoveredX) {\n"
" for (double x = 1e-18; x < 1e40; x *= 1.9) {\n"
" double relativeError = (x - recoveredX) / x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 0));
2018-01-11 14:27:41 +01:00
// Ticket #7139
// "<<" in third expression of for
code = "void f(void) {\n"
" int bit, x;\n"
" for (bit = 1, x = 0; bit < 128; bit = bit << 1, x++) {\n"
" z = x;\n" // <- known value [0..6]
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 6));
ASSERT_EQUALS(false, testValueOfX(code, 4U, 7));
// &&
code = "void foo() {\n"
" for (int x = 0; x < 10; x++) {\n"
" if (x > 1\n"
" && x) {}" // <- x is not 0
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 9));
code = "void foo() {\n"
" for (int x = 0; x < 10; x++) {\n"
" if (x < value\n"
" && x) {}" // <- maybe x is not 9
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 9));
// ||
code = "void foo() {\n"
" for (int x = 0; x < 10; x++) {\n"
" if (x == 0\n"
" || x) {}" // <- x is not 0
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 4U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 4U, 9));
// After loop
code = "void foo() {\n"
" int x;\n"
" for (x = 0; x < 10; x++) {}\n"
" a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 10));
code = "void foo() {\n"
" int x;\n"
" for (x = 0; 2 * x < 20; x++) {}\n"
" a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 10));
code = "void foo() {\n" // related with #887
" int x;\n"
" for (x = 0; x < 20; x++) {}\n"
" a = x++;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 20));
code = "void f() {\n"
" int x;\n"
" for (x = 0; x < 5; x++) {}\n"
" if (x == 5) {\n"
" abort();\n"
" }\n"
" a = x;\n" // <- x can't be 5
"}";
ASSERT_EQUALS(false, testValueOfX(code, 7U, 5));
code = "void f() {\n"
" int x;\n"
" for (x = 0; x < 5; x++) {}\n"
" if (x < 5) {}\n"
" else return;\n"
" a = x;\n" // <- x can't be 5
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 5));
// assert after for loop..
code = "static void f() {\n"
" int x;\n"
" int ctls[10];\n"
" for (x = 0; x <= 10; x++) {\n"
" if (cond)\n"
" break;\n"
" }\n"
" assert(x <= 10);\n"
" ctls[x] = 123;\n" // <- x can't be 11
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 9U, 11));
// hang
code = "void f() {\n"
" for(int i = 0; i < 20; i++)\n"
" n = (int)(i < 10 || abs(negWander) < abs(negTravel));\n"
"}";
testValueOfX(code,0,0); // <- don't hang
// crash (daca@home)
code = "void foo(char *z, int n) {\n"
" int i;\n"
" if (fPScript) {\n"
" i = 1;\n"
" } else if (strncmp(&z[n], \"<!--\", 4) == 0) {\n"
" for (i = 4;;) {\n"
" if (z[n] && strncmp(&z[n+i], \"-->\", 3) == 0) ;\n"
" }\n"
" }\n"
"}";
testValueOfX(code,0,0); // <- don't crash
// conditional code in loop
code = "void f(int mask) {\n" // #6000
" for (int x = 10; x < 14; x++) {\n"
" int bit = mask & (1 << i);\n"
" if (bit) {\n"
" if (bit == (1 << 10)) {}\n"
" else { a = x; }\n" // <- x is not 10
" }\n"
" }\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 6U, 10));
// #7886 - valueFlowForLoop must be called after valueFlowAfterAssign
code = "void f() {\n"
" int sz = 4;\n"
" int x,y;\n"
" for(x=0,y=0; x < sz && y < 10; x++)\n"
" a = x;\n" // <- max value is 3
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 3));
code = "void f() {\n"
" int x;\n"
" for (x = 0; x < 10; x++)\n"
" x;\n"
"}";
std::list<ValueFlow::Value> values = tokenValues(code, "x <");
ASSERT(std::none_of(values.begin(), values.end(), std::mem_fn(&ValueFlow::Value::isUninitValue)));
// #9637
code = "void f() {\n"
" unsigned int x = 0;\n"
" for (x = 0; x < 2; x++) {}\n"
"}\n";
value = valueOfTok(code, "x <");
ASSERT(value.isPossible());
ASSERT_EQUALS(0, value.intvalue);
code = "void f() {\n"
" unsigned int x = 0;\n"
" for (;x < 2; x++) {}\n"
"}\n";
value = valueOfTok(code, "x <");
ASSERT(value.isPossible());
ASSERT_EQUALS(0, value.intvalue);
code = "void f() {\n"
" unsigned int x = 1;\n"
" for (x = 0; x < 2; x++) {}\n"
"}\n";
value = valueOfTok(code, "x <");
ASSERT(!value.isKnown());
}
void valueFlowSubFunction() {
const char *code;
code = "int f(int size) {\n"
" int x = 0;\n"
" if(size>16) {\n"
" x = size;\n"
" int a = x;\n"
" }\n"
" return x;\n"
"}\n"
"void g(){\n"
" f(42);\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 17));
ASSERT_EQUALS(true, testValueOfX(code, 5U, 42));
ASSERT_EQUALS(true, testValueOfX(code, 7U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 7U, 17));
ASSERT_EQUALS(true, testValueOfX(code, 7U, 42));
code = "void g(int, int) {}\n"
"void f(int x, int y) {\n"
" g(x, y);\n"
"}\n"
"void h() {\n"
" f(0, 0);\n"
" f(1, 1);\n"
" f(2, 2);\n"
" f(3, 3);\n"
" f(4, 4);\n"
" f(5, 5);\n"
" f(6, 6);\n"
" f(7, 7);\n"
" f(8, 8);\n"
" f(9, 9);\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 2));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 3));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 4));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 5));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 6));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 7));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 8));
ASSERT_EQUALS(true, testValueOfX(code, 3U, 9));
code = "int f(int i, int j) {\n"
" if (i == j) {\n"
" int x = i;\n"
" return x;\n"
" }\n"
" return 0;\n"
"}\n"
"int g(int x) {\n"
" f(x, -1);\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, -1));
}
2014-11-20 14:20:09 +01:00
void valueFlowFunctionReturn() {
const char *code;
code = "int f1(int x) {\n"
" return x+1;\n"
"}\n"
"void f2() {\n"
" x = 10 - f1(2);\n"
"}";
ASSERT_EQUALS(7, valueOfTok(code, "-").intvalue);
ASSERT_EQUALS(true, valueOfTok(code, "-").isKnown());
code = "int add(int x, int y) {\n"
" return x+y;\n"
"}\n"
"void f2() {\n"
" x = 2 * add(10+1,4);\n"
"}";
ASSERT_EQUALS(30, valueOfTok(code, "*").intvalue);
ASSERT_EQUALS(true, valueOfTok(code, "*").isKnown());
code = "int one() { return 1; }\n"
"void f() { x = 2 * one(); }";
ASSERT_EQUALS(2, valueOfTok(code, "*").intvalue);
ASSERT_EQUALS(true, valueOfTok(code, "*").isKnown());
code = "int add(int x, int y) {\n"
" return x+y;\n"
"}\n"
"void f2() {\n"
" x = 2 * add(1,add(2,3));\n"
"}";
ASSERT_EQUALS(12, valueOfTok(code, "*").intvalue);
ASSERT_EQUALS(true, valueOfTok(code, "*").isKnown());
code = "int f(int i, X x) {\n"
" if (i)\n"
" return g(std::move(x));\n"
" g(x);\n"
" return 0;\n"
"}";
2019-07-10 15:27:07 +02:00
ASSERT_EQUALS(false, testValueOfX(code, 4U, ValueFlow::Value::MoveKind::MovedVariable));
code = "class A\n"
"{\n"
" int f1(int x) {\n"
" return x+1;\n"
" }\n"
" void f2() {\n"
" x = 10 - f1(2);\n"
" }\n"
"};";
ASSERT_EQUALS(7, valueOfTok(code, "-").intvalue);
ASSERT_EQUALS(true, valueOfTok(code, "-").isKnown());
code = "class A\n"
"{\n"
" virtual int f1(int x) {\n"
" return x+1;\n"
" }\n"
" void f2() {\n"
" x = 10 - f1(2);\n"
" }\n"
"};";
ASSERT_EQUALS(7, valueOfTok(code, "-").intvalue);
ASSERT_EQUALS(false, valueOfTok(code, "-").isKnown());
}
void valueFlowFunctionDefaultParameter() {
const char *code;
code = "class continuous_src_time {\n"
" continuous_src_time(std::complex<double> f, double st = 0.0, double et = infinity) {}\n"
"};";
testValueOfX(code, 2U, 2); // Don't crash (#6494)
}
bool isNotKnownValues(const char code[], const char str[]) {
for (const ValueFlow::Value &v : tokenValues(code, str)) {
if (v.isKnown())
return false;
}
return true;
}
void knownValue() {
const char *code;
ValueFlow::Value value;
ASSERT(valueOfTok("x = 1;", "1").isKnown());
// after assignment
code = "void f() {\n"
" int x = 1;\n"
" return x + 2;\n" // <- known value
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(3, value.intvalue);
ASSERT(value.isKnown());
{
code = "void f() {\n"
" int x = 15;\n"
" if (x == 15) { x += 7; }\n" // <- condition is true
"}";
value = valueOfTok(code, "==");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isKnown());
code = "int f() {\n"
" int a = 0, x = 0;\n"
" a = index();\n"
" if (a != 0)\n"
" x = next();\n"
" return x + 1;\n"
"}\n";
value = valueOfTok(code, "+");
ASSERT(value.isPossible());
}
code = "void f() {\n"
" int x;\n"
" if (ab) { x = 7; }\n"
" return x + 2;\n" // <- possible value
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(9, value.intvalue);
ASSERT(value.isPossible());
code = "void f(int c) {\n"
" int x = 0;\n"
" if (c) {} else { x++; }\n"
" return x + 2;\n" // <- possible value
"}";
ASSERT(isNotKnownValues(code, "+"));
code = "void f() {\n"
" int x = 0;\n"
" dostuff(&x);\n"
" if (x < 0) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "void f() {\n"
" int x = 0;\n"
" dostuff(0 ? ptr : &x);\n"
" if (x < 0) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "void f() {\n"
" int x = 0;\n"
" dostuff(unknown ? ptr : &x);\n"
" if (x < 0) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "void f() {\n"
" int x = 0;\n"
" fred.dostuff(x);\n"
" if (x < 0) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "void dostuff(int x);\n"
"void f() {\n"
" int x = 0;\n"
" dostuff(x);\n"
" if (x < 0) {}\n"
"}\n";
value = valueOfTok(code, "<");
ASSERT_EQUALS(0, value.intvalue);
ASSERT(value.isKnown());
code = "void dostuff(int & x);\n"
"void f() {\n"
" int x = 0;\n"
" dostuff(x);\n"
" if (x < 0) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "void dostuff(const int & x);\n"
"void f() {\n"
" int x = 0;\n"
" dostuff(x);\n"
" if (x < 0) {}\n"
"}\n";
value = valueOfTok(code, "<");
ASSERT_EQUALS(0, value.intvalue);
ASSERT(value.isKnown());
code = "void f() {\n"
" int x = 0;\n"
" do {\n"
" if (x < 0) {}\n"
" fred.dostuff(x);\n"
" } while (abc);\n"
"}\n";
ASSERT(isNotKnownValues(code, "<"));
code = "int x;\n"
"void f() {\n"
" x = 4;\n"
" while (1) {\n"
" a = x+2;\n"
" dostuff();\n"
" }\n"
"}";
ASSERT(isNotKnownValues(code, "+"));
code = "void f() {\n"
" int x = 0;\n"
" if (y) { dostuff(x); }\n"
" if (!x) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "!"));
code = "void f() {\n"
" int x = 0;\n"
" MACRO( v, { if (y) { x++; } } );\n"
" if (!x) {}\n"
"}\n";
ASSERT(isNotKnownValues(code, "!"));
code = "void f() {\n"
" int x = 0;\n"
" for (int i = 0; i < 10; i++) {\n"
" if (cond) {\n"
" x = 1;\n"
" break;\n"
" }\n"
" }\n"
" if (!x) {}\n" // <- possible value
"}";
ASSERT(isNotKnownValues(code, "!"));
code = "void f() {\n" // #8356
" bool b = false;\n"
" for(int x = 3; !b && x < 10; x++) {\n" // <- b has known value
" for(int y = 4; !b && y < 20; y++) {}\n"
" }\n"
"}";
value = valueOfTok(code, "!");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isKnown());
code = "void f() {\n"
" int x = 0;\n"
" switch (state) {\n"
" case 1:\n"
" x = 1;\n"
" break;\n"
" }\n"
" if (!x) {}\n" // <- possible value
"}";
ASSERT(isNotKnownValues(code, "!"));
code = "void f() {\n" // #7049
" int x = 0;\n"
" switch (a) {\n"
" case 1:\n"
" x = 1;\n"
" case 2:\n"
" if (!x) {}\n" // <- possible value
" }\n"
"}";
ASSERT(isNotKnownValues(code, "!"));
code = "void f() {\n"
" int x = 0;\n"
" while (!x) {\n" // <- possible value
" scanf(\"%d\", &x);\n"
" }\n"
"}";
value = valueOfTok(code, "!");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isPossible());
code = "void f() {\n"
" int x = 0;\n"
" do { } while (++x < 12);\n" // <- possible value
"}";
ASSERT(isNotKnownValues(code, "<"));
code = "void f() {\n"
" static int x = 0;\n"
" return x + 1;\n" // <- known value
"}\n";
value = valueOfTok(code, "+");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isKnown());
code = "void f() {\n"
" int x = 0;\n"
"a:\n"
" a = x + 1;\n" // <- possible value
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isPossible());
// in conditional code
code = "void f(int x) {\n"
" if (!x) {\n"
" a = x+1;\n" // <- known value
" }\n"
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isKnown());
code = "void f(int x) {\n"
" if (a && 4==x && y) {\n"
" a = x+12;\n" // <- known value
" }\n"
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(16, value.intvalue);
ASSERT(value.isKnown());
// after condition
code = "int f(int x) {\n"
" if (x == 4) {}\n"
" return x + 1;\n" // <- possible value
"}";
value = valueOfTok(code, "+");
ASSERT_EQUALS(5, value.intvalue);
ASSERT(value.isPossible());
code = "int f(int x) {\n"
" if (x < 2) {}\n"
" else if (x >= 2) {}\n" // <- known value
"}";
value = valueOfTok(code, ">=");
ASSERT_EQUALS(1, value.intvalue);
ASSERT(value.isKnown());
code = "int f(int x) {\n"
" if (x < 2) {}\n"
" else if (x > 2) {}\n" // <- possible value
"}";
ASSERT(isNotKnownValues(code, ">"));
// known and possible value
code = "void f() {\n"
" int x = 1;\n"
" int y = 2 + x;\n" // <- known value, don't care about condition
" if (x == 2) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1)); // value of x can be 1
ASSERT_EQUALS(false, testValueOfX(code, 3U, 2)); // value of x can't be 2
code = "bool f() {\n"
" const int s( 4 );"
" return s == 4;\n" // <- known value
"}";
value = valueOfTok(code, "==");
ASSERT(value.isKnown());
ASSERT_EQUALS(1, value.intvalue);
code = "bool f() {\n"
" const int s{ 4 };"
" return s == 4;\n" // <- known value
"}";
value = valueOfTok(code, "==");
ASSERT(value.isKnown());
ASSERT_EQUALS(1, value.intvalue);
code = "bool f() {\n"
" const int s = int( 4 );"
" return s == 4;\n" // <- known value
"}";
value = valueOfTok(code, "==");
ASSERT(value.isKnown());
ASSERT_EQUALS(1, value.intvalue);
code = "bool f() {\n"
" const int s = int{ 4 };"
" return s == 4;\n" // <- known value
"}";
value = valueOfTok(code, "==");
ASSERT(value.isKnown());
ASSERT_EQUALS(1, value.intvalue);
code = "bool f() {\n"
" const int s = int{};"
" return s == 0;\n" // <- known value
"}";
value = valueOfTok(code, "==");
TODO_ASSERT_EQUALS(true, false, value.isKnown());
TODO_ASSERT_EQUALS(1, 0, value.intvalue);
code = "bool f() {\n"
" const int s = int();"
" return s == 0;\n" // <- known value
"}";
value = valueOfTok(code, "==");
TODO_ASSERT_EQUALS(true, false, value.isKnown());
TODO_ASSERT_EQUALS(1, 0, value.intvalue);
// calculation with known result
code = "int f(int x) { a = x & 0; }"; // <- & is 0
value = valueOfTok(code, "&");
ASSERT_EQUALS(0, value.intvalue);
ASSERT(value.isKnown());
// template parameters are not known
code = "template <int X> void f() { a = X; }\n"
"f<1>();";
value = valueOfTok(code, "1");
ASSERT_EQUALS(1, value.intvalue);
ASSERT_EQUALS(false, value.isKnown());
}
void valueFlowSizeofForwardDeclaredEnum() {
const char *code = "enum E; sz=sizeof(E);";
valueOfTok(code, "="); // Don't crash (#7775)
}
void valueFlowGlobalVar() {
const char *code;
code = "int x;\n"
"void f() {\n"
" x = 4;\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 4));
code = "int x;\n"
"void f() {\n"
" if (x == 4) {}\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 4));
code = "int x;\n"
"void f() {\n"
" x = 42;\n"
" unknownFunction();\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 42));
}
2017-03-23 20:01:16 +01:00
void valueFlowGlobalConstVar() {
const char* code;
code = "const int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 321));
code = "void f(const int x = 1) {\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 2U, 1));
code = "volatile const int x = 42;\n"
"void f(){ int a = x; }\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 2U, 42));
code = "static const int x = 42;\n"
"void f(){ int a = x; }\n";
ASSERT_EQUALS(true, testValueOfX(code, 2U, 42));
}
void valueFlowGlobalStaticVar() {
const char *code;
code = "static int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 321));
code = "static int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}"
"void other() { x=a; }\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 321));
code = "static int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}"
"void other() { p = &x; }\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 321));
code = "static int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}"
"void other() { x++; }\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 321));
code = "static int x = 321;\n"
"void f() {\n"
" a = x;\n"
"}"
"void other() { foo(x); }\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 321));
code = "static int x = 1;\n" // compound assignment
"void f() {\n"
" a = x;\n"
"}"
"void other() { x += b; }\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 1));
}
2017-03-23 20:01:16 +01:00
void valueFlowInlineAssembly() {
const char* code = "void f() {\n"
" int x = 42;\n"
" asm(\"\");\n"
" a = x;\n"
"}";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 42));
}
void valueFlowSameExpression() {
const char* code;
code = "void f(int a) {\n"
" bool x = a == a;\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 1));
code = "void f(int a) {\n"
" bool x = a != a;\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "void f(int a) {\n"
" int x = a - a;\n"
" int b = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 0));
code = "void f(float a) {\n"
" bool x = a == a;\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 3U, 1));
}
void valueFlowUninit() {
const char* code;
std::list<ValueFlow::Value> values;
code = "void f() {\n"
" int x;\n"
" switch (x) {}\n"
"}";
values = tokenValues(code, "x )");
ASSERT_EQUALS(true, values.size()==1U && values.front().isUninitValue());
code = "void f() {\n"
" const C *c;\n"
" if (c->x() == 4) {}\n"
"}";
values = tokenValues(code, "c .");
ASSERT_EQUALS(true, values.size()==1U && values.front().isUninitValue());
code = "void f() {\n"
" C *c;\n"
" if (c->x() == 4) {}\n"
"}";
values = tokenValues(code, "c .");
ASSERT_EQUALS(true, values.size()==1U && values.front().isUninitValue());
code = "void f() {\n"
" int **x;\n"
" y += 10;\n"
" x = dostuff(sizeof(*x)*y);\n"
"}";
ASSERT_EQUALS(0U, tokenValues(code, "x )").size());
// #8036
code = "void foo() {\n"
" int x;\n"
" f(x=3), return x+3;\n"
"}";
values = tokenValues(code, "x +");
ASSERT_EQUALS(true, values.empty());
// ASSERT_EQUALS(1U, values.size());
// ASSERT(values.front().isIntValue());
// ASSERT_EQUALS(3, values.front().intvalue);
// #8195
code = "void foo(std::istream &is) {\n"
" int x;\n"
" if (is >> x) {\n"
" a = x;\n"
" }\n"
"}";
values = tokenValues(code, "x ; }");
ASSERT_EQUALS(true, values.empty());
// return (#8173)
code = "int repeat() {\n"
" const char *n;\n"
" return((n=42) && *n == 'A');\n"
"}";
values = tokenValues(code, "n ==");
ASSERT_EQUALS(true, values.empty());
// #8233
code = "void foo() {\n"
" int x;\n"
" int y = 1;\n"
" if (y>1)\n"
" x = 1;\n"
" else\n"
" x = 1;\n"
" if (x>1) {}\n"
"}";
ASSERT_EQUALS(true, testValueOfXKnown(code, 8U, 1));
// #8348 - noreturn else
code = "int test_input_int(int a, int b) {\n"
" int x;\n"
" if (a == 1)\n"
" x = b;\n"
" else\n"
" abort();\n"
" a = x + 1;\n"
"}\n";
values = tokenValues(code, "x +");
values.remove_if(&isNotUninitValue);
ASSERT_EQUALS(true, values.empty());
// #8494 - overloaded operator &
code = "void f() {\n"
" int x;\n"
" a & x;\n"
"}";
values = tokenValues(code, "x ; }");
ASSERT_EQUALS(true, values.empty());
code = "void b(bool d, bool e) {\n"
" int c;\n"
" if (d)\n"
" c = 0;\n"
" if (e)\n"
" goto;\n"
" c++;\n"
"}\n";
values = tokenValues(code, "c ++ ; }");
ASSERT_EQUALS(true, values.empty());
code = "void b(bool d, bool e) {\n"
" int c;\n"
" if (d)\n"
" c = 0;\n"
" if (e)\n"
" return;\n"
" c++;\n"
"}\n";
values = tokenValues(code, "c ++ ; }");
ASSERT_EQUALS(true, values.empty());
code = "void b(bool d, bool e) {\n"
" int c;\n"
" if (d)\n"
" c = 0;\n"
" if (e)\n"
" exit();\n"
" c++;\n"
"}\n";
values = tokenValues(code, "c ++ ; }");
ASSERT_EQUALS(true, values.empty());
code = "void b(bool d, bool e) {\n"
" int c;\n"
" if (d)\n"
" c = 0;\n"
" else if (e)\n"
" c = 0;\n"
" c++;\n"
"}\n";
values = tokenValues(code, "c ++ ; }");
TODO_ASSERT_EQUALS(true, false, values.size() == 2);
// ASSERT_EQUALS(true, values.front().isUninitValue() || values.back().isUninitValue());
// ASSERT_EQUALS(true, values.front().isPossible() || values.back().isPossible());
// ASSERT_EQUALS(true, values.front().intvalue == 0 || values.back().intvalue == 0);
code = "void b(bool d, bool e) {\n"
" int c;\n"
" if (d)\n"
" c = 0;\n"
" else if (!d)\n"
" c = 0;\n"
" c++;\n"
"}\n";
values = tokenValues(code, "c ++ ; }");
ASSERT_EQUALS(true, values.size() == 1);
// TODO: Value should be known
ASSERT_EQUALS(true, values.back().isPossible());
ASSERT_EQUALS(true, values.back().intvalue == 0);
code = "void f() {\n" // sqlite
" int szHdr;\n"
" idx = (A<0x80) ? (szHdr = 0) : dostuff(A, (int *)&(szHdr));\n"
" d = szHdr;\n" // szHdr can be 0.
"}";
values = tokenValues(code, "szHdr ; }");
TODO_ASSERT_EQUALS(1, 0, values.size());
if (values.size() == 1) {
ASSERT_EQUALS(false, values.front().isUninitValue());
}
2019-03-01 15:05:53 +01:00
code = "void f () {\n"
" int szHdr;\n"
" idx = ((aKey<0x80) ? ((szHdr)=aKey), 1 : sqlite3GetVarint32(&(szHdr)));\n"
" d = szHdr;\n"
"}";
values = tokenValues(code, "szHdr ; }");
ASSERT_EQUALS(0, values.size());
// #9933
code = "struct MyStruct { size_t value; }\n"
"\n"
"void foo() {\n"
" MyStruct x;\n"
" fread(((char *)&x) + 0, sizeof(x), f);\n"
" if (x.value < 432) {}\n"
"}";
values = tokenValues(code, "x . value");
ASSERT_EQUALS(0, values.size());
// #10166
code = "int f(bool b) {\n"
" int x;\n"
" do {\n"
" if (b) {\n"
" x = 0;\n"
" break;\n"
" }\n"
" } while (true);\n"
" return x;\n"
"}\n";
values = tokenValues(code, "x ; }", ValueFlow::Value::ValueType::UNINIT);
ASSERT_EQUALS(0, values.size());
code = "int f(bool b) {\n"
" int x;\n"
" while (true) {\n"
" if (b) {\n"
" x = 0;\n"
" break;\n"
" }\n"
" }\n"
" return x;\n"
"}\n";
values = tokenValues(code, "x ; }", ValueFlow::Value::ValueType::UNINIT);
ASSERT_EQUALS(0, values.size());
code = "int f(bool b) {\n"
" int x;\n"
" for(;;) {\n"
" if (b) {\n"
" x = 0;\n"
" break;\n"
" }\n"
" }\n"
" return x;\n"
"}\n";
values = tokenValues(code, "x ; }", ValueFlow::Value::ValueType::UNINIT);
ASSERT_EQUALS(0, values.size());
code = "int f(bool b) {\n"
" int x;\n"
" switch (b) {\n"
" case 1: {\n"
" ret = 0;\n"
" break;\n"
" }\n"
" }\n"
" return x;\n"
"}\n";
values = tokenValues(code, "x ; }", ValueFlow::Value::ValueType::UNINIT);
ASSERT_EQUALS(0, values.size());
}
void valueFlowConditionExpressions() {
const char* code;
// opposite condition
code = "void f(int i, int j) {\n"
" if (i == j) return;\n"
" if(i != j) {}\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 1);
code = "void f(int i, int j) {\n"
" if (i == j) return;\n"
" i++;\n"
" if (i != j) {}\n"
"}\n";
ASSERT_EQUALS(false, valueOfTok(code, "!=").intvalue == 1);
code = "void f(int i, int j, bool a) {\n"
" if (a) {\n"
" if (i == j) return;\n"
" }\n"
" if (i != j) {}\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 1);
ASSERT_EQUALS(false, valueOfTok(code, "!=").isKnown());
code = "void f(int i, int j, bool a) {\n"
" if (i != j) {}\n"
" if (i == j) return;\n"
"}\n";
ASSERT_EQUALS(false, valueOfTok(code, "!=").intvalue == 1);
// same expression
code = "void f(int i, int j) {\n"
" if (i != j) return;\n"
" bool x = (i != j);\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f(int i, int j) {\n"
" if (i != j) return;\n"
" i++;\n"
" bool x = (i != j);\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 5U, 0));
code = "void f(int i, int j, bool a) {\n"
" if (a) {\n"
" if (i != j) return;\n"
" }\n"
" bool x = (i != j);\n"
" bool b = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, 0));
code = "void f(int i, int j, bool a) {\n"
" bool x = (i != j);\n"
" bool b = x;\n"
" if (i != j) return;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, 0));
code = "void f(int i, int j, bool b) {\n"
" if (i == j) { if(b) return; }\n"
" if(i != j) {}\n"
"}\n";
ASSERT_EQUALS(false, valueOfTok(code, "!=").intvalue == 1);
code = "void f(bool b, int i, int j) {\n"
" if (b || i == j) return;\n"
" if(i != j) {}\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 1);
code = "void f(bool b, int i, int j) {\n"
" if (b && i == j) return;\n"
" if(i != j) {}\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "!=").empty());
code = "void f(int i, int j) {\n"
" if (i == j) {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 0);
code = "void f(int i, int j) {\n"
" if (i == j) {} else {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 1);
code = "void f(bool b, int i, int j) {\n"
" if (b && i == j) {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 0);
code = "void f(bool b, int i, int j) {\n"
" if (b || i == j) {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "!=").empty());
code = "void f(bool b, int i, int j) {\n"
" if (b || i == j) {} else {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "!=").intvalue == 1);
code = "void f(bool b, int i, int j) {\n"
" if (b && i == j) {} else {\n"
" if (i != j) {}\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "!=").empty());
code = "void foo()\n" // #8924
"{\n"
" if ( this->FileIndex >= 0 )\n"
" return;\n"
"\n"
" this->FileIndex = 1 ;\n"
" if ( this->FileIndex < 0 ) {}\n"
"}";
ASSERT_EQUALS(false, valueOfTok(code, "<").intvalue == 1);
code = "int f(int p) {\n"
" int v = 0;\n"
" for (int i = 0; i < 1; ++i) {\n"
" if (p == 0)\n"
" v = 1;\n"
" if (v == 1)\n"
" break;\n"
" }\n"
" int x = v;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 10U, 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 10U, 1));
code = "void f() {\n"
" const int size = arrayInfo.num(0);\n"
" if (size <= 0)\n"
" return;\n"
" for (;;)\n"
" if (size > 0) {}\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "> 0").isKnown());
ASSERT_EQUALS(true, valueOfTok(code, "> 0").intvalue == 1);
// FP #10110
code = "enum FENUMS { NONE = 0, CB = 8 };\n"
"bool calc(int x) {\n"
" if (!x) {\n"
" return false;\n"
" }\n"
"\n"
" if (x & CB) {\n"
" return true;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(false, valueOfTok(code, "& CB").isKnown());
ASSERT_EQUALS(true, testValueOfXImpossible(code, 7U, 0));
code = "enum FENUMS { NONE = 0, CB = 8 };\n"
"bool calc(int x) {\n"
" if (x) {\n"
" return false;\n"
" }\n"
"\n"
" if ((!x) & CB) {\n"
" return true;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "& CB").isKnown());
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 0));
code = "enum FENUMS { NONE = 0, CB = 8 };\n"
"bool calc(int x) {\n"
" if (!!x) {\n"
" return false;\n"
" }\n"
"\n"
" if (x & CB) {\n"
" return true;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(true, valueOfTok(code, "& CB").isKnown());
ASSERT_EQUALS(true, testValueOfXKnown(code, 7U, 0));
code = "bool calc(bool x) {\n"
" if (!x) {\n"
" return false;\n"
" }\n"
"\n"
" if (x) {\n"
" return true;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 1));
code = "bool calc(bool x) {\n"
" if (x) {\n"
" return false;\n"
" }\n"
"\n"
" if (!x) {\n"
" return true;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, 0));
}
static std::string isPossibleContainerSizeValue(std::list<ValueFlow::Value> values,
2021-08-07 20:51:18 +02:00
MathLib::bigint i,
bool unique = true) {
values.remove_if(std::mem_fn(&ValueFlow::Value::isSymbolicValue));
if (!unique)
values.remove_if(&isNotPossible);
if (values.size() != 1)
return "values.size():" + std::to_string(values.size());
if (!values.front().isContainerSizeValue())
return "ContainerSizeValue";
if (!values.front().isPossible())
return "Possible";
if (values.front().intvalue != i)
return "intvalue:" + std::to_string(values.front().intvalue);
return "";
}
static std::string isImpossibleContainerSizeValue(std::list<ValueFlow::Value> values,
2021-08-07 20:51:18 +02:00
MathLib::bigint i,
bool unique = true) {
values.remove_if(std::mem_fn(&ValueFlow::Value::isSymbolicValue));
if (!unique)
values.remove_if(&isNotImpossible);
if (values.size() != 1)
return "values.size():" + std::to_string(values.size());
if (!values.front().isContainerSizeValue())
return "ContainerSizeValue";
if (!values.front().isImpossible())
return "Impossible";
if (values.front().intvalue != i)
return "intvalue:" + std::to_string(values.front().intvalue);
return "";
}
static std::string isInconclusiveContainerSizeValue(std::list<ValueFlow::Value> values,
2021-08-07 20:51:18 +02:00
MathLib::bigint i,
bool unique = true) {
values.remove_if(std::mem_fn(&ValueFlow::Value::isSymbolicValue));
if (!unique)
values.remove_if(&isNotInconclusive);
if (values.size() != 1)
return "values.size():" + std::to_string(values.size());
if (!values.front().isContainerSizeValue())
return "ContainerSizeValue";
if (!values.front().isInconclusive())
return "Inconclusive";
if (values.front().intvalue != i)
return "intvalue:" + std::to_string(values.front().intvalue);
return "";
}
2021-07-18 10:01:22 +02:00
static std::string isKnownContainerSizeValue(std::list<ValueFlow::Value> values, MathLib::bigint i, bool unique = true) {
values.remove_if(std::mem_fn(&ValueFlow::Value::isSymbolicValue));
if (!unique)
values.remove_if(&isNotKnown);
if (values.size() != 1)
return "values.size():" + std::to_string(values.size());
if (!values.front().isContainerSizeValue())
return "ContainerSizeValue";
if (!values.front().isKnown())
return "Known";
if (values.front().intvalue != i)
return "intvalue:" + std::to_string(values.front().intvalue);
return "";
}
void valueFlowContainerSize() {
const char *code;
LOAD_LIB_2(settings.library, "std.cfg");
// condition
code = "void f(const std::list<int> &ints) {\n"
" if (!static_cast<bool>(ints.empty()))\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 0));
// valueFlowContainerReverse
code = "void f(const std::list<int> &ints) {\n"
" ints.front();\n" // <- container can be empty
" if (ints.empty()) {}\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f(const std::list<int> &ints) {\n"
" ints.front();\n" // <- container can be empty
" if (ints.size()==0) {}\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f(std::list<int> ints) {\n"
" ints.front();\n" // <- no container size
" ints.pop_back();\n"
" if (ints.empty()) {}\n"
"}";
ASSERT(tokenValues(code, "ints . front").empty());
code = "void f(std::vector<int> v) {\n"
" v[10] = 0;\n" // <- container size can be 10
" if (v.size() == 10) {}\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "v ["), 10));
2018-09-04 20:28:48 +02:00
code = "void f(std::vector<std::string> params) {\n"
" switch(x) {\n"
" case CMD_RESPONSE:\n"
" if(y) { break; }\n"
" params[2];\n" // <- container use
" break;\n"
" case CMD_DELETE:\n"
" if (params.size() < 2) { }\n" // <- condition
" break;\n"
" }\n"
"}";
ASSERT(tokenValues(code, "params [ 2 ]").empty());
// valueFlowAfterCondition
code = "void f(const std::vector<std::string>& v) {\n"
" if(v.empty()) {\n"
" v.front();\n"
" }\n"
"}\n";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "v . front"), 0));
code = "void f(const std::vector<std::string>& v) {\n"
" if(std::empty(v)) {\n"
" v.front();\n"
" }\n"
"}\n";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "v . front"), 0));
code = "void f(const std::vector<std::string>& v) {\n"
" if(!v.empty()) {\n"
" v.front();\n"
" }\n"
"}\n";
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "v . front"), 0));
code = "void f(const std::vector<std::string>& v) {\n"
" if(!v.empty() && v[0] != \"\") {\n"
" v.front();\n"
" }\n"
"}\n";
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "v . front"), 0));
// valueFlowContainerForward
code = "void f(const std::list<int> &ints) {\n"
" if (ints.empty()) {}\n"
" ints.front();\n" // <- container can be empty
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.empty()) { continue; }\n"
" ints.front();\n" // <- no container size
"}";
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.empty()) { ints.push_back(0); }\n"
" ints.front();\n" // <- container is not empty
"}";
ASSERT(tokenValues(code, "ints . front").empty());
code = "void f(const std::list<int> &ints) {\n"
" if (ints.empty()) {\n"
" ints.front();\n" // <- container is empty
" }\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.size() == 3) {\n"
" ints.front();\n" // <- container size is 3
" }\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front"), 3));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.size() <= 3) {\n"
" ints.front();\n" // <- container size is 3
" }\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 3, false));
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 4, false));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.size() >= 3) {\n"
" ints.front();\n" // <- container size is 3
" }\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 3, false));
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 2, false));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.size() < 3) {\n"
" ints.front();\n" // <- container size is 2
" }\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 2, false));
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 3, false));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.size() > 3) {\n"
" ints.front();\n" // <- container size is 4
" }\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "ints . front"), 4, false));
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints . front"), 3, false));
code = "void f(const std::list<int> &ints) {\n"
" if (ints.empty() == false) {\n"
" ints.front();\n" // <- container is not empty
" }\n"
"}";
ASSERT(tokenValues(code, "ints . front").empty());
code = "void f(const std::vector<int> &v) {\n"
" if (v.empty()) {}\n"
" if (!v.empty() && v[10]==0) {}\n" // <- no container size for 'v[10]'
"}";
ASSERT(tokenValues(code, "v [").empty());
code = "void f() {\n"
" std::list<int> ints;\n" // No value => ints is empty
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front"), 0));
code = "void f() {\n"
" std::array<int,10> ints;\n" // Array size is 10
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front"), 10));
code = "void f() {\n"
" std::string s;\n"
" cin >> s;\n"
" s[0];\n"
"}";
ASSERT(tokenValues(code, "s [").empty());
code = "void f() {\n"
" std::string s = \"abc\";\n" // size of s is 3
" s.size();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "s . size"), 3));
code = "void f(const char* p) {\n"
" if (p == nullptr) return;\n"
" std::string s { p };\n" // size of s is unknown
" s.front();\n"
"}";
ASSERT(tokenValues(code, "s . front").empty());
code = "void f() {\n"
" std::string s = { 'a', 'b', 'c' };\n" // size of s is 3
" s.size();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "s . size"), 3));
2018-10-27 18:38:04 +02:00
code = "void f() {\n"
" std::string s=\"abc\";\n" // size of s is 3
" s += unknown;\n"
" s.size();\n"
"}";
ASSERT(tokenValues(code, "s . size").empty());
code = "void f() {\n"
" std::string s=\"abc\";\n" // size of s is 3
" s += \"def\";\n" // size of s => 6
" s.size();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "s . size"), 6));
code = "void f(std::string s) {\n"
" if (s == \"hello\")\n"
" s[40] = c;\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "s ["), 5));
code = "void f(std::string s) {\n"
" s[40] = c;\n"
" if (s == \"hello\") {}\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "s ["), 5));
code = "void f(std::string s) {\n"
" if (s != \"hello\") {}\n"
" s[40] = c;\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "s ["), 5));
code = "void f(std::string s) {\n"
" if (s != \"hello\")\n"
" s[40] = c;\n"
"}";
ASSERT(!isImpossibleContainerSizeValue(tokenValues(code, "s ["), 5).empty());
code = "void f() {\n"
" static std::string s;\n"
" if (s.size() == 0)\n"
" s = x;\n"
"}";
ASSERT(tokenValues(code, "s . size").empty());
code = "void f() {\n"
" const uint8_t data[] = { 1, 2, 3 };\n"
" std::vector<uint8_t> v{ data, data + sizeof(data) };\n"
" v.size();\n"
"}";
TODO_ASSERT_EQUALS("", "ContainerSizeValue", isKnownContainerSizeValue(tokenValues(code, "v . size"), 3)); // TODO: extract container size
2018-11-02 20:10:40 +01:00
// valueFlowContainerForward, loop
code = "void f() {\n"
" std::stack<Token *> links;\n"
" while (!links.empty() || indentlevel)\n"
" links.push(tok);\n"
"}";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "links . empty"), 0));
2018-11-02 20:10:40 +01:00
// valueFlowContainerForward, function call
code = "void f() {\n"
" std::list<int> x;\n"
" f(x);\n"
" x.front();\n" // <- unknown container size
"}";
ASSERT(tokenValues(code, "x . front").empty());
2018-08-21 06:32:33 +02:00
code = "void f() {\n" // #8689
" std::list<int> x;\n"
" f<ns::a>(x);\n"
" x.front();\n" // <- unknown container size
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void g(std::list<int>&);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void g(std::list<int>*);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(&x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void g(std::list<int>* const);\n" // #9434
"void f() {\n"
" std::list<int> x;\n"
" g(&x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void g(const std::list<int>&);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(std::list<int>);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(int&);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x[0]);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(int&);\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x.back());\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(std::list<int>&) {}\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(std::list<int>& y) { y.push_back(1); }\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void g(std::list<int>*) {}\n"
"void f() {\n"
" std::list<int> x;\n"
" g(&x);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void g(std::list<int>* y) { y->push_back(1); }\n"
"void f() {\n"
" std::list<int> x;\n"
" g(&x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void h(std::list<int>&);\n"
"void g(std::list<int>& y) { h(y); }\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
code = "void h(const std::list<int>&);\n"
"void g(std::list<int>& y) { h(y); }\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "x . front"), 0));
code = "void h(const std::list<int>&);\n"
"void g(std::list<int>& y) { h(y); y.push_back(1); }\n"
"void f() {\n"
" std::list<int> x;\n"
" g(x);\n"
" x.front();\n"
"}";
ASSERT(tokenValues(code, "x . front").empty());
2018-08-21 06:32:33 +02:00
code = "void f(std::vector<int> ints) {\n" // #8697
" if (ints.empty())\n"
" abort() << 123;\n"
" ints[0] = 0;\n"
"}";
ASSERT_EQUALS("", isImpossibleContainerSizeValue(tokenValues(code, "ints ["), 0));
2018-08-21 06:32:33 +02:00
code = "struct A {\n" // forward, nested function call, #9424
" double getMessage( std::vector<unsigned char> *message );\n"
"};\n"
"\n"
"struct B {\n"
" A *a;\n"
" double getMessage( std::vector<unsigned char> *message ) { return a->getMessage( message ); }\n"
"};\n"
"\n"
"void foo(B *ptr) {\n"
" std::vector<unsigned char> v;\n"
" ptr->getMessage (&v);\n"
" if (v.size () > 0) {}\n" // <- v has unknown size!
"}";
ASSERT_EQUALS(0U, tokenValues(code, "v . size ( )").size());
// if
code = "bool f(std::vector<int>&) {\n" // #9532
" return false;\n"
"}\n"
"int g() {\n"
" std::vector<int> v;\n"
" if (f(v) || v.empty())\n"
" return 0;\n"
" return v[0];\n"
"}\n";
ASSERT_EQUALS(0U, tokenValues(code, "v [ 0 ]").size());
// container size => yields
code = "void f() {\n"
" std::string s = \"abcd\";\n"
" s.size();\n"
"}";
ASSERT_EQUALS(4, tokenValues(code, "( ) ;").front().intvalue);
code = "void f() {\n"
" std::string s;\n"
" s.empty();\n"
"}";
ASSERT_EQUALS(1, tokenValues(code, "( ) ;").front().intvalue);
// Calculations
code = "void f() {\n"
" std::string s = \"abcd\";\n"
" x = s + s;\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "+"), 8));
2020-08-10 05:52:03 +02:00
code = "void f(const std::vector<int> &ints) {\n"
" ints.clear();\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
2020-08-10 05:52:03 +02:00
code = "void f(const std::vector<int> &ints) {\n"
" ints.resize(3);\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 3));
2020-08-10 05:52:03 +02:00
code = "void f(const std::vector<int> &ints) {\n"
" ints.resize(3);\n"
" ints.push_back(3);\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 4));
2020-08-10 05:52:03 +02:00
code = "void f(const std::vector<int> &ints) {\n"
" ints.resize(3);\n"
" ints.pop_back();\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("", isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 2));
code = "int f(bool b) {\n"
" std::map<int, int> m;\n"
" if (b)\n"
" m[0] = 1;\n"
" return m.at(0);\n"
"}\n";
ASSERT_EQUALS("", isPossibleContainerSizeValue(tokenValues(code, "m . at", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "struct Base {\n"
" virtual bool GetString(std::string &) const { return false; }\n"
"};\n"
"int f() {\n"
" std::string str;\n"
" Base *b = GetClass();\n"
" if (!b->GetString(str)) {\n"
" return -2;\n"
" }\n"
" else {\n"
" return str.front();\n"
" }\n"
"}\n";
ASSERT_EQUALS(0U, tokenValues(code, "str . front").size());
code = "void f() {\n"
" std::vector<int> ints{};\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "void f() {\n"
" std::vector<int> ints{};\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "void f() {\n"
" std::vector<int> ints{1};\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 1));
code = "void f() {\n"
" std::vector<int> ints{1};\n"
" std::vector<int> ints2{ints.begin(), ints.end()};\n"
" ints2.front();\n"
"}";
ASSERT_EQUALS(
"", isKnownContainerSizeValue(tokenValues(code, "ints2 . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 1));
code = "void f() {\n"
" std::vector<int> ints = {};\n"
" ints.front();\n"
"}";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "ints . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "void f(std::string str) {\n"
" if (str == \"123\")\n"
" bool x = str.empty();\n"
"}\n";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "str . empty", ValueFlow::Value::ValueType::CONTAINER_SIZE), 3));
2021-04-04 18:20:32 +02:00
code = "int f() {\n"
" std::array<int, 10> a = {};\n"
" return a.front();\n"
"}\n";
ASSERT_EQUALS("",
isKnownContainerSizeValue(tokenValues(code, "a . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 10));
code = "int f(const std::vector<int>& x) {\n"
" if (!x.empty() && x[0] == 0)\n"
" return 2;\n"
" return x.front();\n"
"}\n";
ASSERT_EQUALS("",
isPossibleContainerSizeValue(tokenValues(code, "x . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "int f(const std::vector<int>& x) {\n"
" if (!(x.empty() || x[0] != 0))\n"
" return 2;\n"
" return x.front();\n"
"}\n";
ASSERT_EQUALS("",
isPossibleContainerSizeValue(tokenValues(code, "x . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
code = "int f() {\n"
" const size_t len = 6;\n"
" std::vector<char> v;\n"
" v.resize(1 + len);\n"
" return v.front();\n"
"}\n";
ASSERT_EQUALS(
"",
isKnownContainerSizeValue(tokenValues(code, "v . front", ValueFlow::Value::ValueType::CONTAINER_SIZE), 7));
code = "void f(std::string str) {\n"
" if (str == \"123\") {\n"
" bool x = (str == \"\");\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f(std::string str) {\n"
" if (str == \"123\") {\n"
" bool x = (str != \"\");\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 1));
code = "void f(std::string str) {\n"
" if (str == \"123\") {\n"
" bool x = (str == \"321\");\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 1));
code = "void f(std::string str) {\n"
" if (str == \"123\") {\n"
" bool x = (str != \"321\");\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 0));
code = "void f(std::string str) {\n"
" if (str.size() == 1) {\n"
" bool x = (str == \"123\");\n"
" bool a = x;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
2021-02-10 11:42:00 +01:00
code = "bool f(std::string s) {\n"
" if (!s.empty()) {\n"
" bool x = s == \"0\";\n"
" return x;\n"
" }\n"
" return false;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 1));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 4U, 0));
code = "void f() {\n"
" std::vector<int> v;\n"
" int x = v.size();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f() {\n"
" std::vector<int> v;\n"
" int x = v.empty();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 1));
code = "void f() {\n"
" std::vector<int> v;\n"
" int x = std::size(v);\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f() {\n"
" std::vector<int> v;\n"
" int x = std::empty(v);\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 1));
2021-02-10 11:42:00 +01:00
code = "bool f() {\n"
" std::list<int> x1;\n"
" std::list<int> x2;\n"
" for (int i = 0; i < 10; ++i) {\n"
" std::list<int>& x = (i < 5) ? x1 : x2;\n"
" x.push_back(i);\n"
" }\n"
" return x1.empty() || x2.empty();\n"
"}\n";
ASSERT_EQUALS("", isInconclusiveContainerSizeValue(tokenValues(code, "x1 . empty", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
ASSERT_EQUALS("", isInconclusiveContainerSizeValue(tokenValues(code, "x2 . empty", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
2021-02-10 11:42:00 +01:00
code = "std::vector<int> g();\n"
"int f(bool b) {\n"
" std::set<int> a;\n"
" std::vector<int> c = g();\n"
" a.insert(c.begin(), c.end());\n"
" return a.size();\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "a . size", ValueFlow::Value::ValueType::CONTAINER_SIZE).empty());
code = "std::vector<int> g();\n"
"std::vector<int> f() {\n"
" std::vector<int> v = g();\n"
" if (!v.empty()) {\n"
" if (v[0] != 0)\n"
" v.clear();\n"
" }\n"
" if (!v.empty() && v[0] != 0) {}\n"
" return v;\n"
"}\n";
ASSERT_EQUALS(true, tokenValues(code, "v [ 0 ] != 0 ) { }", ValueFlow::Value::ValueType::CONTAINER_SIZE).empty());
code = "std::vector<int> f() {\n"
" std::vector<int> v;\n"
" v.reserve(1);\n"
" v[1] = 42;\n"
" return v;\n"
"}\n";
ASSERT_EQUALS(
"", isKnownContainerSizeValue(tokenValues(code, "v [", ValueFlow::Value::ValueType::CONTAINER_SIZE), 0));
}
void valueFlowDynamicBufferSize() {
const char *code;
LOAD_LIB_2(settings.library, "std.cfg");
LOAD_LIB_2(settings.library, "posix.cfg");
code = "void* f() {\n"
" void* x = malloc(10);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 10, ValueFlow::Value::ValueType::BUFFER_SIZE));
code = "void* f() {\n"
" void* x = calloc(4, 5);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, 20, ValueFlow::Value::ValueType::BUFFER_SIZE));
code = "void* f() {\n"
" const char* y = \"abcd\";\n"
" const char* x = strdup(y);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 5, ValueFlow::Value::ValueType::BUFFER_SIZE));
code = "void* f() {\n"
" void* y = malloc(10);\n"
" void* x = realloc(y, 20);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 20, ValueFlow::Value::ValueType::BUFFER_SIZE));
code = "void* f() {\n"
" void* y = calloc(10, 4);\n"
" void* x = reallocarray(y, 20, 5);\n"
" return x;\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 100, ValueFlow::Value::ValueType::BUFFER_SIZE));
}
void valueFlowSafeFunctionParameterValues() {
const char *code;
std::list<ValueFlow::Value> values;
Settings s;
2019-07-24 11:39:18 +02:00
LOAD_LIB_2(s.library, "std.cfg");
2019-07-23 13:14:08 +02:00
s.safeChecks.classes = s.safeChecks.externalFunctions = s.safeChecks.internalFunctions = true;
code = "short f(short x) {\n"
" return x + 0;\n"
"}";
values = removeSymbolic(tokenValues(code, "+", &s));
ASSERT_EQUALS(2, values.size());
ASSERT_EQUALS(-0x8000, values.front().intvalue);
ASSERT_EQUALS(0x7fff, values.back().intvalue);
2019-07-24 11:39:18 +02:00
code = "short f(std::string x) {\n"
" return x[10];\n"
"}";
values = tokenValues(code, "x [", &s);
ASSERT_EQUALS(2, values.size());
ASSERT_EQUALS(0, values.front().intvalue);
ASSERT_EQUALS(1000000, values.back().intvalue);
2019-07-24 12:08:56 +02:00
code = "int f(float x) {\n"
" return x;\n"
"}";
values = tokenValues(code, "x ;", &s);
ASSERT_EQUALS(2, values.size());
ASSERT(values.front().floatValue < -1E20);
ASSERT(values.back().floatValue > 1E20);
code = "short f(__cppcheck_low__(0) __cppcheck_high__(100) short x) {\n"
" return x + 0;\n"
"}";
values = removeSymbolic(tokenValues(code, "+", &s));
ASSERT_EQUALS(2, values.size());
ASSERT_EQUALS(0, values.front().intvalue);
ASSERT_EQUALS(100, values.back().intvalue);
2019-07-12 16:05:08 +02:00
code = "unsigned short f(unsigned short x) [[expects: x <= 100]] {\n"
2019-07-12 16:05:08 +02:00
" return x + 0;\n"
"}";
values = removeSymbolic(tokenValues(code, "+", &s));
2021-04-04 18:20:32 +02:00
values.remove_if([](const ValueFlow::Value& v) {
return v.isImpossible();
});
2019-07-12 16:05:08 +02:00
ASSERT_EQUALS(2, values.size());
ASSERT_EQUALS(0, values.front().intvalue);
ASSERT_EQUALS(100, values.back().intvalue);
}
2019-07-11 16:05:34 +02:00
void valueFlowUnknownFunctionReturn() {
const char *code;
std::list<ValueFlow::Value> values;
Settings s;
2019-07-11 16:05:34 +02:00
LOAD_LIB_2(s.library, "std.cfg");
s.checkUnknownFunctionReturn.insert("rand");
code = "x = rand();";
values = tokenValues(code, "(", &s);
ASSERT_EQUALS(2, values.size());
ASSERT_EQUALS(INT_MIN, values.front().intvalue);
ASSERT_EQUALS(INT_MAX, values.back().intvalue);
}
void valueFlowPointerAliasDeref() {
const char* code;
code = "int f() {\n"
" int a = 123;\n"
" int *p = &a;\n"
" int x = *p;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 5U, 123));
}
Fix crashes in valueflow (#2236) * Fix crashes in valueflow http://cppcheck1.osuosl.org:8000/crash.html For instance in http://cppcheck1.osuosl.org:8000/styx ``` ==19651==ERROR: AddressSanitizer: SEGV on unknown address 0x00000000001c (pc 0x556f21abc3df bp 0x7ffc140d2720 sp 0x7ffc140d2710 T0) ==19651==The signal is caused by a READ memory access. ==19651==Hint: address points to the zero page. #0 0x556f21abc3de in Variable::isGlobal() const ../lib/symboldatabase.h:342 #1 0x556f221f801a in valueFlowForwardVariable ../lib/valueflow.cpp:2471 #2 0x556f22208130 in valueFlowForward ../lib/valueflow.cpp:3204 #3 0x556f221e9e14 in valueFlowReverse ../lib/valueflow.cpp:1892 #4 0x556f221f1a43 in valueFlowBeforeCondition ../lib/valueflow.cpp:2200 #5 0x556f2223dbb5 in ValueFlow::setValues(TokenList*, SymbolDatabase*, ErrorLogger*, Settings const*) ../lib/valueflow.cpp:6521 #6 0x556f220e5991 in Tokenizer::simplifyTokens1(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/tokenize.cpp:2342 #7 0x556f21d8d066 in CppCheck::checkFile(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::istream&) ../lib/cppcheck.cpp:508 #8 0x556f21d84cd3 in CppCheck::check(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/cppcheck.cpp:192 #9 0x556f21a28796 in CppCheckExecutor::check_internal(CppCheck&, int, char const* const*) ../cli/cppcheckexecutor.cpp:884 #10 0x556f21a24be8 in CppCheckExecutor::check(int, char const* const*) ../cli/cppcheckexecutor.cpp:198 #11 0x556f22313063 in main ../cli/main.cpp:95 ``` * Add test case for crash in valueflow
2019-10-16 20:54:07 +02:00
void valueFlowCrashIncompleteCode() {
const char* code;
code = "void SlopeFloor::setAttr(const Value &val) {\n"
" int x = val;\n"
" if (x >= -1)\n"
" state = x;\n"
"}\n";
valueOfTok(code, "=");
code = "void a() {\n"
" auto b = [b = 0] {\n"
" if (b) {\n"
" }\n"
" };\n"
"}\n";
valueOfTok(code, "0");
code = "namespace juce {\n"
"PopupMenu::Item& PopupMenu::Item::operator= (Item&&) = default;\n"
"PopupMenu::Options withDeletionCheck (Component& comp) const {\n"
" Options o (*this);\n"
" o.componentToWatchForDeletion = &comp;\n"
" o.isWatchingForDeletion = true;\n"
" return o;\n"
"}}\n";
valueOfTok(code, "return");
code = "class dummy_resource : public instrument_resource {\n"
"public:\n"
" int reads;\n"
" static std::list<int> log;\n"
"};\n"
"void dummy_reader_reset() {\n"
" dummy_resource::log.clear();\n"
"}\n";
valueOfTok(code, "log");
Fix crashes in valueflow (#2236) * Fix crashes in valueflow http://cppcheck1.osuosl.org:8000/crash.html For instance in http://cppcheck1.osuosl.org:8000/styx ``` ==19651==ERROR: AddressSanitizer: SEGV on unknown address 0x00000000001c (pc 0x556f21abc3df bp 0x7ffc140d2720 sp 0x7ffc140d2710 T0) ==19651==The signal is caused by a READ memory access. ==19651==Hint: address points to the zero page. #0 0x556f21abc3de in Variable::isGlobal() const ../lib/symboldatabase.h:342 #1 0x556f221f801a in valueFlowForwardVariable ../lib/valueflow.cpp:2471 #2 0x556f22208130 in valueFlowForward ../lib/valueflow.cpp:3204 #3 0x556f221e9e14 in valueFlowReverse ../lib/valueflow.cpp:1892 #4 0x556f221f1a43 in valueFlowBeforeCondition ../lib/valueflow.cpp:2200 #5 0x556f2223dbb5 in ValueFlow::setValues(TokenList*, SymbolDatabase*, ErrorLogger*, Settings const*) ../lib/valueflow.cpp:6521 #6 0x556f220e5991 in Tokenizer::simplifyTokens1(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/tokenize.cpp:2342 #7 0x556f21d8d066 in CppCheck::checkFile(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&, std::istream&) ../lib/cppcheck.cpp:508 #8 0x556f21d84cd3 in CppCheck::check(std::__cxx11::basic_string<char, std::char_traits<char>, std::allocator<char> > const&) ../lib/cppcheck.cpp:192 #9 0x556f21a28796 in CppCheckExecutor::check_internal(CppCheck&, int, char const* const*) ../cli/cppcheckexecutor.cpp:884 #10 0x556f21a24be8 in CppCheckExecutor::check(int, char const* const*) ../cli/cppcheckexecutor.cpp:198 #11 0x556f22313063 in main ../cli/main.cpp:95 ``` * Add test case for crash in valueflow
2019-10-16 20:54:07 +02:00
}
void valueFlowCrash() {
const char* code;
code = "void f(int x) {\n"
" if (0 * (x > 2)) {}\n"
"}\n";
valueOfTok(code, "x");
code = "const int& f(int, const int& y = 0);\n"
"const int& f(int, const int& y) {\n"
" return y;\n"
"}\n"
"const int& g(int x) {\n"
" const int& r = f(x);\n"
" return r;\n"
"}\n";
valueOfTok(code, "0");
code = "void fa(int &colors) {\n"
" for (int i = 0; i != 6; ++i) {}\n"
"}\n"
"void fb(not_null<int*> parent, int &&colors2) {\n"
" dostuff(1);\n"
"}\n";
valueOfTok(code, "x");
code = "void a() {\n"
" static int x = 0;\n"
" struct c {\n"
" c(c &&) { ++x; }\n"
" };\n"
"}\n";
valueOfTok(code, "x");
code = "void f(){\n"
" struct dwarf_data **pp;\n"
" for (pp = (struct dwarf_data **) (void *) &state->fileline_data;\n"
" *pp != NULL;\n"
" pp = &(*pp)->next)\n"
" ;\n"
"}\n";
valueOfTok(code, "x");
code = "void *foo(void *x);\n"
"void *foo(void *x)\n"
"{\n"
" if (!x)\n"
"yes:\n"
" return &&yes;\n"
" return x;\n"
"}\n";
valueOfTok(code, "x");
code = "void f() {\n"
" std::string a = b[c->d()];\n"
" if(a.empty()) {\n"
" INFO(std::string{\"a\"} + c->d());\n"
" INFO(std::string{\"b\"} + a);\n"
" }\n"
"}\n";
valueOfTok(code, "a");
2020-12-19 12:23:19 +01:00
code = "class A{\n"
" void f() {\n"
" std::string c{s()};\n"
" }\n"
" std::string s() {\n"
" return \"\";\n"
" }\n"
"};\n";
valueOfTok(code, "c");
code = "void f() {\n"
" char* p = 0;\n"
" int pi =\n"
" p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 \n"
" : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 \n"
" : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 \n"
" : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 \n"
" : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 : p == \"a\" ? 1 \n"
" : 0;\n"
" int *i2 = 0;\n"
" if (i2) { }\n"
"}\n";
valueOfTok(code, "p");
code = "struct a;\n"
"namespace e {\n"
"struct f {\n"
" struct g {\n"
" enum {} h;\n"
" int arg;\n"
" };\n"
" std::vector<g> i;\n"
"};\n"
"} // namespace e\n"
"void fn1() {\n"
" std::vector<a *> arguments;\n"
" e::f b;\n"
" for (e::f::g c : b.i)\n"
" if (c.h)\n"
" a *const d = arguments[c.arg];\n"
"}\n";
valueOfTok(code, "c");
code = "void h(char* p, int s) {\n"
" char *q = p+s;\n"
" char buf[100];\n"
" char *b = buf;\n"
" ++b;\n"
" if (p < q && buf < b)\n"
" diff = (buf-b);\n"
"}\n";
valueOfTok(code, "diff");
code = "void foo() {\n" // #10462
" std::tuple<float, float, float, float> t4(5.2f, 3.1f, 2.4f, 9.1f), t5(4, 6, 9, 27);\n"
" t4 = t5;\n"
" ASSERT(!(t4 < t5) && t4 <= t5);\n"
"}";
valueOfTok(code, "<=");
}
void valueFlowHang() {
const char* code;
// #9659
code = "float arr1[4][4] = {0.0};\n"
"float arr2[4][4] = {0.0};\n"
"void f() {\n"
" if(arr1[0][0] == 0.0 &&\n"
" arr1[0][1] == 0.0 &&\n"
" arr1[0][2] == 0.0 &&\n"
" arr1[0][3] == 0.0 &&\n"
" arr1[1][0] == 0.0 &&\n"
" arr1[1][1] == 0.0 &&\n"
" arr1[1][2] == 0.0 &&\n"
" arr1[1][3] == 0.0 &&\n"
" arr1[2][0] == 0.0 &&\n"
" arr1[2][1] == 0.0 &&\n"
" arr1[2][2] == 0.0 &&\n"
" arr1[2][3] == 0.0 &&\n"
" arr1[3][0] == 0.0 &&\n"
" arr1[3][1] == 0.0 &&\n"
" arr1[3][2] == 0.0 &&\n"
" arr1[3][3] == 0.0 &&\n"
" arr2[0][0] == 0.0 &&\n"
" arr2[0][1] == 0.0 &&\n"
" arr2[0][2] == 0.0 &&\n"
" arr2[0][3] == 0.0 &&\n"
" arr2[1][0] == 0.0 &&\n"
" arr2[1][1] == 0.0 &&\n"
" arr2[1][2] == 0.0 &&\n"
" arr2[1][3] == 0.0 &&\n"
" arr2[2][0] == 0.0 &&\n"
" arr2[2][1] == 0.0 &&\n"
" arr2[2][2] == 0.0 &&\n"
" arr2[2][3] == 0.0 &&\n"
" arr2[3][0] == 0.0 &&\n"
" arr2[3][1] == 0.0 &&\n"
" arr2[3][2] == 0.0 &&\n"
" arr2[3][3] == 0.0\n"
" ) {}\n"
"}\n";
valueOfTok(code, "x");
2020-10-03 11:01:53 +02:00
code = "namespace {\n"
"struct a {\n"
" a(...) {}\n"
" a(std::initializer_list<std::pair<int, std::vector<std::vector<a>>>>) {}\n"
"} b{{0, {{&b, &b, &b, &b}}},\n"
" {0,\n"
" {{&b, &b, &b, &b, &b, &b, &b, &b, &b, &b},\n"
" {{&b, &b, &b, &b, &b, &b, &b}}}},\n"
" {0,\n"
" {{&b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b},\n"
" {&b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b}}}};\n"
"}\n";
valueOfTok(code, "x");
code = "namespace {\n"
"struct a {\n"
" a(...) {}\n"
" a(std::initializer_list<std::pair<int, std::vector<std::vector<a>>>>) {}\n"
"} b{{0, {{&b}}},\n"
" {0, {{&b}}},\n"
" {0, {{&b}}},\n"
" {0, {{&b}}},\n"
" {0, {{&b}, {&b, &b, &b, &b, &b, &b, &b, &b, &b, &b, {&b}}}},\n"
" {0,\n"
" {{&b},\n"
" {&b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b, &b,\n"
" &b}}}};\n"
"}\n";
valueOfTok(code, "x");
code = "int &a(int &);\n"
"int &b(int &);\n"
"int &c(int &);\n"
"int &d(int &e) {\n"
" if (!e)\n"
" return a(e);\n"
" if (e > 0)\n"
" return b(e);\n"
" if (e < 0)\n"
" return c(e);\n"
" return e;\n"
"}\n"
"int &a(int &e) { \n"
" if (!e)\n"
" return d(e); \n"
" if (e > 0)\n"
" return b(e);\n"
" if (e < 0)\n"
" return c(e);\n"
" return e;\n"
"}\n"
"int &b(int &e) { \n"
" if (!e)\n"
" return a(e); \n"
" if (e > 0)\n"
" return c(e);\n"
" if (e < 0)\n"
" return d(e);\n"
" return e;\n"
"}\n"
"int &c(int &e) { \n"
" if (!e)\n"
" return a(e); \n"
" if (e > 0)\n"
" return b(e);\n"
" if (e < 0)\n"
" return d(e);\n"
" return e;\n"
"}\n";
valueOfTok(code, "x");
code = "void a() {\n"
" int b = 0;\n"
" do {\n"
" for (;;)\n"
" break;\n"
" } while (b < 1);\n"
"}\n";
valueOfTok(code, "b");
code = "void ParseEvent(tinyxml2::XMLDocument& doc, std::set<Item*>& retItems) {\n"
" auto ParseAddItem = [&](Item* item) {\n"
" return retItems.insert(item).second;\n"
" };\n"
" tinyxml2::XMLElement *root = doc.RootElement();\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
" for (auto *el = root->FirstChildElement(\"Result\"); el && !ParseAddItem(GetItem(el)); el = el->NextSiblingElement(\"Result\")) ;\n"
"}\n";
valueOfTok(code, "root");
code = "bool isCharPotentialOperator(char ch) {\n"
" return (ispunct((unsigned char) ch)\n"
" && ch != '{' && ch != '}'\n"
" && ch != '(' && ch != ')'\n"
" && ch != '[' && ch != ']'\n"
" && ch != ';' && ch != ','\n"
" && ch != '#' && ch != '\\\\'\n"
" && ch != '\\\'' && ch != '\\\"');\n"
"}\n";
valueOfTok(code, "return");
}
void valueFlowCrashConstructorInitialization() { // #9577
const char* code;
code = "void Error()\n"
"{\n"
" VfsPath path(\"\");\n"
" path = path / amtype;\n"
" size_t base = 0;\n"
" VfsPath standard(\"standard\");\n"
" if (path != standard)\n"
" {\n"
" }\n"
"}";
valueOfTok(code, "path");
code = "void Error()\n"
"{\n"
" VfsPath path;\n"
" path = path / amtype;\n"
" size_t base = 0;\n"
" VfsPath standard(\"standard\");\n"
" if (path != standard)\n"
" {\n"
" }\n"
"}";
valueOfTok(code, "path");
}
void valueFlowUnknownMixedOperators() {
const char *code= "int f(int a, int b, bool x) {\n"
" if (a == 1 && (!(b == 2 && x))) {\n"
" } else {\n"
" if (x) {\n"
" }\n"
" }\n"
"\n"
" return 0;\n"
2021-08-07 20:51:18 +02:00
"}";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 1));
}
void valueFlowIdempotent() {
const char *code;
code = "void f(bool a, bool b) {\n"
" bool x = true;\n"
" if (a)\n"
" x = x && b;\n"
" bool result = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 5U, 1));
code = "void f(bool a, bool b) {\n"
" bool x = false;\n"
" if (a)\n"
" x = x && b;\n"
" bool result = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 0));
code = "void f(bool a, bool b) {\n"
" bool x = true;\n"
" if (a)\n"
" x = x || b;\n"
" bool result = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
code = "void f(bool a, bool b) {\n"
" bool x = false;\n"
" if (a)\n"
" x = x || b;\n"
" bool result = x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 5U, 0));
}
void valueFlowUnsigned() {
const char *code;
code = "auto f(uint32_t i) {\n"
" auto x = i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
code = "auto f(uint32_t i) {\n"
" auto x = (int32_t)i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, -1));
code = "auto f(uint32_t i) {\n"
" auto x = (int64_t)i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
code = "size_t g();\n"
"auto f(uint16_t j) {\n"
" auto x = g() - j;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 4U, 0));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, -1));
code = "auto f(uint32_t i) {\n"
" auto x = (i + 1) % 16;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 0));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
code = "auto f(uint32_t i) {\n"
" auto x = i ^ 3;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 2));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
code = "auto f(uint32_t i) {\n"
" auto x = i & 3;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 2));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, -1));
}
void valueFlowMod() {
const char *code;
code = "auto f(int i) {\n"
" auto x = i % 2;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, 2));
code = "auto f(int i) {\n"
" auto x = !(i % 2);\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 1));
}
void valueFlowNotNull()
{
const char* code;
code = "int f(const std::string &str) {\n"
" int x = str.c_str();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, 0));
code = "int f(const std::string_view &str) {\n"
" int x = str.c_str();\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXImpossible(code, 3U, 0));
code = "auto f() {\n"
" std::shared_ptr<int> x = std::make_shared<int>(1);\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, 0));
code = "auto f() {\n"
" std::unique_ptr<int> x = std::make_unique<int>(1);\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, 0));
code = "struct A {\n"
" A* f() {\n"
" A* x = this;\n"
" return x;\n"
" }\n"
"};\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, 0));
}
void valueFlowSymbolic() {
const char* code;
code = "int f(int i) {\n"
" int j = i;\n"
" int x = i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, "j", 0));
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, "i", 0));
code = "int f(int i) {\n"
" int j = i;\n"
" int x = j;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, "i", 0));
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, "j", 0));
code = "void g(int&);\n"
"int f(int i) {\n"
" int j = i;\n"
" g(i);\n"
" int x = i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 6U, "i", 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 6U, "j", 0));
code = "int f(int i) {\n"
" int j = i;\n"
" j++;\n"
" int x = i == j;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 0));
code = "int f(int i) {\n"
" int j = i;\n"
" i++;\n"
" int x = i - j;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
code = "int f(int i) {\n"
" int j = i;\n"
" i++;\n"
" int x = i > j;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
code = "int f(int i) {\n"
" int j = i;\n"
" j++;\n"
" int x = j > i;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 5U, 1));
code = "int f(int i) {\n"
" int j = i++;\n"
" int x = i++;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, "i++", 0));
code = "float foo() {\n"
" float f = 1.0f;\n"
" float x = f;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, "1.0f", 0));
code = "int foo(float f) {\n"
" float g = f;\n"
" int x = f == g;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, 1));
code = "int f(int i) {\n"
" for(int j = i;;j++) {\n"
" int x = j;\n"
" return x;\n"
" }\n"
" return 0;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, "i", 0));
ASSERT_EQUALS(false, testValueOfXKnown(code, 4U, "i", 1));
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, "j", 0));
code = "void f(int x) {\n"
" int y = x + 1;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, "y", 0));
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "y", -1));
code = "void f(int x) {\n"
" int y = x * 2;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, "y", 0));
code = "int f(int i, int j) {\n"
" if (i == j) {\n"
" int x = i - j;\n"
" return x;\n"
" }\n"
" return 0;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f(int x, int y) {\n"
" if (x == y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "y", 0));
code = "void f(int x, int y) {\n"
" if (x != y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "y", 0));
code = "void f(int x, int y) {\n"
" if (x < y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "y", -1));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "y", 0));
code = "void f(int x, int y) {\n"
" if (x <= y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "y", 0));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "y", 1));
code = "void f(int x, int y) {\n"
" if (x > y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "y", 1));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "y", 0));
code = "void f(int x, int y) {\n"
" if (x >= y) {\n"
" int a = x;\n"
" }\n"
"}";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "y", 0));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "y", -1));
2021-10-11 19:10:37 +02:00
code = "void f(int y) {\n"
" int x = y - 1;\n"
" if (y == 1)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 0));
code = "void f(int y) {\n"
" int x = y * y;\n"
" if (y == 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 4));
code = "void f(int x, int y) {\n"
" if (x == y*y)\n"
" if (y == 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 4U, 4));
code = "void f(int x, int y) {\n"
" if (x > y*y)\n"
" if (y == 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, 4));
code = "void f(int x, int y) {\n"
" if (x != y*y)\n"
" if (y == 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, 4));
code = "void f(int x, int y) {\n"
" if (x >= y*y)\n"
" if (y == 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXImpossible(code, 4U, 3));
code = "void f(int x, int y) {\n"
" if (x == y*y)\n"
" if (y != 2)\n"
" int a = x;\n"
"}\n";
TODO_ASSERT_EQUALS(true, false, testValueOfXImpossible(code, 4U, 4));
code = "void f(int x, int y) {\n"
" if (x == y*y)\n"
" if (y > 2)\n"
" int a = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 4U, 9));
code = "struct A {\n"
" A* b();\n"
" int c() const;\n"
"};\n"
"void f(A *d) {\n"
" if (!d || d->c() != 1)\n"
" return;\n"
" A * y = d;\n"
" d = d->b();\n"
" A * x = d;\n"
" A* z = x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 11U, "d", 0));
ASSERT_EQUALS(false, testValueOfXImpossible(code, 11U, 0));
code = "void f(int * p, int len) {\n"
" for(int x = 0; x < len; ++x) {\n"
" p[x] = 1;\n"
" }\n"
"}\n";
ASSERT_EQUALS(true, testValueOfX(code, 3U, "len", -1));
ASSERT_EQUALS(true, testValueOfXImpossible(code, 3U, "len", 0));
}
void valueFlowSymbolicIdentity()
{
const char* code;
code = "void f(int a) {\n"
" int x = a*1;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a/1;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a+0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a-0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a^0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a|0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a>>0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = a<<0;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(true, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = 0>>a;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, "a", 0));
code = "void f(int a) {\n"
" int x = 0<<a;\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfXKnown(code, 3U, "a", 0));
}
void valueFlowSmartPointer()
{
const char* code;
code = "int* df(int* expr);\n"
"int * f() {\n"
" std::unique_ptr<int> x;\n"
" x.reset(df(x.release()));\n"
" return x;\n"
"}\n";
ASSERT_EQUALS(false, testValueOfX(code, 5U, 0));
}
};
REGISTER_TEST(TestValueFlow)